AQ11EM7R5BA1RE [KYOCERA AVX]
Ceramic Capacitor, Multilayer, Ceramic, 150V, 1.33% +Tol, 1.33% -Tol, 90+/-20ppm/Cel TC, 0.0000075uF, Surface Mount, 0606, CHIP, ROHS COMPLIANT;型号: | AQ11EM7R5BA1RE |
厂家: | KYOCERA AVX |
描述: | Ceramic Capacitor, Multilayer, Ceramic, 150V, 1.33% +Tol, 1.33% -Tol, 90+/-20ppm/Cel TC, 0.0000075uF, Surface Mount, 0606, CHIP, ROHS COMPLIANT 电容器 |
文件: | 总113页 (文件大小:1309K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
A KYOCERA GROUP COMPANY
AVX
RF Microwave/Thin-Film
Products
AVX Microwave
Ask The World Of Us
As one of the world’s broadest line
multilayer ceramic chip capacitor
suppliers, and a major Thin Film
RF/Microwave capacitor, inductor,
directional coupler and low pass filter and
microwave ceramic capacitor manufacturer,
it is our mission to provide First In Class
Technology, Quality and Service, by
establishing progressive design,
manufacturing and continuous
improvement programs driving
toward a single goal:
TOTAL CUSTOMER SATISFACTION
1
RF/Microwave Products
Table of Contents
Company Profile . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Thin-Film RF/Microwave Technology – Accu-F® / Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24
Thin-Film Technology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Thin-Film Chip Capacitors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Thin-Film Chip Capacitors for RF Signal and Power Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Accu-F®. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
0201 Typical Electrical Tables – Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
0402 Typical Electrical Tables – Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12-13
0603 Typical Electrical Tables – Accu-F® / Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
0805 Typical Electrical Tables – Accu-F® / Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1210 Typical Electrical Tables – Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
High Frequency Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-19
Environmental / Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Performance Characteristics RF Power Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Application Notes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22-23
Automatic Insertion Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Thin-Film RF/Microwave Inductor Technology – Accu-L® – L0603/L0805 . . . . . . . . . . . . . . . . . . 25-30
SMD High-Q RF Inductor – Accu-L® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26-29
Environmental Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Application Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Thin-Film RF/Microwave Directional Couplers – CP0402/CP0603/CP0805/DB0805 3dB 90° . . . . 31-67
CP0402 High Directivity LGA Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32-35
CP0603 High Directivity LGA Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36-40
CP0402 and CP0603 Test Jigs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
CP0603 SMD Type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42-44
CP0603 SMD Type – High Directivity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
CP0805 Type. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46-49
CP0805 and CP0603 Test Jigs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
DB0805 3dB 90° Couplers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51-62
DB0805 3dB 90° Test Jigs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Thin-Film RF/Microwave Harmonic Low Pass Filter – LP0603/LP0805 . . . . . . . . . . . . . . . . . . . . 64-71
LP0603 Test Jigs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67-68
LP0805 Test Jigs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
Thin-Film RF/Microwave Products – Designer Kits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72-74
RF/Microwave Multilayer Capacitors (MLC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75-89
Porcelain Capacitors (+90 20ppm/°C) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76-79
• AQ06 (0.063" x 0.032") - Cap. Range: 0.1 to 120pF
• AQ11; AQ12 (0.055" x 0.055") - Cap. Range: 0.1 to 100pF
• AQ13; AQ14 (0.110" x 0.110") - Cap. Range: 0.1 to 1000pF
Hi-Q NP0 Capacitors (0 30ppm/°C) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
• AQ06 (0.063" x 0.032") - Cap. Range: 0.1 to 120pF
• AQ11; AQ12 (0.055" x 0.055") - Cap. Range: 0.1 to 1000pF
• AQ13; AQ14 (0.110" x 0.110") - Cap. Range: 0.1 to 5100pF
Hi-K RF Capacitors ( 15ꢀ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78-79
• AQ12 (0.055" x 0.055") - Cap. Range: 0.001 to 0.010µF
• AQ14 (0.110" x 0.110") - Cap. Range: 0.005 to 0.1µF
MIL-PRF-55681 “BG” Voltage Temperature Limits (+90 20ppm/°C) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80-82
• CDR11BG; CDR12BG (0.055" x 0.055") - Failure Rate Level: M, P, R, S
• CDR13BG; CDR14BG (0.110" x 0.110") - Failure Rate Level: M, P, R, S
MIL-PRF-55681 “BP” Voltage Temperature Limits (0 30ppm/°C) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80-82
• CDR11BP; CDR12BP (0.055" x 0.055") - Failure Rate Level: M, P, R, S
• CDR13BP; CDR14BP (0.110" x 0.110") - Failure Rate Level: M, P, R, S
Performance Curves. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83-87
Automatic Insertion Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
Hi-Q® High RF Power MLC Surface Mount Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
RF/Microwave C0G (NP0) Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90-93
Ultra Low ESR “U” Series, C0G (NP0)
• 0402 (0.040" x 0.020"), 0603 (0.060" x 0.030"), 0805 (0.080" x 0.050"), 1210 (0.125" x 0.100") . . . . . . . . . . . . . . . . . . 91-93
RF/Microwave AQ 12 & 14 and “U” Series Designer Kits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94-97
Introduction to Microwave Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98-110
2
RF/Microwave Products
Table of Contents
Company Profile. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Thin-Film RF/Microwave Technology – Accu-F® / Accu-P® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24
Thin-Film RF/Microwave Technology – Accu-L® L0603, L0805. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25-30
Thin-Film RF/Microwave Directional Couplers – CP0402/CP0603/CP0805/DB0805 3dB 90° . . . . 31-63
Thin-Film RF/Microwave Harmonic Low Pass Filter – LP0603/LP0805 . . . . . . . . . . . . . . . . . . . . . . . . . 64-71
Thin-Film RF/Microwave Products – Designer Kits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72-74
RF/Microwave Multilayer Capacitors (MLC). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75-89
RF/Microwave C0G (NP0) Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90-93
RF/Microwave AQ 12 & 14 and “U” Series Designer Kits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94-97
1
2
3
4
5
6
7
8
9
Introduction to Microwave Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98-110
3
RF/Microwave Products
Company Profile
AVX Corporation is a leading manufacturer of multilayer ceramic,
thin film, tantalum, and glass capacitors, as well as other passive
electronic components. These products are used in virtually every
variety of electronic system today, including data processing,
telecommunications, consumer/automotive electronics, military and
aerospace systems, and instrumentation and process controls.
We continually strive to be the leader in all component segments we
supply. RF/Microwave capacitors is a thrust business for us. AVX
offers a broad line of RF/Microwave Chip Capacitors in a wide range
of sizes, styles, and ratings.
The Thin-Film Products range illustrated in this catalog represents
the state-of-the-art in RF Capacitors, Inductors, Directional
Couplers and Low Pass Filters. The thin-film technology provides
components that exhibit excellent batch-to-batch repeatability of
electrical parameters at RF frequencies.
The Accu-F® and Accu-P® series of capacitors are available in ultra-
tight tolerances (±±.±2pFꢀ as well as non-standard capacitance
values.
The Accu-L® series of inductors are ideally suited for applications
requiring an extremely high Q and high current capability.
The CP±4±2/CP±6±3/CP±8±5 series of Directional Couplers cover
the frequency range of 8±± MHz to 6 GHz. They feature low inser-
tion loss, high directivity and highly accurate coupling factors.
The LP±8±5 series of Low Pass Filters provide a rugged component
in a small ±8±5 size package with excellent high frequency perfor-
mance.
Another major series of microwave capacitors consists of both
multilayer porcelain and ceramic capacitors for frequencies from
1± MHz to 4.2 GHz (AQ11 - 14 Seriesꢀ. Three sizes of specially
designed ultra-low ESR C±G (NP±ꢀ capacitors are covered for
RF applications (“U” Seriesꢀ.
Ask the world of us. Call (843) 448-9411.
Or visit our website http://www.avx.com
4
1
Thin-Film Technology
®
®
Accu-F / Accu-P
Thin-Film RF/Microwave Capacitors
5
®
®
Accu-F / Accu-P
Thin-Film Technology
This accuracy sets apart these Thin-Film capacitors from
ceramic capacitors so that the term Accu has been
employed as the designation for this series of devices, an
abbreviation for “accurate.”
THE IDEAL CAPACITOR
The non-ideal characteristics of a real capacitor can be
ignored at low frequencies. Physical size imparts inductance
to the capacitor and dielectric and metal electrodes result in
resistive losses, but these often are of negligible effect on the
circuit. At the very high frequencies of radio communication
(>100MHz) and satellite systems (>1GHz), these effects
become important. Recognizing that a real capacitor will
exhibit inductive and resistive impedances in addition to
capacitance, the ideal capacitor for these high frequencies is
an ultra low loss component which can be fully characterized
in all parameters with total repeatability from unit to unit.
THIN-FILM TECHNOLOGY
Thin-film technology is commonly used in producing semi-
conductor devices. In the last two decades, this technology
has developed tremendously, both in performance and in
process control. Today’s techniques enable line definitions of
below 1µm, and the controlling of thickness of layers at 100Å
1
-2
(10 µm). Applying this technology to the manufacture of
Until recently, most high frequency/microwave capacitors
were based on fired-ceramic (porcelain) technology. Layers
of ceramic dielectric material and metal alloy electrode paste
are interleaved and then sintered in a high temperature oven.
This technology exhibits component variability in dielectric
quality (losses, dielectric constant and insulation resistance),
variability in electrode conductivity and variability in physical
size (affecting inductance). An alternate thin-film technology
has been developed which virtually eliminates these vari-
ances. It is this technology which has been fully incorporated
capacitors has enabled the development of components
where both electrical and physical properties can be tightly
controlled.
The thin-film production facilities at AVX consist of:
• Class 1000 clean rooms, with working areas under
laminar-flow hoods of class 100, (below 100 particles
per cubic foot larger than 0.5µm).
• High vacuum metal deposition systems for high-purity
electrode construction.
®
®
into Accu-F and Accu-P to provide high frequency capaci-
tors exhibiting truly ideal characteristics.
• Photolithography equipment for line definition down to
2.0µm accuracy.
®
®
The main features of Accu-F and Accu-P may be summa-
rized as follows:
• Plasma-enhanced CVD for various dielectric deposi-
tions (CVD=Chemical Vapor Deposition).
• High purity of electrodes for very low and repeatable
ESR.
• High accuracy, microprocessor-controlled dicing saws
for chip separation.
• Highly pure, low-K dielectric for high breakdown field,
high insulation resistance and low losses to frequencies
above 40GHz.
• High speed, high accuracy sorting to ensure strict
tolerance adherence.
• Very tight dimensional control for uniform inductance,
unit to unit.
• Very tight capacitance tolerances for high frequency
signal applications.
TERMINATION
ALUMINA
SEAL
ELECTRODE
ELECTRODE
DIELECTRIC
ALUMINA
ACCU-P® CAPACITOR
6
®
®
Accu-F / Accu-P
Thin-Film Chip Capacitors
ACCU-F® TECHNOLOGY
ACCU-P® TECHNOLOGY
As in the Accu-F series the use of very low-loss dielectric
®
The use of very low-loss dielectric materials, silicon dioxide
and silicon oxynitride, in conjunction with highly conductive
electrode metals results in low ESR and high Q. These
high-frequency characteristics change at a slower rate with
increasing frequency than for ceramic microwave capacitors.
materials (silicon dioxide and silicon oxynitride) in conjunction
with highly conductive electrode metals results in low ESR and
high Q. At high frequency these characteristics change at
a slower rate with increasing frequency than conventional
ceramic microwave capacitors. Using thin-film technology, the
above-mentioned frequency characteristics are obtained with-
out significant compromise of properties required for surface
mounting. The use of high thermal conductivity materials
results in excellent RF power handling capabilities.
Because of the thin-film technology, the above-mentioned
frequency characteristics are obtained without significant
compromise of properties required for surface mounting.
1
®
The main Accu-F properties are:
• Internationally agreed sizes with excellent dimensional
control.
• Small size chip capacitors (0603) are available.
• Tight capacitance tolerances.
• Low ESR at VHF, UHF and microwave frequencies.
• High stability with respect to time, temperature, frequency
and voltage variation.
®
The main Accu-P properties are:
• Enhanced RF power handling capability.
• Improved mechanical characteristics.
• Internationally agreed sizes with excellent dimensional control.
• Ultra Small size chip capacitors (0201) are available.
• Tight capacitance tolerances.
• Low ESR at UHF, VHF, and microwave frequencies.
• High-stability with respect to time, temperature, frequency
and voltage variation.
• Nickel/solder-coated terminations to provide excellent
solderability and leach resistance.
ACCU-F® FEATURES
Accu-F meets the fast-growing demand for low-loss
• High temperature nickel/solder-coated terminations as stan-
dard to provide excellent solderability and leach resistance.
®
(high-Q) capacitors for use in surface mount technology espe-
cially for the mobile communications market, such as cellular
radio of 450 and 900 MHz, UHF walkie-talkies, UHF cordless
telephones to 2.3 GHz, low noise blocks at 11-12.5 GHz and
for other VHF, UHF and microwave applications.
ACCU-P® FEATURES
• Minimal batch to batch variability of parameters at high fre-
quency.
®
®
• The Accu-P has the same unique features as the Accu-F
®
Accu-F is currently unique in its ability to offer very
capacitor such as low ESR, high Q, availability of very low
capacitance values and very tight capacitance tolerances.
low capacitance values (0.1pF) and very tight capacitance
®
tolerances ( 0.05pF). Typically Accu-F will be used in small
®
• The RF power handling capability of the Accu-P allows for
its usage in both small signal and RF power applications.
signal applications in VCO’s, matching networks, filters, etc.
Inspection test and quality control procedures in accordance
with ISO 9001, CECC, IECQ and USA MIL Standards yield
products of the highest quality.
• Inspection, test and quality control procedures in accor-
dance with ISO 9001, CECC, IECQ and USA MIL Standards
guarantee product of the highest quality.
®
• Hand soldering Accu-P : Due to their construction
APPLICATIONS
utilizing relatively high thermal conductivity materials,
Accu-P’s have become the preferred device in R & D labs
and production environments where hand soldering is used.
Accu-P’s are available in all sizes and are electrically identi-
cal to their Accu-F counterparts.
Cellular Communications
Radar Systems
Video Switching
Test & Measurements
Filters
VCO’s
Matching Networks
CT2/PCN (Cordless
Telephone/Personal Comm.
Networks)
Satellite TV
Cable TV
GPS (Global Positioning Systems)
Vehicle Location Systems
Vehicle Alarm Systems
Paging
APPLICATIONS
Cellular Communications
CT2/PCN (Cordless
Telephone/Personal Comm.
Networks)
Satellite TV
Cable TV
GPS (Global Positioning Systems)
Vehicle Location Systems
Vehicle Alarm Systems
Paging
Radar Systems
Video Switching
Test & Measurements
Filters
APPROVALS
ISO 9001
Military Communications
VCO's
Matching Networks
RF Amplifiers
APPROVALS
ISO 9001
Military Communications
7
®
®
Accu-F */ Accu-P
Thin-Film Chip Capacitors for
RF Signal and Power Applications
B1
T
B2
ACCU-P® (Signal and Power Type Capacitors)
L
1
0201
0402*
0603*
0805*
1210
3.±2±±.1
ACCU-F® *(Signal Type Capacitors)
±.6±±±.±5
1.±±±±.1
1.6±±±.1
2.±1±±.1
L
W
T
0603
1.6±±±.1
(±.±63±±.±±4ꢀ
0805
2.±1±±.1
(±.±79±±.±±4ꢀ
(±.±23±±.±±2ꢀ (±.±39±±.±±4ꢀ (±.±63±±.±±4ꢀ (±.±79±±.±±4ꢀ (±.119±±.±±4ꢀ
±.325±±.±5± ±.55±±.±7 ±.81±±.1 1.27±±.1 2.5±±.1
(±.±128±±.±±2ꢀ (±.±22±±.±±3ꢀ (±.±32±±.±±4ꢀ (±.±5±±±.±±4ꢀ (±.1±±±±.±±4ꢀ
±.225±±.±5± ±.4±±±.1 ±.63±±.1 ±.93±±.2 ±.93±±.2
(±.±±9±±.±±2ꢀ (±.±16±±.±±4ꢀ (±.±25±±.±±4ꢀ (±.±36±±.±±8ꢀ (±.±36±±.±±8ꢀ
±.1±±±.1± ±.±±±±.1/-± ±.35±±.15 ±.3±±±.1 ±.43±±.1
(±.±±4±±.±±4ꢀ (±.±±±±±.±±4/-±ꢀ (±.±14±±.±±6ꢀ (±.±12±±.±±4ꢀ (±.±17±±.±±4ꢀ
±.15±±.±5 ±.2±±±.1 ±.35±±.15 ±.3±±±.1 ±.43±±.1
(±.±±6±±.±±2ꢀ (±.±±8±±.±±4ꢀ (±.±14±±.±±6ꢀ (±.±12±±.±±4ꢀ (±.±17±±.±±4ꢀ
L
W
T
±.81±±.1
(±.±32±±.±±4ꢀ
1.27±±.1
(±.±5±±±.±±4ꢀ
±.63±±.1
(±.±25±±.±±4ꢀ
±.63±±.1
(±.±25±±.±±4ꢀ
B1
B2
±.3±±±.1
(±.±12±±.±±4ꢀ
±.3±±±.1
(±.±12±±.±±4ꢀ
B
Not recommended for new designs.
Accu-P’s are recommended.
DIMENSIONS:
millimeters (inches)
Mount Black Side Up
DIMENSIONS: millimeters (inches)
*
*
HOW TO ORDER
0805
5
J
120
G
A
W
TR
Size
0201*
0402*
0603
0805
Voltage Temperature Capacitance
1 = 100V Coefficient (1)
Tolerance
for
Termination
Code
Packaging
Code
TR = Tape and Reel
Specification
Code
Capacitance
J = 0 30ppm/°C expressed in pF.
®
5 = 50V
3 = 25V
Y = 16V
Z = 10V
C≤2.0pF*
W = Nickel/
A = Accu-F
(-55°C to
+125°C)
K = 0 60ppm/°C
(-55°C to
(2 significant
digits + number Q = 0.03pF
of zeros)
for values
<10pF,
P = 0.02pF
Solder Coated
technology
®
®
Accu-F Sn63, Pb37
B = Accu-P
®
1210*
* Accu-P ONLY
A = 0.05pF
B = 0.1pF
C = 0.25pF
technology
Accu-P 0201 & 0402
Sn90, Pb10
+125°C)
T = Nickel/High Temperature
letter R denotes
decimal point.
Example:
68pF = 680
8.2pF = 8R2
for
C≤3.0pF
Q = 0.03pF
A = 0.05pF
B = 0.1pF
C = 0.25pF
Solder Coated
®
Accu-P 0603, 0805, 1210
Sn96, Ag4
S = Nickel/Lead Free
Solder Coated
®
Accu-P 0402
(1) TC’s shown are per EIA/IEC Specifications.
for
C≤5.6pF
A = 0.05pF
B = 0.1pF
C = 0.25pF
Sn100
for
5.6pF<C<10pF
B = 0.1pF
C = 0.25pF
D = 0.5pF
for
C≥10pF
F = 1ꢀ
G = 2ꢀ
J = 5ꢀ
* Tolerances as tight as 0.01pF are available.
Please consult the factory.
ELECTRICAL SPECIFICATIONS
Operating and Storage Temperature Range
Temperature Coefficients(1)
Capacitance Measurement
Insulation Resistance (IR)
Proof Voltage
-55°C to +125°C
0
30ppm/°C dielectric code “J” / 0 60ppm/°C dielectric code “K”
1 MHz, 1 Vrms
≥1011 Ohms (≥10 Ohms for 0201 and 0402 size)
2.5 UR for 5 secs.
Zero
10
Aging Characteristic
Dielectric Absorption
0.01ꢀ
(1) TC’s shown are per EIA/IEC Specifications.
8
®
Accu-F *
Signal Type Capacitors
Accu-F® Capacitance Ranges (pF)
TEMP. COEFFICIENT CODE
“J” = 0 30ppm/°C
TEMP. COEFFICIENT CODE
“K” = 0 60ppm/°C
(-55°C to +125°C)(2)
(-55°C to +125°)(2)
1
Size
Size Code
Size
Size Code
0603
50
0805
50
0603
50
0805
50
Voltage
100
25
100
25
Voltage
100
25
100
25
Cap in
pF(1)
Cap
Cap in
Cap
(
code
pF(1)
code
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
—
—
—
—
—
—
—
—
—
±R1
±R2
±R3
±R4
±R5
±R6
±R7
±R8
±R9
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
—
—
—
—
—
—
—
—
—
±R1
±R2
±R3
±R4
±R5
±R6
±R7
±R8
±R9
1.±
1.2
1.5
—
—
—
1R±
1R2
1R5
1.±
1.2
1.5
—
—
—
1R±
1R2
1R5
1.8
2.2
2.7
—
—
—
1R8
2R2
2R7
1.8
2.2
2.7
—
—
—
1R8
2R2
2R7
3.3
3.9
4.7
—
—
—
3R3
3R9
4R7
3.3
3.9
4.7
—
—
—
3R3
3R9
4R7
5.6
6.8
8.2
—
—
—
5R6
6R8
8R2
5.6
6.8
8.2
—
—
—
5R6
6R8
8R2
1±
12
15
—
—
—
1±±
12±
15±
1±
12
15
—
—
—
1±±
12±
15±
18
22
27
—
—
—
18±
22±
27±
18
22
27
—
—
—
18±
22±
27±
33
39
47
—
—
—
33±
39±
47±
33
39
47
—
—
—
33±
39±
47±
56
68
82
—
—
—
56±
68±
82±
56
68
82
—
—
—
56±
68±
82±
1±±
12±
15±
—
—
—
1±1
121
151
1±±
12±
15±
—
—
—
1±1
121
151
(1ꢀ
(1ꢀ
For capacitance values higher than listed in table,
please consult factory.
For capacitance values higher than listed in table,
please consult factory.
(2ꢀ
TC shown is per EIA/IEC Specifications.
(2ꢀ TC shown is per EIA/IEC Specifications.
Intermediate values are available within the indicated range.
Not recommended for new designs.
Accu-P’s are recommended.
*
9
®
Accu-P
Signal and Power Type Capacitors
Accu-P® Capacitance Ranges (pF)
TEMP. COEFFICIENT CODE
TEMP. COEFFICIENT CODE
“K” = 0 60ppm/°C (-55°C to +125°C)
Size
(2)
(2)
“J” = 0 30ppm/°C (-55°C to +125°C)
Size
Size Code
Voltage
0805
50
1210
100
Size Code
Voltage
0201
0402
0603
0805
1210
100
25
50(3)
25 16 10 25 16 10 50 25 100 50 25 100 50
Cap in
Cap
Cap in
Cap
pF(1)
code
pF(1)
code
1
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
—
—
—
—
—
—
—
—
—
±R1
±R2
±R3
±R4
±R5
±R6
±R7
±R8
±R9
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
—
—
—
—
—
—
—
—
—
±R1
±R2
±R3
±R4
±R5
±R6
±R7
±R8
±R9
1.±
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
—
—
—
—
—
—
—
—
—
—
1R±
1R1
1R2
1R3
1R4
1R5
1R6
1R7
1R8
1R9
1.±
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
—
—
—
—
—
—
—
—
—
—
1R±
1R1
1R2
1R3
1R4
1R5
1R6
1R7
1R8
1R9
2.±
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
—
—
—
—
—
—
—
—
—
—
2R±
2R1
2R2
2R3
2R4
2R5
2R6
2R7
2R8
2R9
2.±
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
—
—
—
—
—
—
—
—
—
—
2R±
2R1
2R2
2R3
2R4
2R5
2R6
2R7
2R8
2R9
3.±
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
—
—
—
—
—
—
—
—
—
—
3R±
3R1
3R2
3R3
3R4
3R5
3R6
3R7
3R8
3R9
3.±
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
—
—
—
—
—
—
—
—
—
—
3R±
3R1
3R2
3R3
3R4
3R5
3R6
3R7
3R8
3R9
4.±
4.1
4.2
4.3
4.4
4.5
4.6
4.7
—
—
—
—
—
—
—
—
4R±
4R1
4R2
4R3
4R4
4R5
4R6
4R7
4.±
4.1
4.2
4.3
4.4
4.5
4.6
4.7
—
—
—
—
—
—
—
—
4R±
4R1
4R2
4R3
4R4
4R5
4R6
4R7
5.1
5.6
6.2
—
—
—
5R1
5R6
6R2
5.1
5.6
6.2
—
—
—
5R1
5R6
6R2
6.8
7.5
8.2
—
—
—
6R8
7R5
8R2
6.8
7.5
8.2
—
—
—
6R8
7R5
8R2
9.1
1±.±
11.±
—
—
—
9R1
1±±
11±
9.1
1±.±
11.±
—
—
—
9R1
1±±
11±
12.±
13.±
14.±
—
—
—
12±
13±
14±
12.±
13.±
14.±
—
—
—
12±
13±
14±
15.±
16.±
17.±
—
—
—
15±
16±
17±
15.±
16.±
17.±
—
—
—
15±
16±
17±
18.±
22.±
24.±
—
—
—
18±
22±
24±
18.±
22.±
24.±
—
—
—
18±
22±
24±
27.±
3±.±
33.±
—
—
—
27±
3±±
33±
27.±
3±.±
33.±
—
—
—
27±
3±±
33±
39.±
47.±
56.±
68.±
—
—
—
—
39±
47±
56±
68±
39.±
47.±
56.±
68.±
—
—
—
—
39±
47±
56±
68±
(1ꢀ For capacitance values higher than listed in table,
please consult factory.
(1ꢀ For capacitance values higher than listed in table,
please consult factory.
(2ꢀ TC shown is per EIA/IEC Specifications.
(3ꢀ For 5± volt range, please consult factory.
(2ꢀ TC shown is per EIA/IEC Specifications.
These values are produced with “K” temperature coefficient
code only.
Intermediate values are available within the indicated range.
1±
®
Accu-P
0201 Typical Electrical Tables
Self
250MHz
500MHz
750MHz
1000MHz
1250MHz
Capacitance Resonance
@ 1 MHz
(pF)
Frequency
(GHz)
Typical
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
0.8
1.2
1.8
2.2
3.3
3.9
4.7
5.6
6.8
9.1
7.6
6.3
5.7
4.6
4.3
3.9
3.6
3.3
0.84
1.21
1.84
2.23
3.29
3.91
4.71
5.62
6.77
2154
1375
1298
1355
1295
1902
1677
1391
1135
360
405
271
214
156
93
0.84
1.21
1.85
2.24
3.31
3.93
4.74
5.67
6.83
630
525
520
512
430
460
391
370
314
603
517
341
281
230
181
174
154
149
0.85
1.22
1.86
2.25
3.33
3.97
4.80
5.74
6.91
424
341
337
335
285
298
252
257
217
594
527
347
284
230
185
178
148
142
0.85
1.23
1.87
2.27
3.36
4.02
4.87
5.83
7.03
327
267
270
264
220
227
181
195
164
577
503
326
270
223
181
183
144
139
0.86
1.23
1.88
2.29
3.40
4.08
4.97
5.95
7.18
255
208
201
199
159
163
130
140
118
588
515
347
284
242
198
200
157
151
1
84
84
84
Self
1500MHz
1750MHz
2250MHz
2500MHz
2750MHz
Capacitance Resonance
@ 1 MHz
(pF)
Frequency
(GHz)
Typical
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
M
Typ.
ESR
(ꢀΩ)
Typ.
C(eff)
(pF)
Typ.
Q
Typ.
ESR
(ꢀΩ)
0.8
1.2
1.8
2.2
3.3
3.9
4.7
5.6
6.8
9.1
7.6
6.3
5.7
4.6
4.3
3.9
3.6
3.3
0.86
1.24
1.90
2.32
3.45
4.16
5.08
6.11
7.38
204
155
148
145
119
122
99
611
565
388
320
266
216
213
166
155
0.87
1.26
1.92
2.34
3.50
4.25
5.23
6.31
7.63
168
129
123
123
101
103
83
631
577
395
322
263
214
212
164
158
0.88
1.28
1.96
2.41
3.63
4.46
5.55
6.76
8.22
141
92
96
93
74
75
60
64
54
587
570
395
329
277
224
221
174
166
0.89
1.30
1.99
2.46
3.73
4.63
5.83
7.16
8.74
126
89
83
81
64
64
50
53
44
571
566
396
328
276
223
222
175
169
0.90
1.31
2.02
2.50
3.84
4.79
6.10
7.56
9.29
122
81
74
72
55
56
43
45
37
532
558
397
330
281
225
224
141
173
108
93
91
76
11
®
Accu-P
0402 Typical Electrical Tables
Capacitance
Self
& Tolerance* Resonance Ref
Typ.
Typ.
Q
Typ.
Ref
Typ.
Typ.
Q
Typ. Ref Typ.
Typ.
Q
Typ.
Ref Typ. Typ.
Typ.
Ref
Typ.
Typ.
Q
Typ.
@ 1 MHz
(pF)
Frequency
(GHz)
Typical
Freq C(eff)
(MHz) (pF)
ESR Freq C(eff)
(Ω) (MHz) (pF)
ESR Freq C(eff)
(Ω) (MHz) (pF)
ESR Freq C(eff)
(Ω) (MHz) (pF)
Q
ESR
(Ω)
Freq C(eff)
(MHz) (pF)
ESR
(Ω)
0.1 0.05
0.2 0.05
0.3 0.05
0.4 0.05
0.5 0.05
0.6 0.05
0.7 0.05
0.8 0.05
0.9 0.05
1.00 0.05
1.10 0.05
1.20 0.05
1.30 0.05
1.40 0.05
1.50 0.05
1.60 0.05
1.70 0.05
1.80 0.05
1.90 0.05
2.00 0.05
2.10 0.05
2.20 0.05
2.30 0.05
2.40 0.05
2.50 0.05
2.60 0.05
2.70 0.05
2.80 0.05
2.90 0.05
3.00 0.05
3.10 0.05
3.20 0.05
3.30 0.05
3.40 0.05
3.50 0.05
3.60 0.05
3.70 0.05
3.80 0.05
3.90 0.05
4.00 0.05
4.10 0.05
4.20 0.05
4.30 0.05
4.40 0.05
4.50 0.05
4.60 0.05
4.70 0.05
5.10 0.05
5.60 0.05
6.2 0.1
19.4
16.4
14.6
12.5
11.3
10.4
9.5
9.1
8.8
8
7.8
7.4
7
6.8
6.5
6.5
6.4
6.2
6
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
1.15 1283
1.22 1219
1.33 1153
1.42 1109
1.54 1061
1.63 1002
1.76
1.81
1.86
1.93
2.06
2.14
2.27
2.36
2.48
2.6
2.71
2.83
2.94
3.11
3.39
3.45
3.61
3.72
3.78
3.82
3.87
3.93
4
4.01
4.07
4.18
4.27
4.34
4.45
4.52
4.62
4.74
5.16
5.75
6.09
6.94
7.51
8.36
9.28
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
1.13
1.21
1.31
1.4
1.52
1.58
1.69
1.75
1.83
1.91
2.11
2.21
2.26
2.4
2.51
2.62
2.73
2.82
2.9
2.99
3.11
3.22
3.3
3.42
3.53
3.6
3.7
3.81
3.9
4.02
4.11
4.2
4.29
4.43
4.5
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
1.12 620
1.19 561
1.3
1.35 480
1.49 461
1.6
1.71 429
1.75 422
1.8
1.91 401
2.01 400
2.1
2.27 396
2.3 379
2.41 358
2.52 349
2.65 331
2.86 313
2.91 308
3.15 303
3.41 299
3.48 291
3.68 285
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
1
n/a
n/a
247
246
245
244
243
242
242
241
240
239
239
238
237
237
236
235
234
233
233
232
231
230
230
229
228
227
226
226
225
224
224
223
223
222
222
221
221
220
217
214
211
208
205
202
199
196
193
189
186
184
182
179
178
1.16 1635 0.34
1.25 1581 0.32
1.34 1538 0.30
1.42 1502 0.29
1.53 1476 0.28
1.63 1454 0.28
1.71 1448 0.27
1.85 1444 0.27
1.93 1430 0.26
2.01 1421 0.25
2.11 1410 0.24
2.21 1406 0.23
2.28 1406 0.22
2.32 1405 0.20
2.45 1404 0.19
2.49 1404 0.18
494
492
491
490
488
486
485
483
482
481
480
478
476
475
473
472
470
469
468
467
466
465
464
462
461
460
459
458
458
457
457
456
455
454
453
452
451
450
447
443
440
436
433
430
428
0.22 742
0.21 740
0.21 738
0.21 736
0.20 733
0.20 731
0.20 729
0.19 728
0.19 727
0.19 726
0.18 722
0.17 720
0.16 718
0.16 716
0.16 715
0.16 714
0.15 712
0.15 711
0.15 710
0.15 710
0.15 709
0.15 708
0.15 707
0.14 707
0.14 706
0.14 705
0.14 704
0.14 702
0.13 699
0.13 697
0.13 696
0.13 696
0.12 695
0.12 694
0.12 693
0.12 692
0.11 691
0.11 690
0.11 687
0.11 684
0.10 681
0.09 678
0.09 675
0.08 673
0.09 670
870
791
727
701
680
638
622
612
597
583
582
581
581
549
501
486
477
464
458
450
440
429
421
415
407
402
395
389
386
384
381
380
379
373
369
364
359
351
348
342
339
334
320
306
249
0.22
0.22
0.22
0.21
0.21
0.21
0.21
0.20
0.20
0.20
0.19
0.18
0.17
0.17
0.17
0.17
0.17
0.17
0.16
0.16
0.16
0.16
0.16
0.16
0.15
0.15
0.15
0.15
0.15
0.15
0.14
0.14
0.14
0.14
0.14
0.13
0.13
0.13
0.13
0.12
0.11
0.10
0.10
0.09
0.10
0.11
0.11
0.11
0.09
0.12
0.10
0.11
0.11
0.10
0.11
0.11
0.12
991
989
986
983
980
978
986
985
983
972
969
966
964
962
960
959
958
956
954
953
952
951
950
949
948
947
946
945
944
943
942
941
940
939
939
938
938
937
934
932
928
926
924
922
920
0.23 1240 1.14
0.24 1238 1.21
0.25 1234 1.33
0.24 1230 1.41
0.23 1229 1.53
0.23 1226 1.65
0.23 1224 1.77
0.22 1223 1.86
0.22 1220 1.91
0.21 1219 1.97
0.20 1215 2.11
0.19 1213 2.22
0.18 1212 2.35
0.18 1209
0.19 1208 2.53
0.19 1205 2.7
0.19 1204 2.85
0.19 1203
0.18 1202 3.12
0.18 1201 3.24
0.18 1201 3.33
0.18 1199 3.45
0.17 1198 3.58
0.17 1197 3.61
0.17 1196 3.78
0.16 1195 3.91
474
425
372
350
333
316
309
305
299
294
293
291
289
262
253
240
231
224
220
218
212
207
203
198
195
191
186
181
177
172
170
169
167
168
162
161
161
159
131
129
128
127
120
0.25
0.25
0.25
0.25
0.25
0.25
0.24
0.23
0.23
0.22
0.21
0.20
0.19
0.20
0.20
0.20
0.20
0.20
0.20
0.19
0.19
0.19
0.19
0.19
0.19
0.18
0.18
0.18
0.18
0.18
0.18
0.17
0.17
0.17
0.16
0.16
0.16
0.16
0.16
0.16
0.15
0.14
0.13
0.13
0.13
0.12
0.12
0.12
0.12
0.15
0.13
0.14
0.14
0.14
0.14
0.14
0.14
503
438
986
970
931
897
896
893
893
870
845
821
799
778
769
751
746
733
725
711
705
693
688
667
658
649
650
655
658
657
660
665
670
673
589
576
585
591
567
542
458
413
5.7
5.4
5.1
5
398
2.4
4.9
4.7
4.6
4.5
4.5
4.4
4.4
4.4
4.3
4.3
4.3
4.2
4.2
4.1
4
3.9
3.9
3.8
3.8
3.7
3.7
3.6
3.6
3.5
3.4
3.3
3
2.8
2.7
2.6
2.5
2.4
2.3
2.2
2.2
2.1
2.1
2
1.9
1.8
1.8
1.8
1.75
2.6
1402 0.16
2.84 1399 0.15
2.85 1395 0.15
2.87 1395 0.15
2.88 1392 0.14
3
2.9
1392 0.14
2.91 1391 0.14
2.92 1391 0.14
2.93 1390 0.14
2.95 1389 0.13
2.97 1382 0.13
2.99 1381 0.13
3.8
282
3.79 276
3.85 273
3.89 270
3.95 262
4.02 256
4.11 251
4.18 250
4.23 248
4.37 247
4.58 246
4.62 246
0.16 1194
0.16 1193
4
4.1
4
1380 0.13
0.16 1192 4.23
0.16 1191 4.37
0.16 1190 4.46
0.15 1190 4.52
0.15 1199 4.66
0.15 1195 4.75
0.14 1192 4.82
0.14 1190 4.96
0.14 1188 5.07
0.14 1186 5.18
0.14 1184 5.82
0.14 1182 6.62
0.12 1180 7.34
0.11 1177 8.22
0.10 1176 9.01
4.01 1379 0.13
4.09 1372 0.12
4.18 1370 0.12
4.27 1356 0.12
4.36 1355 0.12
4.44 1351 0.11
4.53 1350 0.11
4.62 1347 0.11
4.75 1343 0.11
5.19 1310 0.11
5.74 1297 0.11
6.31 1244 0.10
6.92 1202 0.09
7.57 1155 0.08
8.35 1116 0.08
9.23 1059 0.09
4.6
4.7
245
4.72
4.74
5.23
5.81
6.33
7.04
7.85
8.48
9.87
4.79 244
4.86 244
5.53 230
6.01 201
6.68 202
7.39 203
8.17 191
8.93 186
10.2 152
6.8 0.1
7.5 0.1
8.2 0.1
9.1 0.1
0.10 1174 10.04 118
0.11 1172 11.98
0.13 1171 13.75
0.12 1170 15.3
0.13 1168 17.63
0.11 1164 23.9
0.14 1167 23.1
0.16 1166 23.6
0.13 1161 34.7
0.12 1163 34.9
0.11 1164 35.2
0.11 1163 37.5
0.12 1162 39.1
0.13 1161 100.5
88
70
61
52
47
40
44
28
28
29
24
19
15
10.0 1ꢀ
11.0 1ꢀ
12.0 1ꢀ
13.0 1ꢀ
14.0 1ꢀ
15.0 1ꢀ
16.0 1ꢀ
17.0 1ꢀ
18.0 1ꢀ
19.0 1ꢀ
20.0 1ꢀ
22.0 1ꢀ
10.14 936
11.19 912
12.16 889
13.3
14.26 802
15.34 791
0.09
0.08
0.08
0.07
0.08
0.07
0.07
0.07
0.07
0.08
0.08
424 10.24 385
421 11.17 363
418
416 13.32 363
414 14.44 298
413 15.46 283
410
410
409 18.42 258
407 19.4 241
405 20.43 195
404 23.105 174
0.10 668 10.55 202
0.09 666 11.81 185
0.09 664 12.77 173
0.08 661
0.09 660 15.03 149
0.08 660 16.16 138
0.08 657
0.08 657
0.07 657 19.51 130
0.07 655 20.51 115
0.06 655
0.54 654
919 11.49 118
917 12.87 103
915 14.16 95
12.3
348
984
14.1
183
912
15.8 101
913 16.72 76.7
912 18.51 82
16.3
17.6
780
765
16.4
17.7
270
263
17.6
18.2
129
130
909
909
910
908
908
20.2
21.3
22.7 75.5
24.5
26.5
68
70
176.5 18.13 754
175
173
19.2
20.32 520
680
62
57
22.1
25
112
85.5
170.04 22.42 497.5 0.09
907 30.95 44
* Other tolerances are available, see page 8
12
®
Accu-P
0402 Typical Electrical Tables
Capacitance
Self
& Tolerance* Resonance Ref
Typ.
Typ.
Q
Typ.
Ref
Typ. Typ.
Typ.
Ref Typ.
Typ.
Q
Typ.
Ref
Typ. Typ. Typ.
Ref
Typ.
Typ.
Q
Typ.
@ 1 MHz
(pF)
Frequency
(GHz)
Typical
Freq C(eff)
(MHz) (pF)
ESR Freq C(eff)
(Ω) (MHz) (pF)
Q
ESR Freq C(eff)
(Ω) (MHz) (pF)
ESR Freq C(eff)
(Ω) (MHz) (pF)
Q
ESR
Freq C(eff)
(MHz) (pF)
ESR
(Ω)
(Ω)
0.1 0.05
0.2 0.05
0.3 0.05
0.4 0.05
0.5 0.05
0.6 0.05
0.7 0.05
0.8 0.05
0.9 0.05
1.00 0.05
1.10 0.05
1.20 0.05
1.30 0.05
1.40 0.05
1.50 0.05
1.60 0.05
1.70 0.05
1.80 0.05
1.90 0.05
2.00 0.05
2.10 0.05
2.20 0.05
2.30 0.05
2.40 0.05
2.50 0.05
2.60 0.05
2.70 0.05
2.80 0.05
2.90 0.05
3.00 0.05
3.10 0.05
3.20 0.05
3.30 0.05
3.40 0.05
3.50 0.05
3.60 0.05
3.70 0.05
3.80 0.05
3.90 0.05
4.00 0.05
4.10 0.05
4.20 0.05
4.30 0.05
4.40 0.05
4.50 0.05
4.60 0.05
4.70 0.05
5.10 0.05
5.60 0.05
6.2 0.1
19.4
16.4
14.6
12.5
11.3
10.4
9.5
9.1
8.8
8
7.8
7.4
7
6.8
6.5
6.5
6.4
6.2
6
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
380
342
307
289
265
252
246
241
240
239
233
230
228
214
196
182
173
164
159
156
150
148
145
143
138
133
130
126
125
121
121
121
120
120
119
119
118
118
105
90
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
314
275
251
240
221
203
201
199
198
197
190
185
183
168
151
144
132
122
120
117
114
109
105
101
101
95
94
92
90
89
88
87
87
85
85
81
80
80
75
61
60
58
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
265
232
208
196
179
169
168
167
166
165
160
155
149
132
120
112
97
94
88
84
81
79
77
76
75
73
71
69
67
66
66
65
65
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
200
177
149
137
125
115
119
120
122
123
118
115
108
99
91
81
72
66
65
63
61
59
58
55
52
51
51
49
48
47
48
49
49
50
52
52
54
54
39
28
33
36
33
31
15
8
n/a
n/a
n/a
n/a
n/a
n/a
n/a
n/a
1
n/a
n/a
1489
1485
1483
1479
1477
1474
1472
1470
1469
1468
1466
1463
1461
1460
1459
1458
1455
1453
1451
1450
1449
1448
1447
1446
1446
1445
1445
1444
1443
1442
1441
1440
1440
1439
1439
1438
1438
1437
1435
1434
1432
1430
1.18
1.29
1.37
1.45
1.6
1.72
1.81
1.92
1.98
2.06
2.12
2.31
2.47
2.51
2.6
2.77
2.85
3.18
3.25
3.33
3.49
3.61
3.7
3.79
4.01
4.11
4.2
4.28
4.44
4.72
4.8
4.92
5.01
5.17
5.28
5.41
5.49
5.6
0.25 1739 1.25
0.25 1735 1.33
0.25 1732 1.45
0.25 1729 1.58
0.25 1726 1.71
0.25 1724 1.82
0.24 1722 1.91
0.23 1719 1.99
0.22 1718 2.06
0.22 1717 2.19
0.21 1716 2.22
0.20 1714 2.43
0.20 1711 2.65
0.20 1709 2.81
0.25 1988 1.32
0.25 1986 1.41
0.25 1982 1.54
0.25 1980 1.66
0.25 1977 1.78
0.25 1974 1.94
0.24 1971 2.01
0.24 2240 1.38 229
0.24 2238 1.49 201
0.24 2234 1.59 173
0.24 2230 1.73 166
0.24 2229 1.88 154
0.24 2227 2.01 143
0.23 2493 1.41
0.24 2490 1.55
0.25 2488 1.62
0.25 2485 1.76
0.25 2483 1.89
0.25 2481 2.03
0.23
0.25
0.27
0.27
0.26
0.27
0.25
0.24
0.22
0.21
0.21
0.20
0.20
0.22
0.23
0.23
0.24
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.24
0.24
0.24
0.24
0.24
0.24
0.23
0.23
0.21
0.20
0.20
0.19
0.19
0.19
0.21
0.23
0.19
0.14
0.14
0.14
0.16
0.18
0.18
0.19
0.23 2226
2.1
142
0.24 2479
2.1
0.23 1970
2.1
0.22 2225 2.23 141
0.21 2223 2.34 141
0.21 2222 2.41 140
0.20 2220 2.62 138
0.20 2219 2.76 132
0.20 2217 2.91 126
0.19 2216 3.15 121
0.19 2215 3.42 109
0.19 2214 3.58
0.19 2212 3.73
0.20 2211 3.89
0.20 2210 3.97
0.20 2210 4.12
0.20 2209 4.26
0.20 2209 4.45
0.19 2208 4.62
0.20 2207 4.81
0.20 2206 4.93
0.19 2206 5.21
0.23 2478 2.23
0.22 2477 2.35
0.21 2476 2.42
0.21 2475 2.65
0.22 1969 2.24
0.21 1968 2.33
0.21 1968 2.51
0.21 1966 2.62
0.20 1964 2.83
0.20 1963 2.98
0.20 1962 3.16
0.20 1960 3.32
0.20 1957 3.51
0.20 1956 3.75
0.20 1956 3.93
0.20 1956 4.02
0.20 1955 4.21
5.7
5.4
5.1
5
0.2
2474 2.81
0.19 2473 2.91
0.19 2471 3.16
0.2
4.9
4.7
4.6
4.5
4.5
4.4
4.4
4.4
4.3
4.3
4.3
4.2
4.2
4.1
4
3.9
3.9
3.8
3.8
3.7
3.7
3.6
3.6
3.5
3.4
3.3
3
2.8
2.7
2.6
2.5
2.4
2.3
2.2
2.2
2.1
2.1
2
1.9
1.8
1.8
1.8
1.75
0.20 1708
3
2469 3.42
0.20 1706 3.12
0.20 1705 3.25
0.20 1703 3.47
0.20 1702 3.62
0.19 1702 3.77
0.19 1701 3.99
0.19 1700 4.16
0.19 1700 4.31
0.19 1699 4.47
0.19 1698 4.62
0.19 1697 4.78
0.19 1697 4.91
0.19 1696 5.05
0.19 1696 5.11
0.19 1695 5.26
0.18 1694 5.38
92
85
78
75
73
72
70
69
68
66
65
63
62
61
60
60
60
59
58
57
56
55
56
45
0.21 2468 3.66
0.22 2467 3.73
0.24 2466 3.89
0.24 2466 4.03
0.24 2466 4.17
0.24 2465 4.21
0.24 2465 4.33
0.23 2464 4.49
0.23 2464 4.66
0.22 2464 4.92
0.23 2463 5.15
0.22 2463 5.25
0.22 2462 5.41
0.22 2462 5.66
0.22 2461 5.82
0.21 2461 5.86
0.21 2460
0.21 2460 5.95
0.2
0.2
0.19 2458 6.23
0.18 2458 6.29
0.18 2457 6.35
0.20 1952
4.4
0.20 1952 4.62
0.20 1951 4.76
0.20 1950 4.92
0.20 1950 5.18
0.20 1949 5.34
0.20 2205
5.4
0.19 1949
5.5
0.20 2205 5.62
0.20 2204 5.78
0.21 2204 5.94
0.20 2203 6.03
0.19 2203 6.11
0.18 2203 6.24
0.18 2202 6.35
0.19 1948 5.61
0.19 1948 5.77
0.19 1947 5.81
0.19 1947 5.93
0.18 1946 6.05
0.18 1946 6.11
0.18 1945 6.23
0.18 1945 6.45
0.18 1944 6.66
0.18 1944 6.72
0.18 1943 7.97
0.17 1942 10.03
0.15 1941 11.52
0.13 1940 13.36
0.14 1939 15.06
0.13 1938 16.85
0.14 1937 28.35
0.16 1936 40.16
0.15 1935 66.25
0.14 1934 92.97
0.17 1934 125
0.21 1934 180.3
0.17 1933 244.5
0.17 1932
0.18 1693
5.5
5.9
0.18 1692 5.63
0.18 1692 5.78
0.18 1691 5.91
0.18 1691 6.04
0.17 1691 6.11
0.17 1690 6.23
0.17 1689 7.48
0.17 1687 8.75
0.15 1686 10.21
0.13 1684 11.43
0.13 1683 12.25
0.13 1682 14.43
0.13 1681 19.07
0.14 1680 26.51
0.15 1679 32.66
0.15 1678 43.51
0.13 1671 63.2
0.15 1677 122
0.14 1676 154
0.14 1670
64
64
64
63
63
60
51
48
45
40
38
25
11
8
5
3
2459 6.01
2459 6.12
0.18 2202
6.4
0.19 2201 6.52
0.17 2201 6.67
0.17 2200 6.71
0.19 2200 8.11
0.21 2199 10.42 37
0.18 2198 11.88 36
0.14 2196 13.72 37
0.13 2195 15.24 35
0.13 2195 16.65 32
0.15 2194 31.08 15
0.17 2194 45.46
0.17 2192 81.07
0.18 2192 123.19
0.18 2191
0.19 2191
0.16 2191
6.59
7.43
8.27
9.41
0.2
2456
8.1
0.22 2456 10.07
0.18 2455 11.02
0.14 2454 12.85
0.15 2454 13.66
0.14 2453 15.32
0.16 2452 29.91
0.18 2452 39.54
0.2
0.2
0.2
0.18
0.161
0.16
0.16
0.16
0.16
0.16
0.155
91
88
85
79
60
41
36
29
18
17
20
12
11
9
7
5
6.8 0.1
7.5 0.1
8.2 0.1
9.1 0.1
1429 10.05
1428 11.64
1427 13.39
1425
1424 20.09
1423 24.14
1417
1422 39.55
1421 38.93
1416
1415
1411 83.13
56
52
33
21
19
13
5
2
10.0 1ꢀ
11.0 1ꢀ
12.0 1ꢀ
13.0 1ꢀ
14.0 1ꢀ
15.0 1ꢀ
16.0 1ꢀ
17.0 1ꢀ
18.0 1ꢀ
19.0 1ꢀ
20.0 1ꢀ
22.0 1ꢀ
17.6
8
5
3
2451 61.28
2450 82.44
6
4
48.3
1
2
79.3
77.6
0.16 2191
0.16 2191
0.16 2182
0.16 2181
0.16 2180
0.16 2178
0.14 1670
0.15 1675
0.15 1673
0.15 1673
0.17 1932
0.17 1932
0.16 1932
0.16 1930
1415
1415
1415.3 78.8
79.6
78.5
4
0.15 1670.5
0.15 1927.5
* Other tolerances are available, see page 8
13
®
®
Accu-F / Accu-P
0603 Typical Electrical Tables
Capacitance
Self
Ref
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
& Tolerance* Resonance Freq.
@ 1 MHz
(pF)
Frequency MHz
(GHz)
0.1 0.05
0.2 0.05
0.3 0.05
0.4 0.05
0.5 0.05
0.6 0.10
0.7 0.10
0.8 0.10
0.9 0.10
1.0 0.10
1.1 0.10
1.2 0.10
1.3 0.10
1.4 0.10
1.5 0.10
1.6 0.10
1.7 0.10
1.8 0.10
1.9 0.10
2.0 0.10
2.1 0.10
2.2 0.10
2.4 0.25
2.7 0.25
3.0 0.25
3.3 0.25
3.6 0.25
3.9 0.25
4.3 0.25
4.7 0.25
5.1 0.25
5.6 0.25
6.2 0.25
6.8 0.25
7.5 0.50
8.2 0.50
9.1 0.50
10 5ꢀ
18.0
12.7
10.4
9.0
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
491
490
487
486
485
484
483
482
479
478
477
475
474
471
468
465
459
456
455
451
448
445
443
439
435
432
429
425
422
420
418
416
414
412
410
408
404
403
402
401
400
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
738
736
734
732
731
729
727
725
723
721
720
718
717
713
709
706
699
697
695
692
689
686
684
680
677
675
672
670
667
665
663
661
660
659
657
656
654
653
652
651
650
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
987
985
981
974
977
976
973
971
969
967
966
964
962
958
954
951
945
942
940
937
935
931
929
927
925
925
921
919
917
916
914
913
912
911
910
908
906
905
905
904
904
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
1
8.1
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
7.4
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
6.8
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
6.4
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
6.0
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
5.7
5.4
5.2
5.0
4.8
4.7
4.5
4.4
4.2
4.1
4.0
3.9
3.8
3.7
3.5
3.3
3.1
3.0
2.9
2.7
2.6
2.5
2.4
2.3
2.2
2.1
2.0
1.9
1.8
1.7
1.6
1.6
1.5
1.5
1.4
1.3
1.2
1.2
1.1
1.0
1.0
245
244
243
242
241
241
240
240
239
239
238
237
236
234
232
230
226
224
223
220
218
216
214
211
208
205
202
200
195
191
189
187
185
182
179
176
170
168
165
163
160
1.15/0.90
1.25/1.00
1.35/1.10
1.45/1.15
1.55/1.25
1.65/1.35
1.75/1.45
1.85/1.55
2.10/1.70
2.15/1.78
2.11/1.80
2.25/1.95
2.40/2.05
2.70/2.15
3.00/2.45
3.40/2.75
3.60/3.05
3.90/3.30
4.20/3.65
4.60/4.00
5.00/4.45
5.40/4.85
5.90/5.35
6.50/5.95
7.20/6.55
8.10/7.00
8.80/7.70
9.80/8.60
10.70/9.50
11.60/10.90
12.90/11.40
13.10/12.90
14.90/13.25
15.90/14.25
17.00/15.15
19.50/17.00
24.00/20.90
26.00/22.80
29.00/25.60
32.00/28.50
37.65/31.35
.280
.270
.260
.260
.250
.250
.240
.230
.220
.210
.205
.200
.190
.175
.160
.150
.130
.128
.125
.122
.120
.115
.110
.105
.100
.095
.090
.090
.085
.085
.085
.080
.080
.080
.070
.070
.066
.066
.065
.064
.064
1.10/0.90
1.25/1.00
1.35/1.05
1.45/1.15
1.55/1.25
1.65/1.35
1.75/1.45
1.85/1.60
2.10/1.70
2.15/1.80
2.11/1.80
2.25/1.98
2.45/2.05
2.75/2.15
3.10/2.45
3.40/2.75
3.70/3.05
4.25/3.35
4.35/3.70
4.80/4.05
5.20/4.45
5.70/4.89
6.10/5.35
6.90/5.95
7.25/6.55
8.10/7.00
8.80/7.70
10.95/8.65
11.60/9.50
12.20/10.60
13.40/11.50
14.00/13.00
16.90/14.00
17.50/15.30
18.00/15.90
20.20/17.10
25.00/20.90
30.00/23.00
36.00/27.00
40.00/30.00
45.00/33.00
.220
.210
.200
.200
.190
.180
.180
.170
.160
.160
.155
.150
.145
.140
.125
.120
.120
.119
.115
.117
.110
.105
.100
.099
.099
.099
.098
.098
.097
.095
.095
.095
.090
.090
.085
.085
.080
.080
.080
.080
.080
1.10/0.90
1.11/1.00
1.40/1.05
1.45/1.15
1.45/1.25
1.65/1.35
1.75/1.45
1.85/1.60
2.10/1.70
2.15/1.80
2.11/1.80
2.35/1.98
2.42/2.05
2.80/2.15
3.10/2.45
3.40/2.75
3.70/3.05
3.90/3.35
4.90/3.75
5.10/4.05
5.30/4.50
6.00/4.90
6.15/5.40
7.10/6.00
7.50/6.60
8.20/7.00
9.00/7.70
12.00/9.00
12.50/9.60
13.20/10.50
14.60/11.90
16.00/13.50
19.00/15.00
21.00/16.50
22.00/17.00
23.70/19.00
28.00/21.00
N/A
.220
.210
.210
.200
.200
.190
.190
.180
.170
.167
.165
.162
.160
.150
.145
.140
.130
.125
.120
.115
.115
.115
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.100
.100
.100
.10
1.15/0.90
1.25/1.00
1.35/1.05
1.45/1.15
1.55/1.25
1.70/1.35
1.80/1.50
1.90/1.60
2.15/1.70
2.20/1.80
2.25/1.90
2.35/2.00
2.45/2.10
2.80/2.15
3.15/2.48
3.60/2.80
3.80/3.10
4.10/3.40
5.15/3.75
5.30/4.05
5.50/4.55
6.20/5.00
6.50/5.50
8.00/6.10
9.00/6.65
9.50/7.05
10.00/7.80
13.00/9.10
16.00/9.90
17.00/10.00
18.00/12.00
21.00/14.00
26.00/15.00
29.00/17.00
30.00/18.00
33.00/21.00
39.00/21.50
N/A
.300
.290
.280
.270
.260
.250
.250
.250
.250
.240
.230
.220
.210
.200
.190
.170
.165
.160
.150
.150
.145
.140
.135
.130
.130
.125
.125
.120
.120
.120
.120
.120
.120
.120
.120
.120
.120
.120
.120
.120
.120
11 5ꢀ
12 5ꢀ
13 5ꢀ
14 5ꢀ
15 5ꢀ
16 5ꢀ
18 5ꢀ
22 5ꢀ
24 5ꢀ
.10
27 5ꢀ
N/A
.10
N/A
30 5ꢀ
N/A
.10
N/A
33 5ꢀ
N/A
.10
N/A
* Other tolerances are available, see page 8
14
®
®
Accu-F / Accu-P
0805 Typical Electrical Tables
Capacitance
Ref
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
MHz
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Self
& Tolerance* Resonance Freq.
@ 1 MHz
(pF)
Frequency MHz
(GHz)
0.1 0.05
0.2 0.05
0.3 0.05
0.4 0.05
0.5 0.05
0.6 0.10
0.7 0.10
0.8 0.10
0.9 0.10
1.0 0.10
1.1 0.10
1.2 0.10
1.3 0.10
1.4 0.10
1.5 0.10
1.6 0.10
1.7 0.10
1.8 0.10
1.9 0.10
2.0 0.10
2.1 0.10
2.2 0.10
2.4 0.25
2.7 0.25
3.0 0.25
3.3 0.25
3.6 0.25
3.9 0.25
4.3 0.25
4.7 0.25
5.1 0.25
5.6 0.25
6.2 0.25
6.8 0.25
7.5 0.05
8.2 0.05
9.1 0.05
10 5ꢀ
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
500
496
492
488
487
486
484
483
482
481
479
477
475
473
470
465
463
462
459
456
451
447
444
442
435
434
432
429
423
420
418
416
414
414
411
408
406
405
403
401
400
399
397
396
395
394
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
750
754
739
734
733
731
729
728
726
724
722
720
716
714
711
707
704
704
701
697
691
688
684
683
677
675
673
670
668
665
663
662
661
660
659
657
656
655
654
652
651
650
649
648
647
646
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
999
993
987
980
979
977
975
974
972
970
967
964
962
960
957
952
948
947
944
940
936
934
930
927
925
924
922
920
918
916
915
914
913
912
911
910
908
907
907
906
905
904
903
902
901
900
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
1
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
5.6
5.4
5.1
4.9
4.8
4.6
4.5
4.3
4.2
4.1
4.0
3.9
3.8
3.6
3.4
3.3
3.1
3.0
2.9
2.7
2.6
2.5
2.4
2.3
2.2
2.1
2.0
1.9
1.8
1.8
1.6
1.6
1.5
1.5
1.4
1.3
1.3
1.2
1.2
1.1
1.0
1.0
0.9
0.9
0.9
0.8
250
248
245
243
242
242
241
240
239
239
238
237
236
235
233
231
229
228
227
223
220
218
215
212
208
206
203
199
196
193
190
187
184
182
179
176
173
171
168
165
163
159
157
155
153
152
1.20/0.90
1.30/1.00
1.40/1.10
1.50/1.20
1.60/1.30
1.70/1.40
1.80/1.50
1.90/1.60
2.00/1.70
2.10/1.80
2.20/1.90
2.30/2.00
2.40/2.10
2.85/2.15
3.19/2.45
3.51/2.75
3.83/3.05
4.16/3.35
4.48/3.65
4.91/4.05
5.35/4.45
5.78/4.85
6.00/5.35
7.00/5.95
7.20/6.55
8.64/7.00
9.40/7.70
10.37/8.60
11.00/9.50
12.50/10.45
13.61/11.40
14.75/12.35
15.88/13.30
17.02/14.25
18.16/15.20
20.42/17.10
22.70/19.00
24.95/20.90
27.20/22.80
30.78/25.69
34.23/28.50
37.85/31.35
41.19/34.20
44.79/37.05
49.99/40.85
55.19/44.65
.320
.290
.270
.260
.240
.230
.220
.210
.200
.200
.190
.190
.180
.170
.160
.150
.140
.140
.130
.130
.120
.120
.100
.100
.100
.100
.090
.080
.080
.080
.070
.070
.070
.070
.070
.070
.060
.060
.060
.060
.050
.050
.050
.050
.050
.050
1.20/0.90
1.30/1.00
1.40/1.10
1.50/1.20
1.60/1.20
1.70/1.40
1.85/1.50
1.95/1.60
2.05/1.70
2.15/1.80
2.30/1.90
2.40/2.00
2.60/2.10
3.13/2.29
3.47/2.55
3.76/2.86
4.04/3.10
4.35/3.42
4.67/3.72
5.11/4.13
5.52/4.53
5.94/4.94
6.82/5.40
7.52/6.00
8.21/6.88
9.02/7.10
9.83/7.90
10.88/8.76
11.92/9.76
13.23/10.50
14.50/11.90
15.80/13.00
17.22/14.00
18.56/15.19
19.90/16.28
22.69/18.57
25.38/20.78
28.08/21.00
31.31/25.61
36.10/32.20
40.58/33.20
46.65/35.00
52.22/38.00
59.08/47.08
70.50/53.04
81.99/59.00
.300
.270
.250
.230
.220
.210
.210
.200
.190
.190
.180
.170
.170
.170
.150
.140
.140
.130
.120
.120
.110
.110
.100
.100
.100
.100
.080
.080
.080
.080
.080
.080
.080
.080
.080
.070
.070
.070
.070
.070
.070
.070
.070
.070
.060
.060
1.20/0.90
1.30/1.00
1.40/1.10
1.50/1.10
1.60/1.20
1.70/1.40
2.00/1.50
2.05/1.60
2.10/1.70
2.25/1.80
2.40/1.90
2.60/2.00
2.80/2.14
3.17/2.30
3.52/2.60
3.84/2.93
4.15/3.19
4.50/3.53
4.85/3.86
5.32/4.25
5.79/4.60
6.25/5.20
7.27/5.60
8.08/6.10
8.90/6.96
9.85/7.50
10.80/8.25
12.02/9.10
13.24/10.00
15.07/11.00
16.90/12.82
18.87/14.00
20.84/16.00
22.62/19.13
27.00/20.89
33.00/22.10
38.00/23.15
42.00/24.00
N/A
.270
.250
.240
.230
.220
.220
.220
.210
.210
.200
.200
.190
.190
.190
.170
.160
.160
.150
.150
.150
.140
.140
.120
.120
.120
.120
.110
.110
.110
.110
.110
.110
.110
.110
.100
.100
.100
.100
.090
.090
.090
.090
.090
.090
.090
.090
1.20/0.90
1.30/1.00
1.40/1.10
1.50/1.20
1.60/1.30
1.70/1.40
2.00/1.50
2.20/1.60
2.30/1.70
2.40/1.80
2.60/1.95
2.80/2.06
3.06/2.17
3.31/2.31
3.67/2.60
4.00/3.00
4.38/3.30
4.80/3.60
5.23/3.90
5.79/4.50
6.36/4.80
7.16/5.74
8.25/5.90
9.35/6.80
10.46/7.32
11.75/8.42
13.04/9.53
14.70/10.70
15.37/11.80
16.00/12.20
N/A
.300
.290
.280
.270
.260
.260
.250
.240
.230
.230
.220
.210
.210
.210
.200
.190
.190
.190
.180
.180
.170
.160
.150
.150
.150
.150
.150
.150
.140
.140
.140
.140
.140
.130
.130
.130
.130
.130
.130
.130
.130
.120
.120
.120
.120
.110
11 5ꢀ
12 5ꢀ
13 5ꢀ
N/A
14 5ꢀ
N/A
15 5ꢀ
N/A
16 5ꢀ
N/A
18 5ꢀ
N/A
20 5ꢀ
N/A
22 5ꢀ
N/A
24 5ꢀ
N/A
27 5ꢀ
N/A
N/A
30 5ꢀ
N/A
N/A
33 5ꢀ
N/A
N/A
36 5ꢀ
N/A
N/A
39 5ꢀ
N/A
N/A
43 5ꢀ
N/A
N/A
47 5ꢀ
N/A
N/A
* Other tolerances are available, see page 8
15
®
Accu-P
1210 Typical Electrical Tables
Capacitance
Self
Ref
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
(MHz)
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
(MHz)
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
Ref
Freq.
(MHz)
Effective
Capacitance
Max/Min
(pF)
Max
ESR
(Ω)
& Tolerance* Resonance Freq.
@ 1 MHz
(pF)
Frequency (MHz)
(GHz)
1.0 0.25
1.2 0.25
1.5 0.25
1.8 0.25
2.2 0.25
2.7 0.25
3.3 0.25
3.6 0.25
3.9 0.25
4.3 0.25
4.7 0.25
5.1 0.25
5.6 0.25
6.2 0.25
6.8 0.25
7.5 0.25
8.2 0.25
9.1 0.25
10 5ꢀ
4.98
4.55
4.07
9.71
9.96
2.70
2.60
2.50
2.40
2.30
2.20
2.10
2.00
1.90
1.80
1.70
1.70
1.60
1.50
1.50
1.40
1.30
1.30
1.20
1.20
1.10
1.10
1.00
0.98
0.96
0.92
0.91
0.88
0.85
0.84
0.82
0.80
0.77
0.73
0.70
247
245
242
240
237
233
229
228
227
223
220
218
215
212
208
206
203
199
196
193
190
185
183
182
180
176
173
171
168
166
164
163
162
161
159
158
157
155
153
152
1.23/0.75
1.32/0.95
.350
.310
.250
.200
.170
.140
.140
.130
.130
.120
.120
.110
.110
.100
.100
.100
.100
.090
.090
.090
.080
.080
.080
.080
.080
.070
.070
.070
.070
.070
.070
.070
.070
.070
.060
.060
.060
.060
.060
.060
495
491
486
482
476
466
463
462
458
456
451
447
441
442
435
434
432
429
423
420
418
416
415
414
411
408
406
405
403
402
401
401
400
399
399
398
397
396
396
395
1.34/0.86
1.45/1.00
.260
.240
.230
.200
.170
.140
.130
.130
.120
.110
.110
.110
.100
.100
.100
.100
.090
.090
.090
.090
.080
.080
.080
.080
.080
.080
.080
.080
.080
.080
.070
.070
.070
.070
.070
.070
.070
.070
.070
.070
745
739
731
731
727
708
704
704
701
697
691
683
681
679
677
675
673
670
668
665
663
662
661
660
659
657
656
655
654
653
652
651
651
650
650
649
649
649
648
648
1.46/0.94
1.64/1.1
1.82/1.95
2.4/1.6
.280
.260
.250
.200
.180
.150
.140
.140
.140
.130
.130
.130
.120
.110
.110
.100
.100
.090
.090
.090
.090
.090
.090
.090
.090
.080
.080
.080
.080
.080
.080
.080
.080
.080
.080
.080
.070
.070
.070
.070
995
987
978
978
969
952
948
947
944
940
936
933
928
927
925
924
922
920
918
916
915
914
913
912
911
909
908
908
907
907
906
906
905
905
905
904
904
904
904
903
1.6/0.99
2.00/1.2
2.1/1.4
2.54/1.7
3.02/2.2
3.89/2.70
4.49/3.30
4.78/3.45
5.18/3.90
5.72/4.30
6.56/4.70
7.20/5.40
8.15/6.00
9.18/7.00
10.20/7.42
11.36/8.00
13.00/9.10
15.11/10.25
17.22/11.06
N/A
.350
.320
.270
.210
.200
.170
.160
.160
.150
.140
.140
.140
.140
.130
.130
.130
.130
.130
.130
.130
.120
.120
.120
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
.110
1.6/1.23
1.75/1.3
2.1/1.55
2.21/1.56
2.48/1.95
2.68/2.00
2.85/2.1
3.73/2.63
4.33/3.23
4.50/3.32
4.85/3.75
5.32/4.29
5.94/4.60
6.36/5.10
7.17/5.67
7.99/6.10
8.81/6.93
9.58/7.60
10.68/8.31
12.10/9.66
13.51/10.05
15.07/11.33
16.90/12.82
18.80/13.60
20.85/16.00
22.62/17.00
25.12/18.00
30.00/24.00
35.00/26.00
42.00/27.00
N/A
1
3.42/2.45
3.49/2.55
4.02/3.05
4.09/3.15
4.18/3.35
4.32/3.43
4.53/3.65
4.66/3.73
5.01/4.05
5.11/4.14
5.48/4.45
5.62/4.50
5.88/4.85
6.04/4.90
6.49/5.35
6.72/5.56
7.19/5.95
7.26/6.07
7.38/6.55
8.16/6.42
8.60/7.90
8.90/7.25
9.36/7.70
9.76/7.96
10.34/8.60
11.33/9.50
12.50/10.45
13.61/11.40
14.75/12.35
15.89/13.30
17.02/14.25
18.16/15.20
20.42/17.10
22.70/19.00
24.95/20.90
27.20/22.60
26.39/23.75
30.78/25.65
31.93/26.50
34.23/28.50
36.51/30.40
37.65/31.35
38.83/32.30
41.20/34.20
44.79/37.05
49.99/40.85
55.69/44.65
10.87/8.88
11.97/9.79
13.23/10.83
14.59/11.90
15.64/13.00
17.22/14.00
18.56/15.19
19.90/16.28
22.69/18.57
25.36/20.78
28.06/22.96
31.31/25.60
32.91/26.00
36.10/28.00
37.60/30.76
40.50/33.20
44.63/34.50
46.65/35.00
48.51/37.00
52.22/41.00
59.00/43.00
70.00/46.00
81.00/53.00
11 5ꢀ
12 5ꢀ
N/A
13 5ꢀ
N/A
14 5ꢀ
N/A
15 5ꢀ
N/A
16 5ꢀ
N/A
18 5ꢀ
N/A
20 5ꢀ
N/A
22 5ꢀ
N/A
24 5ꢀ
N/A
25 5ꢀ
N/A
N/A
27 5ꢀ
N/A
N/A
28 5ꢀ
N/A
N/A
30 5ꢀ
N/A
N/A
32 5ꢀ
N/A
N/A
33 5ꢀ
N/A
N/A
34 5ꢀ
N/A
N/A
36 5ꢀ
N/A
N/A
39 5ꢀ
N/A
N/A
43 5ꢀ
N/A
N/A
47 5ꢀ
N/A
N/A
* Other tolerances are available, see page 8
16
®
®
Accu-F / Accu-P
High Frequency Characteristics
Typical ESR vs. Frequency
®
Accu-P 0201
1±±±
9±±
8±±
7±±
0.8pF
1.8pF
6±±
5±±
1
4±±
3±±
2.2pF
3.3pF
2±±
1±±
4.7pF
6.8pF
±
5±±
1±±±
15±±
2±±±
25±±
3±±±
Frequency (MHzꢀ
Typical SRF vs. Capacitance
®
Accu-P 0201
8
7
6
5
4
3
2
1
±
3
4
5
6
7
8
9
1±
SRF (GHzꢀ
Typical Q vs. Frequency
®
Accu-P 0201
1±±±
±.8pF
Q
1±±
1.8pF
3.9pF
4.7pF
6.8pF
1±
5±±
1±±±
15±±
2±±±
25±±
3±±±
Frequency (MHzꢀ
17
®
®
Accu-F / Accu-P
High Frequency Characteristics
Typical ESR vs. Frequency
Typical ESR vs. Frequency
® ®
®
Accu-P 0402
Accu-F /Accu-P 0603
1
±.25
1.0pF
±.2
2.2pF
2.7pF
10pF
±.15
±.1
1
4.7pF
±.1
10pF
22pF
±.±5
±
±
5±±
1±±±
Frequency (MHzꢀ
Measured on Boonton 34A
15±±
2±±±
25±±
±.±1
±
±.5
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
1
1.5
2
2.5
3GHz
Typical Q vs. Frequency
Typical Q vs. Frequency
® ®
®
Accu-P 0402
Accu-F /Accu-P 0603
1±±±±
1±±±
1±±
1±
1±±±±
1±±±
1 pF
2.2 pF
4.7 pF
1±±
1±
10 pF
10pF
22pF
2.7pF
1
±
5±±
1±±±
15±±
2±±±
25±±
3±±±
±
±.5
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
1
1.5
2
2.5
3GHz
Frequency (MHzꢀ
Typical Self Resonant Frequency vs. Capacitance
Typical Self Resonant Frequency vs. Capacitance
®
®
®
Accu-F /Accu-P 0603
Accu-P 0402
GHz
10
8
7
6
5
4
3
2
1
±
1
±
2
4
6
8
1±
12
0.1
CAPACITANCE (pFꢀ
1
10
100
pF
Measured on Wiltron 36± Vector Analyzer
L (self inductance)
0.78 nH
~
NOTE
L and SRF are obtained from the measured increase in
effective capacitance as the frequency is increased
Measured on the Boonton 34-A
18
®
®
Accu-F / Accu-P
High Frequency Characteristics
Typical ESR vs. Frequency
Accu-F /Accu-P 0805
Typical ESR vs. Frequency
®
®
®
Accu-P 1210
1
1
1pF
1pF
3.3pF
3.3pF
±.1
1
±.1
10pF
33pF
33pF
±.±1
±.±1
±
±.5
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
1
1.5
2
2.5
3GHz
±
±.5
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
1
1.5
2
2.5
3GHz
Typical Q vs. Frequency
Accu-F /Accu-P 0805
Typical Q vs. Frequency
®
®
®
Accu-P 1210
1±±±±
1±±±
1±±±±
1±±±
1±±
1±
1±±
1±
1pF
1pF
3.3pF
3.3pF
2.5
10pF
10pF
33pF
33pF
±
±.5
1
1.5
2
3GHz
±
±.5
1
1.5
2
2.5
3GHz
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
Measured on Boonton 34-A
(34-A limits measurements to 3GHzꢀ
Typical Self Resonant Frequency vs. Capacitance
Typical Self Resonant Frequency vs. Capacitance
®
®
®
Accu-P 1210
Accu-F /Accu-P 0805
GHz
10
GHz
10
1
1
0.1
0.1
1
10
100
pF
1
10
100
pF
L (self inductance)
1.02 nH
~
L (self inductance)
NOTE
0.82 nH
~
NOTE
L and SRF are obtained from the measured increase in
L and SRF are obtained from the measured increase in
effective capacitance as the frequency is increased
effective capacitance as the frequency is increased
Measured on the Boonton 34-A
Measured on the Boonton 34-A
19
®
®
Accu-F / Accu-P
Environmental / Mechanical Characteristics
ENVIRONMENTAL CHARACTERISTICS
TEST
CONDITIONS
REQUIREMENT
Life (Endurance)
MIL-STD-202F Method 108A
125°C, 2UR,1000 hours
No visible damage
∆ C/C ≤ 2ꢀ for C≥5pF
∆ C ≤ 0.25pF for C<5pF
Accelerated Damp
85°C, 85ꢀ RH, UR, 1000 hours
No visible damage
Heat Steady State
MIL-STD-202F Method 103B
∆ C/C ≤ 2ꢀ for C≥5pF
∆ C ≤ 0.25pF for C<5pF
1
Temperature Cycling
MIL-STD-202F Method 107E
MIL-STD-883D Method 1010.7
-55°C to +125°C, 15 cycles – Accu-P®
-55°C to +125°C, 5 cycles – Accu-F®
No visible damage
∆ C/C ≤ 2ꢀ for C≥5pF
∆ C ≤ 0.25pF for C<5pF
Resistance to Solder Heat
IEC-68-2-58
260°C 5°C for 10 secs
C remains within initial limits
MECHANICAL CHARACTERISTICS
TEST
CONDITIONS
REQUIREMENT
Solderability
IEC-68-2-58
Components completely immersed in a
solder bath at 235°C for 2 secs.
Terminations to be well tinned, minimum 95ꢀ
coverage
Leach Resistance
IEC-68-2-58
Components completely immersed in a
solder bath at 260 5°C for 60 secs.
Dissolution of termination faces ≤15ꢀ of area
Dissolution of termination edges ≤25ꢀ of length
Adhesion
A force of 5N applied for 10 secs.
No visible damage
MIL-STD-202F Method 211A
Termination Bond Strength
IEC-68-2-21 Amend. 2
Tested as shown in diagram
No visible damage
∆ C/C ≤ 2ꢀ for C≥5pF
∆ C ≤ 0.25pF for C<5pF
D
D = 3mm Accu-P
D = 1mm Accu-F
45mm
45mm
Robustness of Termination
IEC-68-2-21 Amend. 2
A force of 5N applied for 10 secs.
55Hz to 2000Hz, 20G
No visible damage
No visible damage
High Frequency Vibration
MIL-STD-202F Method 201A,
®
204D (Accu-P only)
Storage
12 months minimum with components
stored in “as received” packaging
Good solderability
Average capacitance with histogram printout for
capacitance distribution;
QUALITY & RELIABILITY
Accu-P is based on well established thin-film technology
and materials.
®
IR and Breakdown Voltage distribution;
Temperature Coefficient;
Solderability;
• ON-LINE PROCESS CONTROL
Dimensional, mechanical and temperature stability.
This program forms an integral part of the production cycle
and acts as a feedback system to regulate and control
production processes. The test procedures, which are
integrated into the production process, were developed
after long research work and are based on the highly
developed semiconductor industry test procedures and
equipment. These measures help AVX to produce a con-
sistent and high yield line of products.
QUALITY ASSURANCE
The reliability of these thin-film chip capacitors has been
studied intensively for several years. Various measures
have been taken to obtain the high reliability required today
by the industry. Quality assurance policy is based on well
established international industry standards. The reliability
of the capacitors is determined by accelerated testing
under the following conditions:
• FINAL QUALITY INSPECTION
Life (Endurance)
Accelerated Damp
Heat Steady State
125°C, 2UR, 1000 hours
Finished parts are tested for standard electrical parameters
and visual/mechanical characteristics. Each production lot
is 100ꢀ evaluated for: capacitance and proof voltage at
2.5 UR. In addition, production is periodically evaluated for:
85°C, 85ꢀ RH, UR,
1000 hours.
2±
®
®
Accu-F / Accu-P
Performance Characteristics RF Power Applications
ESR and therefore RF heating. Values of ESR for
RF POWER APPLICATIONS
In RF power applications capacitor losses generate heat. Two
factors of particular importance to designers are:
®
Accu-P capacitors are significantly less than those of
ceramic MLC components currently available.
• Minimizing the generation of heat.
• Dissipating heat as efficiently as possible.
HEAT DISSIPATION
• Heat is dissipated from a capacitor through a variety of
paths, but the key factor in the removal of heat is the
thermal conductivity of the capacitor material.
• The higher the thermal conductivity of the capacitor, the
more rapidly heat will be dissipated.
CAPACITOR HEATING
1
• The major source of heat generation in a capacitor in RF
power applications is a function of RF current (I) and ESR,
from the relationship:
• The table below illustrates the importance of thermal
®
2
conductivity to the performance of Accu-P in power
Power dissipation = I RMS x ESR
applications.
®
• Accu-P capacitors are specially designed to minimize
PRODUCT
MATERIAL
Alumina
Magnesium Titanate
THERMAL CONDUCTIVITY W/mK
®
Accu-P
Microwave MLC
18.9
6.0
Power Handling
®
Accu-P 10pF
Amps
8
6
4
Data used in calculating the graph:
Thermal impedance of capacitors:
0402
0603
0805
1210
17°C/W
12°C/W
6.5°C/W
5°C/W
121±
1210
±8±5
0805
±6±3
±4±2
Thermal impedance measured using RF generator,
amplifier and strip-line transformer.
2
0
ESR of capacitors measured on Boonton 34A
0
200 400 600 800 1000 1200 1400MHz
The thermal impedance expresses the temperature difference
in °C between chip center and termination caused by
a power dissipation of 1 watt in the chip. It is expressed in
°C/W.
THERMAL IMPEDANCE
Thermal impedance of Accu-P chips is shown below com-
pared with the thermal impedance of Microwave MLC’s.
®
CAPACITOR TYPE
Accu-P®
CHIP SIZE
THERMAL IMPEDANCE (°C/W)
0805
1210
6.5
5
Microwave MLC
0505
1210
12
7.5
ADVANTAGES OF ACCU-P®
IN RF POWER CIRCUITS
The optimized design of Accu-P offers the designer of RF
power circuits the following advantages:
PRACTICAL APPLICATION
IN RF POWER CIRCUITS
®
• There is a wide variety of different experimental methods
for measuring the power handling performance of a
capacitor in RF power circuits. Each method has its
own problems and few of them exactly reproduce the
conditions present in “real” circuit applications.
• Similarly, there is a very wide range of different circuit appli-
cations, all with their unique characteristics and operating
conditions which cannot possibly be covered by such
“theoretical” testing.
• Reduced power losses due to the inherently low ESR of
®
Accu-P .
• Increased power dissipation due to the high thermal
®
conductivity of Accu-P .
• THE ONLY TRUE TEST OF A CAPACITOR IN ANY PARTICULAR
APPLICATION IS ITS PERFORMANCE UNDER OPERATING
CONDITIONS IN THE ACTUAL CIRCUIT.
21
®
®
Accu-F / Accu-P
Application Notes
GENERAL
HANDLING
®
®
Accu-F and Accu-P SMD capacitors are designed for
soldering to printed circuit boards or other substrates. The
construction of the components is such that they will with-
stand the time/temperature profiles used in both wave and
reflow soldering methods.
SMD capacitors should be handled with care to avoid damage
or contamination from perspiration and skin oils. The use of
plastic tipped tweezers or vacuum pick-ups is strongly recom-
mended for individual components. Bulk handling should
ensure that abrasion and mechanical shock are minimized. For
automatic equipment, taped and reeled product gives the
ideal medium for direct presentation to the placement
machine.
1
CIRCUIT BOARD TYPE
COMPONENT PAD DESIGN
®
The circuit board types which may be used with Accu-F and
Component pads must be designed to achieve good
joints and minimize component movement during reflow
soldering. Pad designs are given below for both wave and
reflow soldering.
®
Accu-P are as follows:
®
Accu-F : All flexible types of circuit boards
(eg. FR-4, G-10).
®
The basis of these designs is:
Accu-P : All flexible types of circuit boards
(eg. FR-4, G-10) and also alumina.
a. Pad width equal to component width. It is permissible to
decrease this to as low as 85ꢀ of component width but
it is not advisable to go below this.
For other circuit board materials, please consult factory.
b. Pad overlap 0.5mm beneath large components. Pad
overlap about 0.3mm beneath small components.
c. Pad extension of 0.5mm for reflow of large components
and pad extension about 0.3mm for reflow of small com-
ponents. Pad extension about 1.0mm for wave soldering.
WAVE SOLDERING
DIMENSIONS: millimeters (inches)
1.5
(±.±59ꢀ
1.5
(±.±59ꢀ
5.±
(±.197ꢀ
±.8
(±.±31ꢀ
±.26
1.2
(±.±47ꢀ
1.25
(±.±49ꢀ
4.±
(±.157ꢀ
(±.±1±ꢀ
2.±
(±.±79ꢀ
±.4±
1.±
(±.±39ꢀ
(±.±16ꢀ
2.1
(±.±83ꢀ
±.5
(±.±2±ꢀ
1.±6
(±.±42ꢀ
3.1
(±.122ꢀ
3.1
(±.122ꢀ
±.6
(±.±24ꢀ
±.7
(±.±28ꢀ
±.4±
(±.±16ꢀ
±.8
(±.±31ꢀ
±.34
(±.±13ꢀ
1.5
(±.±59ꢀ
1.25
(±.±49ꢀ
1.2
(±.±47ꢀ
1.5
(±.±59ꢀ
±.55
(±.±22ꢀ
1.25
(±.±49ꢀ
±.8
(±.±31ꢀ
±.8
(±.±31ꢀ
2.5
(±.±98ꢀ
0603
0805
1210
Accu-P®
0201
Accu-P®
0402
Accu-P®
0603
Accu-F®
Accu-P®
Accu-F®
Accu-P®
REFLOW SOLDERING
DIMENSIONS: millimeters (inches)
1.±
(±.±39ꢀ
1.±
4.±
(±.157ꢀ
±.26
(±.±1±ꢀ
±.8
±.85
(±.±39ꢀ
(±.±31ꢀ
(±.±33ꢀ
±.26
(±.±1±ꢀ
±.6
2.±
(±.±79ꢀ
3.±
(±.±24ꢀ
2.3
(±.±91ꢀ
2.3
(±.±91ꢀ
±.6
(±.±24ꢀ
(±.118ꢀ
±.7
(±.±28ꢀ
1.7
1.±
(±.±39ꢀ
±.78
(±.±3±ꢀ
±.5
(±.±68ꢀ
(±.±2±ꢀ
±.85
(±.±33ꢀ
±.8
(±.±31ꢀ
±.6
(±.±24ꢀ
±.34
(±.±13ꢀ
±.26
(±.±1±ꢀ
1.±
(±.±39ꢀ
1.±
(±.±39ꢀ
±.8
(±.±31ꢀ
±.8
(±.±31ꢀ
±.55
(±.±22ꢀ
1.25
(±.±49ꢀ
2.5
(±.±98ꢀ
0603
0805
1210
Accu-P®
0201
Accu-P®
0402
Accu-P®
0603
Accu-P®
Accu-F®
Accu-P®
Accu-F®
22
®
®
Accu-F / Accu-P
Application Notes
PREHEAT & SOLDERING
CLEANING RECOMMENDATIONS
The rate of preheat in production should not exceed 4°C/
second and a recommended maximum is about 2°C/second.
Temperature differential from preheat to soldering should not
exceed 100°C.
For further specific application or process advice, please consult
AVX.
Care should be taken to ensure that the devices are
thoroughly cleaned of flux residues, especially the space
beneath the device. Such residues may otherwise become
conductive and effectively offer a lossy bypass to the device.
Various recommended cleaning conditions (which must be
optimized for the flux system being used) are as follows:
Cleaning liquids. . . . . . . i-propanol, ethanol, acetylacetone,
water and other standard PCB
1
COOLING
cleaning liquids.
After soldering, the assembly should preferably be allowed
to cool naturally. In the event of assisted cooling, similar
conditions to those recommended for preheating should be
used.
Ultrasonic conditions . . power-20w/liter max.
frequency-20kHz to 45kHz.
Temperature . . . . . . . . . 80°C maximum (if not otherwise
limited by chosen solvent system).
Time . . . . . . . . . . . . . . . 5 minutes max.
HAND SOLDERING & REWORK
Hand soldering is permissible. Preheat of the PCB to 150°C is
required. The most preferable technique is to use hot air sol-
dering tools. Where a soldering iron is used, a temperature
controlled model not exceeding 30 watts should be used and
set to not more than 260°C.
STORAGE CONDITIONS
®
Recommended storage conditions for Accu-F and
®
Accu-P prior to use are as follows:
Temperature . . . . . . . . . . 15°C to 35°C
Humidity . . . . . . . . . . . . . ≤65ꢀ
Air Pressure . . . . . . . . . . 860mbar to 1060mbar
RECOMMENDED SOLDERING
PROFILE
IR REFLOW
WAVE SOLDERING
3–5 seconds
22±
26±
24±
22±
2±±
18±
16±
14±
12±
1±±
8±
6±
4±
Assembly exits heat–
21±
2±±
19±
18±
17±
16±
15±
14±
13±
12±
11±
1±±
9±
no forced cooldown
1±±°C
Additional soak time
to allow uniform
heating of the
substrate
Natural
Cooling
186°C solder melting
temperature
Assembly enters the
preheat zone
45-6± sec.
above solder
melting point
Enter Wave
Time (secondsꢀ
Soak time
2±
8±
1ꢀ Activates the flux
2ꢀ Allows center of board
temperatures to catch up with
corners
7±
±
1±
2±
3±
4±
5±
6±
7±
8±
9± 1±± 11± 12±
6±
5±
4±
3±
2±
±
±.5
1
1.5
2
2.5
3
3.5
4
4.5
Time (minsꢀ
VAPOR PHASE
Transfer from
preheat with
min. delay &
temp. loss
Preheat
Reflow
215°C
215°C
2±±
18±
16±
14±
12±
1±±
8±
2±±
18±
16±
14±
12±
1±±
8±
Duration varies
Natural
Cooling
with thermal mass
of assembly
1±–6± secs typical
Enter
Vapor
6±
6±
4±
4±
2±
2±
±
±
10
20
30
40
50
60
70
Time (minutesꢀ
Time (secondsꢀ
23
®
®
Accu-F /Accu-P
Automatic Insertion Packaging
TAPE & REEL
All tape and reel specifications are in compliance with EIA 481-1-A.
(equivalent to IEC 286 part 3).
• 8mm carrier
• Reeled quantities: Reels of 3,000 per 7" reel or 10,000 pieces per 13" reel
0201 and 0402 = 5,000 pieces per 7" reel and 20,000 pieces per 13" reel
1
REEL
DIMENSIONS: millimeters (inches)
(1)
A
B
C
D
E
F
G
180 1.0
(7.087 0.039)
1.5 min.
(0.059 min.)
13 0.2
(0.512 0.008)
20.2 min.
(0.795 min.)
50 min.
(1.969 min.)
9.6 1.5
(0.370 0.050)
14.4 max.
(0.567 max.)
Metric dimensions will govern.
Inch measurements rounded and for reference only.
(1ꢀ 33±mm (13 inchꢀ reels are available.
G MAX.
B*
C
A
E
F
D*
FULL RADIUS
*DRIVE SPOKES OPTIONAL
IF USED, ASTERISKED
DIMENSIONS APPLY.
CARRIER
DIMENSIONS: millimeters (inches)
A
B
C
D
E
F
+±.1
8.0 0.3
(0.315 0.012)
3.5 0.05
(0.138 0.002)
1.75 0.1
(0.069 0.004)
2.0 0.05
(0.079 0.002)
4.0 0.1
(0.157 0.004)
1.5-±.±
(0.059-±.±±±)
+±.±±4
NOTE: The nominal dimensions of the component compartment (W,Lꢀ are derived from the component size.
1± PITCHES
CUMULATIVE
E
TOLERANCE ON
TAPE ±.2
D
F
C
TOP
TAPE
W
B
A
L
P = 4mm except 0201 and 0402 where P = 2mm
P
CENTER LINES
OF CAVITY
DIRECTION OF FEED
NOTE: AVX reserves the right to change the information published herein without notice.
24
2
Thin-Film Technology
®
Accu-L L±6±3/L±8±5
Thin-Film RF/Microwave Inductors
25
®
Accu-L
SMD High-Q RF Inductor
2
1± nH Inductor (Top Viewꢀ
ACCU-L® TECHNOLOGY
The Accu-L SMD Inductor is based on thin-film multilayer
technology. This technology provides a level of control on the
electrical and physical characteristics of the component which
gives consistent characteristics within a lot and lot-to-lot.
®
®
The Accu-L inductor is particularly suited for the telecom-
munications industry where there is a continuing trend
towards miniaturization and increasing frequencies. The
Accu-L inductor meets both the performance and tolerance
®
requirements of present cellular frequencies 450MHz and
900MHz and of future frequencies, such as 1700MHz,
1900MHz and 2400MHz.
The original design provides small size, excellent high-
frequency performance and rugged construction for reliable
automatic assembly.
FEATURES
APPLICATIONS
• High Q
• Mobile Communications
• Satellite TV Receivers
• GPS
• RF Power Capability
• High SRF
• Low DC Resistance
• Ultra-Tight Tolerance on Inductance
• Standard 0603 and 0805 Chip Size
• Low Profile
• Vehicle Locations Systems
• Filters
• Matching Networks
• Rugged Construction
• Taped and Reeled
26
®
Accu-L 0603 and 0805
SMD High-Q RF Inductor
Operating/Storage
Temp. Range:
-55°C to +125°C
DIMENSIONS: millimeters (inches)
0603
0805
B
1.6±±.1±
2.11±±.1±
L
(±.±63±±.±±4ꢀ
±.81±±.1±
(±.±32±±.±±4ꢀ
(±.±83±±.±±4ꢀ
1.5±±.1±
(±.±59±±.±±4ꢀ
W
±.61±±.1±
(±.±24±±.±±4ꢀ
±.91±±.13
(±.±36±±.±±5ꢀ
T
T
top: ±.± +±.3/-±.±
(±.±+±.±12ꢀ
±.25±±.15
(±.±1±±±.±±6ꢀ
L
B
bottom:
±.35±±.2±
(±.±14±±.±±8ꢀ
HOW TO ORDER
L
0805
4R7
D
E
W
TR
Product
Inductor
Size
0603
0805
Termination
Code
Packaging
Code
TR = Tape and Reel
(3,000/reel)
Inductance
Expressed in nH
(2 significant digits +
number of zeros)
for
values <10nH,
letter R denotes
decimal point.
Example:
Tolerance
Specification
Code
2
for
®
L ≤ 4.7nH, L ≥ 10nH,
W = Nickel/
solder coated
E = Accu-L 0805
B = 0.1nH
C = 0.2nH
D = 0.5nH
G = 2ꢀ
J = 5ꢀ
technology
(Sn 63, Pb 37)
®
G = Accu-L 0603
technology
4.7nH<L<10nH,
C = 0.2nH
D = 0.5nH
22nH = 220
4.7nH = 4R7
ELECTRICAL SPECIFICATIONS TABLE FOR ACCU-L® 0603
DC
450 MHz
900 MHz
1900 MHz
2400 MHz
I
max
Test Frequency
Test Frequency
Test Frequency
Test Frequency
(mA)
DC
SRF min
(MHz)
R
max
Inductance
L (nH)
Q
Q
Q
Q
Available
(Ω)
L (nH)
L (nH)
L (nH)
Typical
Typical
Typical
Typical
Inductance Tolerance
(1)
1000
1000
1000
1000
750
750
500
500
300
300
300
300
300
300
1.2
1.5
1.8
2.2
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10.0
12.0
15.0
49
26
20
20
21
24
25
23
26
23
23
28
28
28
1.2
70
39
30
30
30
35
57
32
36
33
31
39
38
38
1.2
134
1.2
170
76
59
56
54
64
69
49
60
39
31
41
20
15
10000
10000
10000
10000
9000
8400
6500
5500
5000
4500
3800
3500
3000
2500
0.04
0.06
0.07
0.08
0.08
0.08
0.12
0.15
0.25
0.30
0.35
0.45
0.50
0.60
0.1, 0.2nH
0.1, 0.2nH
0.1, 0.2nH
0.1, 0.2nH
0.1, 0.2nH
0.1, 0.2, 0.5nH
0.1, 0.2, 0.5nH
0.1, 0.2, 0.5nH
0.2, 0.5nH
0.2, 0.5nH
0.2, 0.5nH
2ꢀ, 5ꢀ
1.54
1.74
2.2
2.7
3.33
3.9
4.68
5.65
6.9
8.4
10
1.52
1.73
2.24
2.75
3.39
4.06
4.92
5.94
7.3
63
50
49
48
56
60
46
54
47
35
47
30
30
1.52
1.72
2.24
2.79
3.47
4.21
5.2
6.23
8.1
12.1
10
11.8
14.1
25.9
14.1
17.2
49.8
2ꢀ, 5ꢀ
2ꢀ, 5ꢀ
13.2
16.2
Inductance and Q measured on Agilent 4291B / 4287 using the 16196A test fixture.
(1ꢀ
I
measured for 15°C rise at 25°C ambient temperature when soldered to FR-4 board.
DC
ELECTRICAL SPECIFICATIONS TABLE FOR ACCU-L® 0805
DC
450 MHz
900 MHz
1700 MHz
2400 MHz
I
max
Test Frequency
Test Frequency Test Frequency Test Frequency
(mA)
DC
SRF min
(MHz)
R max
Inductance
L (nH)
Q
Q
Q
Q
∆T = 15°C ∆T = 70°C
Available
(Ω)
L (nH)
L (nH)
L (nH)
Typical
Typical
Typical
Typical
Inductance Tolerance
(1)
(2)
1.2
1.5
1.8
2.2
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10
60
50
50
42
42
38
27
43
50
43
43
46
40
36
30
36
1.2
1.5
1.8
2.2
2.7
3.3
3.9
4.8
5.7
92
74
72
62
62
46
36
62
68
62
56
60
50
46
27
33
1.2
1.5
1.8
2.2
2.8
3.4
4.0
5.3
6.3
7.7
10.0
13.4
17.3
27
122
102
88
82
80
48
38
76
73
71
55
52
40
23
–
1.2
1.5
1.9
2.3
2.9
3.5
4.1
5.8
7.6
9.4
15.2
–
92
84
73
72
70
57
42
60
62
50
32
–
10000
10000
10000
10000
10000
10000
10000
5500
4600
4500
3500
2500
0.05
0.05
0.06
0.07
0.08
0.11
0.20
0.10
0.10
0.11
0.12
0.13
0.20
0.20
0.35
0.40
1000
1000
1000
1000
1000
750
750
750
750
750
750
750
750
750
500
500
2000
2000
2000
2000
2000
1500
1500
1500
1500
1500
1500
1500
1500
1000
1000
1000
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.1nH, 0.2nH, 0.5nH
0.5nH
0.5nH
0.5nH
2ꢀ, 5ꢀ
2ꢀ, 5ꢀ
2ꢀ, 5ꢀ
2ꢀ, 5ꢀ
2ꢀ, 5ꢀ
7.0
8.5
10.6
12.9
16.7
21.9
27.5
12
15
18
22
–
–
–
–
–
–
–
–
2400
2200
1700
1400
–
–
–
(1ꢀ IDC measured for 15°C rise at 25°C ambient temperature
(2ꢀ IDC measured for 7±°C rise at 25°C ambient temperature
L, Q, SRF measured on HP 4291A, Boonton 34A and Wiltron 36±
Vector Analyzer, RDC measured on Keithley 58± micro-ohmmeter.
27
®
Accu-L 0603 and 0805
SMD High-Q RF Inductor
L0603
Typical Q vs. Frequency
Typical Inductance vs. Frequency
L0603
L0603
18±
16±
14±
12±
1±±
1±
1
1.2nH
15nH
Q
1±±
8±
6±
8.2nH
6.8nH
1.5nH
5.6nH
4.7nH
3.3nH
2.2nH
4±
8.2nH
15nH
2±
1.8nH
±
1.2nH
±
1
2
3
±
±.5
1
1.5
2
2.5
3
Frequency (GHzꢀ
Frequency (GHzꢀ
2
Measured on AGILENT 4291B/4287
using the 16196A test fixture
Measured on AGILENT 4291B/4287
using the 16196A test fixture
L0805
Typical Inductance vs. Frequency
L0805
Typical Q vs. Frequency
L0805
140
100
10
1
120
1.2nH
100
1.5nH
22nH
80
1.8nH
15nH
10nH
5.6nH
60
5.6nH
1.8nH
10nH
40
15nH
20
22nH
0.01
0.1
1
10
0
0.1
1
10
Frequency (GHz)
Frequency (GHz)
Measured on HP4291A and
Boonton 34A Coaxial Line
Measured on HP4291A and
Wiltron 36± Vector Analyzer
Maximum Temperature Rise
at 25°C ambient temperature (on FR-4)
L0805
200
15nH
10nH 6.8nH 4.7nH
2.7nH
100
10
1
0
0.5
1
1.5
2
2.5
3
3.5
Current (A)
Temperature rise will typically be no higher than shown by the graph
28
®
Accu-L 0603 and 0805
SMD High-Q RF Inductor
FINAL QUALITY INSPECTION
Finished parts are tested for electrical parameters and visual/
mechanical characteristics.
Parts are 100ꢀ tested for inductance at 450MHz. Parts are
100ꢀ tested for RDC. Each production lot is evaluated on a
sample basis for:
• Q at test frequency
• Static Humidity Resistance: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
2
ENVIRONMENTAL CHARACTERISTICS
TEST
Solderability
CONDITIONS
REQUIREMENT
Terminations to be well tinned.
No visible damage.
Components completely immersed in
a solder bath at 235 5°C for 2 secs.
Leach Resistance
Components completely immersed in
Dissolution of termination faces
a solder bath at 260 5°C for 60 secs. ≤ 15ꢀ of area.
Dissolution of termination edges
≤ 25ꢀ of length.
Storage
Shear
12 months minimum with components Good solderability
stored in “as received” packaging.
Components mounted to a substrate.
A force of 5N applied normal to the
line joining the terminations and in
a line parallel to the substrate.
No visible damage
Rapid Change of
Temperature
Components mounted to a substrate.
5 cycles -55°C to +125°C.
Tested as shown in diagram
No visible damage
No visible damage
Bend Strength
1mm
deflection
45mm
45mm
Temperature
Coefficient of
Inductance
(TCL)
Component placed in
environmental chamber
-55°C to +125°C.
+0 to +125 ppm/°C
• 106
L2-L1
L1 (T2-T1)
TCL =
(typical)
T1 = 25°C
29
®
Accu-L 0805
Application Notes
HANDLING
PREHEAT & SOLDERING
SMD chips should be handled with care to avoid damage or
contamination from perspiration and skin oils. The use of
plastic tipped tweezers or vacuum pick-ups is strongly
recommended for individual components. Bulk handling
should ensure that abrasion and mechanical shock are min-
imized. For automatic equipment, taped and reeled product
is the ideal medium for direct presentation to the placement
machine.
The rate of preheat in production should not exceed
4°C/second. It is recommended not to exceed 2°C/
second.
Temperature differential from preheat to soldering should not
exceed 150°C.
For further specific application or process advice, please
consult AVX.
HAND SOLDERING & REWORK
CIRCUIT BOARD TYPE
Hand soldering is permissible. Preheat of the PCB to 100°C
is required. The most preferable technique is to use hot air
soldering tools. Where a soldering iron is used, a tempera-
ture controlled model not exceeding 30 watts should be
used and set to not more than 260°C. Maximum allowed
time at temperature is 1 minute. When hand soldering, the
base side (white side) must be soldered to the board.
All flexible types of circuit boards may be used (e.g. FR-4,
G-10) and also alumina.
2
For other circuit board materials, please consult factory.
COMPONENT PAD DESIGN
Component pads must be designed to achieve good joints
and minimize component movement during soldering.
COOLING
Pad designs are given below for both wave and reflow
soldering.
After soldering, the assembly should preferably be allowed to
cool naturally. In the event of assisted cooling, similar condi-
tions to those recommended for preheating should be used.
The basis of these designs is:
a. Pad width equal to component width. It is permissible
to decrease this to as low as 85ꢀ of component width
but it is not advisable to go below this.
CLEANING RECOMMENDATIONS
b. Pad overlap about 0.3mm.
Care should be taken to ensure that the devices are thor-
oughly cleaned of flux residues, especially the space beneath
the device. Such residues may otherwise become conduc-
tive and effectively offer a lossy bypass to the device. Various
recommended cleaning conditions (which must be optimized
for the flux system being used) are as follows:
c. Pad extension about 0.3mm for reflow.
Pad extension about 0.8mm for wave soldering.
WAVE SOLDERING
DIMENSIONS: millimeters (inches)
Cleaning liquids . . . . . . i-propanol, ethanol, acetylace-
tone, water, and other standard
PCB cleaning liquids.
1.3±
1.2
(±.±51ꢀ
(±.±47ꢀ
Ultrasonic conditions . . power – 20w/liter max.
frequency – 20kHz to 45kHz.
3.1
(±.122ꢀ
±.5±
(±.±2±ꢀ
1.4
3.8
Temperature. . . . . . . . . 80°C maximum (if not otherwise
limited by chosen solvent system).
(±.±55ꢀ
(±.15±ꢀ
1.3±
(±.±51ꢀ
Time. . . . . . . . . . . . . . . 5 minutes max.
1.2
0603
Accu-L
0805
Accu-L
(±.±47ꢀ
±.8
(±.±31ꢀ
®
®
1.5
(±.±59ꢀ
STORAGE CONDITIONS
®
Recommended storage conditions for Accu-L prior to use
are as follows:
REFLOW SOLDERING
DIMENSIONS: millimeters (inches)
Temperature. . . . . . . . . 15°C to 35°C
Humidity . . . . . . . . . . . ≤65ꢀ
Air Pressure . . . . . . . . . 860mbar to 1060mbar
±.7
±.9±
(±.±28ꢀ
(±.±35ꢀ
2.3
(±.±91ꢀ
±.5±
(±.±2±ꢀ
2.8
1.4
(±.11±ꢀ (±.±55ꢀ
±.9±
(±.±35ꢀ
0603
Accu-L
0805
Accu-L
RECOMMENDED SOLDERING
PROFILE
±.7
(±.±28ꢀ
®
®
±.8
(±.±31ꢀ
1.5
(±.±59ꢀ
For recommended soldering profile see page 23
3±
Thin-Film Technology
3
CP±4±2/CP±6±3/CP±8±5
and DB±8±5 3dB 9±°
Thin-Film RF/Microwave
Directional Couplers
31
Thin-Film Directional Couplers
CP0402 High Directivity LGA Termination
GENERAL DESCRIPTION
DIMENSIONS:
(Bottom View)
millimeters (inches)
ITF (Integrated Thin-Film) TECHNOLOGY
S
B
The ITF High Directivity LGA Coupler is based on thin-film multilayer
technology. The technology provides a miniature part with excellent high
frequency performance and rugged construction for reliable automatic
assembly.
A
The ITF Coupler is offered in a variety of frequency bands compatible
with various types of high frequency wireless systems.
L
APPLICATIONS
FEATURES
T
• Mobile Communications
• Satellite TV Receivers
• GPS
• Inherent Low Profile
• Self Alignment during Reflow
• Excellent Solderability
• Low Parasitics
W
• Vehicle Location Systems
• Wireless LAN’s
1.±±±±.±5
(±.±4±±±.±±2ꢀ
±.58±±.±4
(±.±23±±.±±2ꢀ
±.35±±.±5
(±.±14±±.±±2ꢀ
±.2±±±.±5
(±.±±8±±.±±2ꢀ
±.18±±.±5
(±.±±7±±.±±2ꢀ
±.±5±±.±5
(±.±±2±±.±±2ꢀ
• Better Heat Dissipation
L
A
B
S
3
• Operating/Storage Temp
-40°C to +85°C
W
• Power Rating 3W RF Cont
T
HOW TO ORDER
CP
0402
X
X
L
TR
****
Frequency
Style
Size
0402
Type
Sub Type
LGA
Packaging Code
Termination
L = LGA Sn90, Pb10
N = LGA Sn100
TR = Tape and Reel
(MHz)
Directional Coupler
QUALITY INSPECTION
TERMINALS (Top View)
Finished parts are 100ꢀ tested for electrical parameters and
visual characteristics. Each production lot is evaluated on a
sample basis for:
5± OHM
OUT
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
TERMINATION
Sn90Pb10 or Lead-Free Sn100 Nickel/Solder coating
compatible with automatic soldering technologies: reflow,
wave soldering, vapor phase and manual.
COUPLING
IN
Recommended Pad Layout Dimensions
mm (inches)
ORIENTATION IN TAPE
0.63
(0.025)
5±
5±
OUT
IN
OUT
IN
OHM
OHM
0.25
(0.010)
CP
CP
0.39
(0.015)
1.18
(0.046)
*The recommended distance to the PCB Ground Plane is ±.254mm (±.±1±"ꢀ
32
Thin-Film Directional Couplers
CP0402 High Directivity LGA Termination
COUPLER TYPE SELECTION GRAPH
Coupling vs. Frequency
0
CP0402A
CP0402A
CP0402A
CP0402A
CP0402A
CP0402A
AL
BL
CL
DL
EL
FL
****
****
****
****
****
****
-5
-10
-15
-20
-25
3
-30
-35
-40
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
Frequency (GHz)
Intermediate coupling factors are readily available.
Please contact factory.
33
Thin-Film Directional Couplers
CP0402 High Directivity LGA Termination
Coupler P/N CP0402AxxxxAL
CP0402AxxxxALTR
±
±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12
-16
-1±.±
-2±.±
[MHz]
[dB]
32
CP±4±2A±836AL 824 - 849
CP±4±2A±881AL 869 - 894
CP±4±2A±9±2AL 89± - 915
CP±4±2A±947AL 935 - 96±
CP±4±2A±897AL 88± - 915
CP±4±2A±942AL 925 - 96±
CP±4±2A1441AL 1429 - 1453 14.5±
CP±4±2A1747AL 171± - 1785 13.±±
CP±4±2A1842AL 18±5 - 188± 12.5±
CP±4±2A188±AL 185± - 191± 12.3±
CP±4±2A196±AL 193± - 199± 12.±±
19.1±
18.6±
18.5±
18.±±
18.5±
18.±±
Coupling
AMPS
GSM
R. Loss
±.25
±.4±
31
-3±.±
-4±.±
E-GSM
PDC
Isolation
28
26
21
PCN
-2±
-24
-5±.±
-6±.±
PCS
±.5±
±.7±
25
23
±.8
1.6
2.4
3.2
4.±
PHP
DECT
CP±4±2A19±7AL 1895 - 192±
CP±4±2A189±AL 188± - 19±±
12.3±
Frequency (GHzꢀ
Wireless LAN CP±4±2A2442AL 24±± - 2484 1±.3±
3
Coupler P/N CP0402AxxxxBL
CP0402AxxxxBLTR
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[MHz]
[dB]
max. Loss
[dB]
[dB]
-2.±
-4.±
-6.±
-8.±
[dB]
CP±4±2A±836BL 824 - 849
CP±4±2A±881BL 869 - 894
CP±4±2A±9±2BL 89± - 915
CP±4±2A±947BL 935 - 96±
CP±4±2A±897BL 88± - 915
CP±4±2A±942BL 925 - 96±
22.±±
21.7±
21.5±
21.±±
21.5±
21.±±
AMPS
GSM
Coupling
R. Loss
±.2±
28
±.25
±.2±
27
28
27
24
-3±.±
-4±.±
E-GSM
PDC
±.25
±.3±
CP±4±2A1441BL 1429 - 1453 17.5±
CP±4±2A1747BL 171± - 1785 16.±±
27
Isolation
PCN
CP±4±2A1842BL 18±5 - 188±
CP±4±2A188±BL 185± - 191±
-1±.±
-12.±
-5±.±
-6±.±
23
15.5±
PCS
CP±4±2A196±BL 193± - 199± 15.±±
±.35
±.4±
22
23
21
±.8
1.6
2.4
3.2
4.±
PHP
DECT
CP±4±2A19±7BL 1895 - 192±
CP±4±2A189±BL 188± - 19±±
15.5±
Frequency (GHzꢀ
Wireless LAN CP±4±2A2442BL 24±± - 2484 13.3±
Coupler P/N CP0402AxxxxCL
CP0402AxxxxCLTR
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-2.±
-4.±
-6.±
-8.±
[MHz]
[dB]
Coupling
R. Loss
CP±4±2A±836CL 824 - 849
CP±4±2A±881CL 869 - 894
CP±4±2A±9±2CL 89± - 915
CP±4±2A±947CL 935 - 96±
CP±4±2A±897CL 88± - 915
CP±4±2A±942CL 925 - 96±
23.6±
23.±±
AMPS
GSM
33
26
33
25
32
31
±.2±
22.5±
23.±±
22.5±
22
-3±.±
-4±.±
E-GSM
PDC
CP±4±2A1441CL 1429 - 1453 19.±±
CP±4±2A1747CL 171± - 1785 17.2±
CP±4±2A1842CL 18±5 - 188± 17.±±
CP±4±2A188±CL 185± - 191± 16.8±
CP±4±2A196±CL 193± - 199± 16.5±
Isolation
PCN
-1±.±
-12.±
-5±.±
-6±.±
3±
±.25
±.45
3±
PCS
29
±.8
1.6
2.4
3.2
4.±
PHP
DECT
CP±4±2A19±7CL 1895 - 192±
CP±4±2A189±CL 188± - 19±±
16.8±
Frequency (GHzꢀ
3±
28
Wireless LAN CP±4±2A2442CL 24±± - 2484 14.7±
Important: Couplers can be used at any frequency within the indicated range.
34
Thin-Film Directional Couplers
CP0402 High Directivity LGA Termination
Coupler P/N CP0402AxxxxDL
CP0402AxxxxDLTR
I. Loss
±
±
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-2.±
-4.±
-6.±
-8.±
-1±.±
-2±.±
[MHz]
[dB]
29
Coupling
R. Loss
CP±4±2A±836DL 824 - 849
CP±4±2A±881DL 869 - 894
CP±4±2A±9±2DL 89± - 915
CP±4±2A±947DL 935 - 96±
CP±4±2A±897DL 88± - 915
CP±4±2A±942DL 925 - 96±
25.2±
24.8±
24.7±
24.1±
24.7±
24.1±
AMPS
GSM
28
2±
-3±.±
-4±.±
±.2±
E-GSM
PDC
CP±4±2A1441DL 1429 - 1453 2±.5±
CP±4±2A1747DL 171± - 1785 19.±±
CP±4±2A1842DL 18±5 - 188± 18.5±
CP±4±2A188±DL 185± - 191± 18.2±
CP±4±2A196±DL 193± - 199± 18.±±
CP±4±2A19±7DL 1895 - 192± 18.1±
CP±4±2A189±DL 188± - 19±± 18.2±
25
24
Isolation
PCN
-1±.±
-12.±
-5±.±
-6±.±
PCS
±.25
±.35
23
22
23
±.8
1.6
2.4
3.2
4.±
PHP
DECT
Frequency (GHzꢀ
Wireless LAN CP±4±2A2442DL 24±± - 2484 16.±±
3
Coupler P/N CP0402AxxxxEL
CP0402AxxxxELTR
I. Loss
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-2.±
-4.±
-6.±
-8.±
[MHz]
[dB]
35
Coupling
R. Loss
CP±4±2A±836EL 824 - 849
CP±4±2A±881EL 869 - 894
CP±4±2A±9±2EL 89± - 915
CP±4±2A±947EL 935 - 96±
CP±4±2A±897EL 88± - 915
CP±4±2A±942EL 925 - 96±
27.2±
26.8±
26.5±
26.±±
26.5±
26.±±
AMPS
GSM
±.2±
34
25
-3±.±
-4±.±
E-GSM
PDC
CP±4±2A1441EL 1429 - 1453 22.3±
CP±4±2A1747EL 171± - 1785 2±.5±
CP±4±2A1842EL 18±5 - 188± 2±.3±
CP±4±2A188±EL 185± - 191±
29
27
Isolation
PCN
-1±.±
-12.±
-5±.±
-6±.±
±.25
±.35
PCS
CP±4±2A196±EL 193± - 199±
CP±4±2A19±7EL 1895 - 192±
26
23
23
2±.±±
±.8
1.6
2.4
3.2
4.±
4.8
5.6
6.4
PHP
DECT
Frequency (GHzꢀ
CP±4±2A189±EL 188± - 19±±
Wireless LAN CP±4±2A2442EL 24±± - 2484 18.±±
Coupler P/N CP0402AxxxxFL
CP0402AxxxxFLTR
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-1.±
-2.±
-3.±
-4.±
[MHz]
[dB]
29.1±
28.6±
28.5±
28.1±
28.5±
28.1±
CP±4±2A±836FL
CP±4±2A±881FL
CP±4±2A±9±2FL
CP±4±2A±947FL
CP±4±2A±897FL
CP±4±2A±942FL
CP±4±2A1441FL 1429 - 1453 26.5±
CP±4±2A1747FL 171± - 1785 25.±±
CP±4±2A1842FL 18±5 - 188± 24.5±
CP±4±2A188±FL 185± - 191± 24.2±
CP±4±2A196±FL 193± - 199± 24.±±
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
31.±±
3±.7±
3±.6±
3±.±±
3±.6±
3±.±±
Coupling
R. Loss
AMPS
GSM
-3±.±
-4±.±
E-GSM
PDC
±.2± 25.±±
23.8±
11
Isolation
PCN
23.6±
23.5±
23.3±
23.4±
-5±.±
-6±.±
-5.±
-6.±
PCS
±.8
1.6
2.4
3.2
4.±
4.8
5.6
6.4
PHP
CP±4±2A19±7FL 1895 - 192±
CP±4±2A189±FL 188± - 19±±
24.2±
DECT
23.5±
Frequency (GHzꢀ
Wireless LAN CP±4±2A2442FL 24±± - 2484 22.±±
±.25 22.6±
Important: Couplers can be used at any frequency within the indicated range.
35
Thin-Film Directional Couplers
CP0603 High Directivity LGA Termination
GENERAL DESCRIPTION
ITF (Integrated Thin-Film) TECHNOLOGY
DIMENSIONS:
(Bottom View)
millimeters (inches)
S
The ITF LGA Coupler is based on thin-film multilayer technology.
The technology provides a miniature part with excellent high frequency
performance and rugged construction for reliable automatic assembly.
B
A
The ITF Coupler is offered in a variety of frequency bands compatible
with various types of high frequency wireless systems.
FEATURES
APPLICATIONS
L
• Inherent Low Profile
• Self Alignment during Reflow
• Excellent Solderability
• Low Parasitics
• Mobile Communications
• Satellite TV Receivers
• GPS
T
• Vehicle Location Systems
• Wireless LAN’s
W
• Better Heat Dissipation
1.6±±±.1±
(±.±63±±.±±4ꢀ
±.84±±.1±
(±.±33±±.±±4ꢀ
±.25±±.±5
A
• Operating/Storage Temp
-40°C to +85°C
L
(±.±1±±±.±±2ꢀ
3
±.2±±±.±5
W
B
• Power Rating 3W RF Cont
(±.±±8±±.±±2ꢀ
±.6±±±.1±
(±.±24±±.±±4ꢀ
±.±5±±.±5
(±.±±2±±.±±2ꢀ
T
S
HOW TO ORDER
CP
0603
X
L
TR
X
****
Frequency
Type
Style
Size
Sub Type
Termination
Code
Packaging Code
0603
TR = Tape and Reel
(MHz)
Directional Coupler
L = LGA Sn90, Pb10
N = LGA Sn100
QUALITY INSPECTION
TERMINALS (Top View)
Finished parts are 100ꢀ tested for electrical parameters and
visual characteristics. Each production lot is evaluated on a
sample basis for:
50 OHM
OUT
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
TERMINATION
Sn90Pb10 or Lead-Free Sn100 Nickel/Solder coating
compatible with automatic soldering technologies: reflow,
wave soldering, vapor phase and manual.
COUPLING
IN
Recommended Pad Layout Dimensions
mm (inches)
ORIENTATION IN TAPE
1.1±
5±
5±
OUT
IN
OUT
IN
(±.±43ꢀ
OHM
OHM
±.4±
(±.±16ꢀ
CP
CP
±.5±
(±.±2±ꢀ
1.75 (±.±69ꢀ
*The recommended distance to the PCB Ground Plane is ±.254mm (±.±1±"ꢀ
36
Thin-Film Directional Couplers
CP0603 High Directivity LGA Termination
COUPLER TYPE SELECTION GRAPH
Coupling vs. Frequency
0
-5
-10
-15
-20
3
CP0603A
CP0603A
CP0603A
CP0603A
CP0603A
CP0603A
CP0603A
CP0603A
CP0603A
CL
HL
AL
DL
BL
ML
EL
FL
****
****
****
****
****
****
****
****
****
-25
-30
-35
-40
GL
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
Frequency (GHz)
Intermediate coupling factors are readily available.
Please contact factory.
37
Thin-Film Directional Couplers
CP0603 High Directivity LGA Type
Coupler P/N CP0603AxxxxAL
CP0603AxxxxALTR
±0
±0
I. Loss
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[MHz]
[dB]
max. Loss
[dB]
--11±0..±0
--22±0..±0
--44
[dB]
[dB]
Coupling
CP±6±3A±836AL 824 - 849
CP±6±3A±881AL 869 - 894
CP±6±3A±9±2AL 89± - 915
CP±6±3A±947AL 935 - 96±
CP±6±3A±897AL 88± - 915
CP±6±3A±942AL 925 - 96±
CP±6±3A1441AL 1429 - 1453
CP±6±3A1747AL 171± - 1785
CP±6±3A1842AL 18±5 - 188±
CP±6±3A188±AL 185± - 191±
CP±6±3A196±AL 193± - 199±
CP±6±3A19±7AL 1895 - 192±
CP±6±3A189±AL 188± - 19±±
2±.±
19.7
19.4
19.±
19.4
19.±
15.5
14.±
13.5
13.2
13.±
--88
AMPS
GSM
28
R. Loss
27
--1122
--1166
--33±0..±0
--44±0..±0
±.25
28
27
24
Isolation
E-GSM
PDC
±.4±
±.5±
22
--55±0..±0
--66±0..±0
--22±0
--2244
PCN
22
PCS
±.55
±.5±
±.75
21
22
2±
±0..88
11..66
22..44
33..22
44..±0
PHP
DECT
FFrreeqquueennccyy ((GGHHzzꢀ)
13.2
11.5
Wireless LAN CP±6±3A2442AL 24±± - 2484
3
Coupler P/N CP0603AxxxxBL
CP0603AxxxxBLTR
0
0
-10.0
-20.0
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4
[MHz]
[dB]
Coupling
R. Loss
CP±6±3A±836BL 824 - 849
CP±6±3A±881BL 869 - 894
CP±6±3A±9±2BL 89± - 915
CP±6±3A±947BL 935 - 96±
CP±6±3A±897BL 88± - 915
CP±6±3A±942BL 925 - 96±
CP±6±3A1441BL 1429 - 1453
CP±6±3A1747BL 171± - 1785
CP±6±3A1842BL 18±5 - 188±
CP±6±3A188±BL 185± - 191±
CP±6±3A196±BL 193± - 199±
CP±6±3A19±7BL 1895 - 192±
CP±6±3A189±BL 188± - 19±±
23.±
22.7
22.5
22.±
22.5
22.±
18.5
17.±
16.4
16.2
16.±
16.1
16.2
14.2
AMPS
GSM
-8
31
±.2±
29
3±
31
3±
27
-12
-16
-30.0
-40.0
Isolation
E-GSM
PDC
PCN
-50.0
-60.0
-20
-24
25
±.25
±.35
PCS
24
25
23
24
0.8
1.6
2.4
3.2
4.0
PHP
DECT
Frequency (GHz)
Wireless LAN CP±6±3A2442BL 24±± - 2484
Coupler P/N CP0603AxxxxCL
CP0603AxxxxCLTR
±
±
-1±.±
-2±.±
I. Loss
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
Coupling
R. Loss
CP±6±3A±836CL 824 - 849
CP±6±3A±881CL 869 - 894
CP±6±3A±9±2CL 89± - 915
CP±6±3A±947CL 935 - 96±
CP±6±3A±897CL 88± - 915
CP±6±3A±942CL 925 - 96±
CP±6±3A1441CL 1429 - 1453
CP±6±3A1747CL 171± - 1785
CP±6±3A1842CL 18±5 - 188±
CP±6±3A188±CL 185± - 191±
CP±6±3A196±CL 193± - 199±
CP±6±3A19±7CL 1895 - 192±
CP±6±3A189±CL 188± - 19±±
15.2
15.±
14.7
14.3
14.7
14.3
11.±
9.5
AMPS
GSM
±.35
23
-3±.±
-4±.±
±.4±
±.35
±.4±
±.7±
±.8±
22
23
22
19
18
23
Isolation
E-GSM
PDC
-5±.±
-6±.±
-2±.±
-24.±
PCN
9.±
8.8
8.5
±.9±
1.±±
±.9±
1.4±
PCS
17
15
21
±.8
1.6
2.4
3.2
4.±
PHP
DECT
Frequency (GHzꢀ
8.8
7.±
Wireless LAN CP±6±3A2442CL 24±± - 2484
Important: Couplers can be used at any frequency within the indicated range.
38
Thin-Film Directional Couplers
CP0603 High Directivity LGA Type
Coupler P/N CP0603AxxxxDL
CP0603AxxxxDLTR
±
±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[MHz]
[dB]
max. Loss
[dB]
-1±.±
-2±.±
-1.±
-2.±
-3.±
-4.±
[dB]
[dB]
Coupling
R. Loss
CP±6±3A±836DL 824 - 849
CP±6±3A±881DL 869 - 894
CP±6±3A±9±2DL 89± - 915
CP±6±3A±947DL 935 - 96±
CP±6±3A±897DL 88± - 915
CP±6±3A±942DL 925 - 96±
CP±6±3A1441DL 1429 - 1453
CP±6±3A1747DL 171± - 1785
CP±6±3A1842DL 18±5 - 188±
CP±6±3A188±DL 185± - 191±
CP±6±3A196±DL 193± - 199±
CP±6±3A19±7DL 1895 - 192±
CP±6±3A189±DL 188± - 19±±
22.±
21.8
21.3
21.±
21.3
21.±
17.7
16.±
15.4
15.2
15.±
31
AMPS
GSM
±.25
±.3±
±.25
±.3±
3±
3±
-3±.±
-4±.±
E-GSM
PDC
Isolation
27
25
PCN
-5±.±
-6±.±
-5.±
-6.±
±.4±
±.55
PCS
25
±.8
1.6
2.4
3.2
4.±
24
22
PHP
DECT
15.2
13.3
Frequency (GHzꢀ
Wireless LAN CP±6±3A2442DL 24±± - 2484
3
Coupler P/N CP0603AxxxxEL
CP0603AxxxxELTR
I. Loss
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
Coupling
R. Loss
CP±6±3A±836EL 824 - 849
CP±6±3A±881EL 869 - 894
CP±6±3A±9±2EL 89± - 915
CP±6±3A±947EL 935 - 96±
CP±6±3A±897EL 88± - 915
CP±6±3A±942EL 925 - 96±
CP±6±3A1441EL 1429 - 1453
CP±6±3A1747EL 171± - 1785
CP±6±3A1842EL 18±5 - 188±
CP±6±3A188±EL 185± - 191±
CP±6±3A196±EL 193± - 199±
CP±6±3A19±7EL 1895 - 192±
CP±6±3A189±EL 188± - 19±±
25.8
25.3
25.±
24.7
26.±
24.7
22.±
19.5
19.±
18.8
18.5
18.7
18.8
17.±
AMPS
GSM
32
-3±.±
-4±.±
±.2±
±.25
31
32
31
28
Isolation
E-GSM
PDC
21
-5±.±
-6±.±
-2±.±
-24.±
PCN
PCS
±.3±
±.4±
26
24
±.8
1.6
2.4
3.2
4.±
4.8
5.6
6.4
Frequency (GHzꢀ
PHP
DECT
Wireless LAN CP±6±3A2442EL 24±± - 2484
Coupler P/N CP0603AxxxxFL
CP0603AxxxxFLTR
±
±
-1±.±
-2±.±
I. Loss
Frequency Coupling I. Loss Return Directivity
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
Coupling
CP±6±3A±836FL
CP±6±3A±881FL
CP±6±3A±9±2FL
CP±6±3A±947FL
CP±6±3A±897FL
CP±6±3A±942FL
CP±6±3A1441FL 1429 - 1453
CP±6±3A1747FL 171± - 1785
CP±6±3A1842FL 18±5 - 188±
CP±6±3A188±FL 185± - 191±
CP±6±3A196±FL 193± - 199±
CP±6±3A19±7FL 1895 - 192±
CP±6±3A189±FL 188± - 19±±
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
31.2
3±.8
3±.5
3±.2
3±.5
3±.2
27.±
25.±
26.5
24.3
24.±
AMPS
GSM
38
R. Loss
±.2±
-3±.±
-4±.±
37
Isolation
E-GSM
PDC
33
31
12
-5±.±
-6±.±
-2±.±
-24.±
PCN
PCS
±.25
±.8
1.6
2.4
3.2
4.±
4.8
5.6
6.4
3±
31
3±
Frequency (GHzꢀ
PHP
DECT
24.2
21.5
Wireless LAN CP±6±3A2442FL 24±± - 2484
Important: Couplers can be used at any frequency within the indicated range.
39
Thin-Film Directional Couplers
CP0603 High Directivity LGA Type
Coupler P/N CP0603AxxxxGL
CP0603AxxxxGLTR
±
±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-1±.±
-2±.±
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
CP±6±3A±836GL 824 - 849
CP±6±3A±881GL 869 - 894
CP±6±3A±9±2GL 89± - 915
CP±6±3A±947GL 935 - 96±
CP±6±3A±897GL 88± - 915
CP±6±3A±942GL 925 - 96±
CP±6±3A1441GL 1429 - 1453
CP±6±3A1747GL 171± - 1785
CP±6±3A1842GL 18±5 - 188±
CP±6±3A188±GL 185± - 191±
CP±6±3A196±GL 193± - 199±
CP±6±3A19±7GL 1895 - 192±
CP±6±3A189±GL 188± - 19±±
34.2
33.8
33.6
33.2
33.6
33.2
3±.±
28.5
28.±
27.7
27.5
27.6
27.7
25.5
AMPS
GSM
39
Coupling
±.2±
38
39
38
34
-3±.±
-4±.±
R. Loss
E-GSM
PDC
13
Isolation
PCN
-5±.±
-6±.±
-2±.±
-24.±
32
PCS
±.25
31
32
31
±.8
1.6
2.4
3.2
4.±
4.8
5.6
6.4
PHP
DECT
Frequency (GHzꢀ
Wireless LAN CP±6±3A2442GL 24±± - 2484
3
Coupler P/N CP0603AxxxxHL
CP0603AxxxxHLTR
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
26
CP±6±3A±836HL 824 - 849
CP±6±3A±881HL 869 - 894
CP±6±3A±9±2HL 89± - 915
CP±6±3A±947HL 935 - 96±
CP±6±3A±897HL 88± - 915
CP±6±3A±942HL 925 - 96±
CP±6±3A1441HL 1429 - 1453
CP±6±3A1747HL 171± - 1785
CP±6±3A1842HL 18±5 - 188±
CP±6±3A188±HL 185± - 191±
CP±6±3A196±HL 193± - 199±
CP±6±3A19±7HL 1895 - 192±
CP±6±3A189±HL 188± - 19±±
17.3
17.±
16.7
16.3
17.±
16.3
13.±
11.4
11.±
1±.8
1±.5
1±.7
1±.8
8.8
AMPS
GSM
Coupling
R. Loss
±.3±
25
26
-3±.±
-4±.±
±.35
±.55
E-GSM
PDC
Isolation
22
2±
PCN
-5±.±
-6±.±
-2±.±
-24.±
PCS
24
±.75
1.±±
19
17
PHP
DECT
±.8
1.6
2.4
3.2
4.±
Frequency (GHzꢀ
Wireless LAN CP±6±3A2442HL 24±± - 2484
Coupler P/N CP0603AxxxxML
CP0603AxxxxMLTR
±
±
-1±.±
-2±.±
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4.±
-8.±
-12.±
-16.±
[MHz]
[dB]
33
CP±6±3A±836ML 824 - 849
CP±6±3A±881ML 869 - 894
CP±6±3A±9±2ML 89± - 915
CP±6±3A±947ML 935 - 96±
CP±6±3A±897ML 88± - 915
CP±6±3A±942ML 925 - 96±
CP±6±3A1441ML 1429 - 1453
CP±6±3A1747ML 171± - 1785
CP±6±3A1842ML 18±5 - 188±
CP±6±3A188±ML 185± - 191±
CP±6±3A196±ML 193± - 199±
CP±6±3A19±7ML 1895 - 192±
CP±6±3A189±ML 188± - 19±±
24.2
23.8
23.4
23.2
23.4
23.2
2±.±
18.4
18.±
17.8
17.5
17.7
17.8
15.6
AMPS
GSM
Coupling
R. Loss
±.2±
32
23
-3±.±
-4±.±
E-GSM
PDC
Isolation
28
27
PCN
-5±.±
-6±.±
-2±.±
-24.±
±.25
±.35
PCS
2±
26
24
PHP
DECT
±.8
1.6
2.4
3.2
4.±
Frequency (GHzꢀ
Wireless LAN CP±6±3A2442ML 24±± - 2484
Important: Couplers can be used at any frequency within the indicated range.
4±
Thin-Film Directional Couplers
CP0402 / CP0603 High Directivity Couplers Test Jigs
GENERAL DESCRIPTION
These jigs are designed for testing the CP0402 and CP0603
High Directivity Couplers using a Vector Network Analyzer.
The connectors are SMA type (female), ‘Johnson Components
Inc.’ Product P/N: 142-0701-841.
They consist of a dielectric substrate, having 50Ω microstrips
as conducting lines and a bottom ground plane located at a
distance of 0.254mm (0.010") from the microstrips.
Both a measurement jig and a calibration jig are provided.
The calibration jig is designed for a full 2-port calibration, and
consists of an open line, short line and through line. LOAD
calibration can be done by a 50Ω SMA termination.
The substrate used is Neltec’s NH9338ST0254C1BC.
MEASUREMENT PROCEDURE
When measuring a component, it can be either soldered or
pressed using a non-metallic stick until all four ports touch
the appropriate pads. Set the VNA to the relevant frequency
band. Connect the VNA using a 10dB attenuator on the jig
terminal connected to port 2. Follow the VNA’s instruction
manual and use the calibration jig to perform a full 2-Port
calibration in the required bandwidths.
Place the coupler on the measurement jig as follows:
3
Input (Coupler) ➜ Connector 1 (Jig)
Output (Coupler) ➜ Connector 2 (Jig)
Termination (Coupler) ➜ Connector 3 (Jig)
Coupling (Coupler) ➜ Connector 4 (Jig)
To measure I. Loss connect:
Connector 1 (Jig) ➜ Port 1 (VNA) Connector 3 (Jig) ➜ 50Ω
Connector 2 (Jig) ➜ Port 2 (VNA) Connector 4 (Jig) ➜ 50Ω
To measure R. Loss and Coupling connect:
Connector 1 (Jig) ➜ Port 1 (VNA) Connector 3 (Jig) ➜ 50Ω
Connector 2 (Jig) ➜ 50Ω
Connector 4 (Jig) ➜ Port 2 (VNA)
To measure Isolation connect:
Connector 1 (Jig) ➜ 50Ω
Connector 3 (Jig) ➜ 50Ω
Connector 2 (Jig) ➜ Port 1 (VNA) Connector 4 (Jig) ➜ Port 2 (VNA)
Measurement Jig
Calibration Jig
Short Line
to GND.
Connector 1
Connector
Johnson
P/N 142-±7±1-841
Connector 2
OPEN
TH
Load &
Open
Line
Connector 4
Through
Load &
Through
Connector 3
41
Thin-Film Directional Couplers
CP0603 SMD Type
GENERAL DESCRIPTION
ITF (Integrated Thin-Film) TECHNOLOGY
DIMENSIONS:
millimeters (inches)
B
W
The ITF SMD Coupler is based on thin-film multilayer technology.
The technology provides a miniature part with excellent high frequency
performance and rugged construction for reliable automatic assembly.
L
T
The ITF Coupler is offered in a variety of frequency bands compatible with
various types of high frequency wireless systems.
B1
A
Top View
Bottom View
FEATURES
APPLICATIONS
0603
1.6±±.1
(±.±63±±.±±4ꢀ
±.84±±.1
(±.±33±±.±±4ꢀ
±.6±±±.1
(±.±28±±.±±4ꢀ
±.35±±.15
(±.±14±±.±±6ꢀ
• Miniature Size: 0603
• Mobile Communications
• Satellite TV Receivers
• GPS
L
W
T
• Frequency Range: 800MHz - 3GHz
• Characteristic Impedance: 50Ω
• Operating / Storage Temp.: -40ºC to +85ºC
• Power Rating: 3W Continuous
• Low Profile
• Vehicle Location Systems
• Wireless LAN’s
A
• Rugged Construction
3
B
±.175±±.1
(±.±±7±±.±±4ꢀ
• Taped and Reeled
B1
±.±±+±.1/±-±.±
(±.±±+±.±±4/-±.±ꢀ
HOW TO ORDER
CP
0603
X
W
TR
X
****
Frequency
Type
Style
Size
0603
Sub Type
Termination
Code
Packaging Code
TR = Tape and Reel
MHz
Directional Coupler
W = Sn90, Pb10
S = Sn100
QUALITY INSPECTION
TERMINALS (Top View)
Finished parts are 100ꢀ tested for electrical parameters and
visual characteristics. Each production lot is evaluated on a
sample basis for:
OUT
50 OHM
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
TERMINATION
Nickel/Solder coating compatible with automatic soldering
technologies: reflow, wave soldering, vapor phase and
manual.
IN
COUPLING
Recommended Pad Layout Dimensions
mm (inches)
1.85
(±.±73ꢀ
±.45
(±.±18ꢀ
Orientation in tape
±.28
(±.±11ꢀ
1.±8
(±.±43ꢀ
42
Thin-Film Directional Couplers
CP0603 SMD Type
Coupler P/N CP0603A
AW
P/N CP0603A AW
****
****
0
-10
-20
-30
-40
0
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
I. Loss
Application
AMPS
[dB]
18.5±1
18.5±1
18±1
17.5±1
18±1
17.5±1
14±1
12.5±1
12±1
max
max
-2
-4
-6
-8
CP±6±3A±836AW
CP±6±3A±881AW
CP±6±3A±9±2AW
CP±6±3A±947AW
CP±6±3A±897AW
CP±6±3A±942AW
Coupling
Isolation
±.25
GSM
Return Loss
E-GSM
PDC
CP±6±3A1441AW 1429 - 1453
CP±6±3A1747AW 171± - 1785
CP±6±3A1842AW 18±5 - 188±
CP±6±3A188±AW 185± - 191±
CP±6±3A196±AW 193± - 199±
CP±6±3A19±7AW 1895 - 192±
CP±6±3A189±AW 188± - 19±±
±.4
±.6
-50
-60
-10
-12
1.2
PCN
12±1
11.5±1
12±1
PCS
0.5
1.0
1.5
2.0
Frequency (GHz)
2.5
3.0
3.5
±.65
±.6
PHP
DECT
12±1
Wireless LAN CP±6±3A2442AW 24±± - 2484
1±±1
±.85
Coupler P/N CP0603A
BW
CP0603A BW
****
****
0
0
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
I. Loss
Application
AMPS
[dB]
16±1
15.5±1
15.5±1
15±1
15.5±1
15±1
11.5±1
1±±1
9.5±1
9±1
max
max
-2
-4
-6
-8
-10
-20
-30
-40
-50
-60
Coupling
CP±6±3A±836BW
CP±6±3A±881BW
CP±6±3A±9±2BW
CP±6±3A±947BW
CP±6±3A±897BW
CP±6±3A±942BW
Return Loss
Isolation
±.25
1.2
GSM
3
E-GSM
PDC
CP±6±3A1441BW 1429 - 1453
CP±6±3A1747BW 171± - 1785
CP±6±3A1842BW 18±5 - 188±
CP±6±3A188±BW 185± - 191±
CP±6±3A196±BW 193± - 199±
CP±6±3A19±7BW 1895 - 192±
CP±6±3A189±BW 188± - 19±±
±.55
1.3
1.4
-10
-12
PCN
PCS
0.5
1.0
1.5
2.0
2.5
3.0
9±1
9±1
9±1
7.5±1
±.8
1.1
PHP
DECT
Frequency (GHz)
Wireless LAN CP±6±3A2442BW 24±± - 2484
Coupler P/N CP0603A
CW
CP0603A CW
****
****
0
0
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
[dB]
21±1
I. Loss
Application
AMPS
-1
-2
-3
-4
-5
-6
-7
-8
-9
max
max
-10
CP±6±3A±836CW
CP±6±3A±881CW
CP±6±3A±9±2CW
CP±6±3A±947CW
CP±6±3A±897CW
CP±6±3A±942CW
Coupling
Isolation
-20
-30
-40
2±.5±1
2±.5±1
2±±1
2±.5±1
2±±1
16.5±1
15±1
14.5±1
14.5±1
14±1
±.25
GSM
Return Loss
E-GSM
PDC
-50
-60
-70
CP±6±3A1441CW 1429 - 1453
CP±6±3A1747CW 171± - 1785
CP±6±3A1842CW 18±5 - 188±
CP±6±3A188±CW 185± - 191±
CP±6±3A196±CW 193± - 199±
CP±6±3A19±7CW 1895 - 192±
CP±6±3A189±CW 188± - 19±±
±.4±
1.2
-10
-11
-12
PCN
PCS
±.5
0.5
1.0
1.5
2.0
2.5
3.0
3.5
PHP
DECT
14.5±1
14.5±1
12.5±1
Frequency (GHz)
Wireless LAN CP±6±3A2442CW 24±± - 2484
±.65
Coupler P/N CP0603A
DW
CP0603A
DW
****
****
0
-10
-20
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
Application
I. Loss
[dB]
15.±±1
14.5±1
14.5±1
14±1
14.5±1
14±1
1±.5±1
9±1
8.5±1
8.5±1
8±1
8.5±1
8.5±1
6.5±1
max
max
AMPS
CP±6±3A±836DW
CP±6±3A±881DW
CP±6±3A±9±2DW
CP±6±3A±947DW
CP±6±3A±897DW
CP±6±3A±942DW
Coupling Return Loss
Isolation
±.4±
1.2
GSM
-30
-40
-50
-60
E-GSM
PDC
CP±6±3A1441DW 1429 - 1453
CP±6±3A1747DW 171± - 1785
CP±6±3A1842DW 18±5 - 188±
CP±6±3A188±DW 185± - 191±
CP±6±3A196±DW 193± - 199±
CP±6±3A19±7DW 1895 - 192±
CP±6±3A189±DW 188± - 19±±
±.7
±.9
1.±
1.3
1.5
PCN
PCS
0.5 0.7 0.9 1.1 1.3 1.5 1.7 1.9 2.1 2.3 2.5
PHP
DECT
Frequency (GHz)
Wireless LAN CP±6±3A2442DW 24±± - 2484
1.5
Important: Couplers can be used at any frequency within the indicated range.
43
Thin-Film Directional Couplers
CP0603 SMD Type
Coupler P/N CP0603B
AW
CP0603B
AW
****
****
0
P/N
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
I. Loss
-1
-3
-5
-7
Application
AMPS
Examples
[dB]
24.5±1
24±1
24±1
23.5±1
24±1
23.5±1
2±±1
18±1
17.5±1
17.5±1
17.5±1
17.5±1
17.5±1
15.5±1
max
max
-10
-20
Coupling
CP±6±3B±836AW
CP±6±3B±881AW
CP±6±3B±9±2AW
CP±6±3B±947AW
CP±6±3B±897AW
CP±6±3B±942AW
Isolation
±.2
GSM
-30
-40
-50
-60
Return Loss
E-GSM
PDC
-9
CP±6±3B1441AW 1429 - 1453
CP±6±3B1747AW 171± - 1785
CP±6±3B1842AW 18±5 - 188±
CP±6±3B188±AW 185± - 191±
CP±6±3B196±AW 193± - 199±
CP±6±3B19±7AW 1895 - 192±
CP±6±3B189±AW 188± - 19±±
1.2
±.25
-11
PCN
-13
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
PCS
±.3
Frequency (GHz)
PHP
DECT
Wireless LAN CP±6±3B2442AW 24±± - 2484
±.45
Coupler P/N CP0603B
BW
CP0603B
I. Loss
BW
****
****
0
-5
0
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
Application
AMPS
[dB]
25.5±1
25±1
25±1
24.5±1
25±1
24.5±1
21±1
19±1
max
max
-10
-15
-20
-25
-2
CP±6±3B±836BW
CP±6±3B±881BW
CP±6±3B±9±2BW
CP±6±3B±947BW
CP±6±3B±897BW
CP±6±3B±942BW
Coupling
3
-4
-6
GSM
±.2
Return Loss
-30
E-GSM
PDC
-35
-40
CP±6±3B1441BW 1429 - 1453
CP±6±3B1747BW 171± - 1785
CP±6±3B1842BW 18±5 - 188±
CP±6±3B188±BW 185± - 191±
CP±6±3B196±BW 193± - 199±
CP±6±3B19±7BW 1895 - 192±
CP±6±3B189±BW 188± - 19±±
1.2
Isolation
-8
PCN
19±1
-45
-50
0.5
18.5±1
18.5±1
18.5±1
18.5±1
16.5±1
±.25
±.35
-10
4.0
PCS
1.0
1.5
2.0
2.5
3.0
3.5
PHP
DECT
Frequency (GHz)
Wireless LAN CP±6±3B2442BW 24±± - 2484
Coupler P/N CP0603B
CW
CP0603B
CW
****
****
0
0
-5
-10
-15
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
I. Loss
Application
AMPS
[dB]
26.5±1
26±1
26±1
25.5±1
26±1
25.5±1
22±1
2±.5±1
2±±1
2±±1
19.5±1
2±±1
max
max
-2
-4
-6
CP±6±3B±836CW
CP±6±3B±881CW
CP±6±3B±9±2CW
CP±6±3B±947CW
CP±6±3B±897CW
CP±6±3B±942CW
Coupling
-20
-25
-30
-35
-40
-45
-50
GSM
±.2
E-GSM
PDC
Return Loss
Isolation
CP±6±3B1441CW 1429 - 1453
CP±6±3B1747CW 171± - 1785
CP±6±3B1842CW 18±5 - 188±
CP±6±3B188±CW 185± - 191±
CP±6±3B196±CW 193± - 199±
CP±6±3B19±7CW 1895 - 192±
CP±6±3B189±CW 188± - 19±±
1.2
-8
PCN
-10
4.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
PCS
±.25
±.35
Frequency (GHz)
PHP
DECT
2±±1
18±1
Wireless LAN CP±6±3B2442CW 24±± - 2484
1.3
Important: Couplers can be used at any frequency within the indicated range.
44
Thin-Film Directional Couplers
CP0603 SMD Type – High Directivity
Coupler P/N CP0603D
AW
CP0603D AW
****
****
0
0
-5
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
-2
Application
Band
[dB]
max. Loss
[dB]
[dB]
-4
[MHz]
[dB]
23
-10
-15
-20
-25
-30
-35
-40
Coupling
Isolation
CP±6±3D±836AW 824 - 849
CP±6±3D±881AW 869 - 894
CP±6±3D±9±2AW 89± - 915
CP±6±3D±947AW 935 - 96±
CP±6±3D±897AW 88± - 915
CP±6±3D±942AW 925 - 96±
CP±6±3D1441AW 1429 - 1453
CP±6±3D1747AW 171± - 1785
CP±6±3D1842AW 18±5 - 188±
CP±6±3D188±AW 185± - 191±
CP±6±3D196±AW 193± - 199±
CP±6±3D19±7AW 1895 - 192±
CP±6±3D189±AW 188± - 19±±
13.5±
13.±±
-6
AMPS
GSM
-8
-10
-12
-14
-16
12.5±
13.±±
12.5±
9.±±
±.5±
1.±±
22
21
E-GSM
PDC
Return Loss
18
17
19
18
8.±±
PCN
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
7.5±
Frequency (GHz)
PCS
1.4±
2.±±
17
15
PHP
DECT
7.±±
5.5±
16
15
Wireless LAN CP±6±3D2442AW 24±± - 2484
3
Coupler P/N CP0603D
BW
CP0603D
BW
****
****
0
0
-5
-10
-15
Frequency Coupling I. Loss Return Directivity
I. Loss
P/N
Examples
-1
-2
-3
-4
Application
Band
[dB]
max. Loss
[dB]
[dB]
[MHz]
[dB]
Coupling
CP±6±3D±836BW 824 - 849
CP±6±3D±881BW 869 - 894
CP±6±3D±9±2BW 89± - 915
CP±6±3D±947BW 935 - 96±
CP±6±3D±897BW 88± - 915
CP±6±3D±942BW 925 - 96±
2±.±±
19.5±
AMPS
GSM
36
-20
-25
-30
-35
-40
-45
-5
-6
-7
-8
-9
±.25
35
Return Loss
Isolation
19.±±
19.5±
19.±±
36
35
3±
28
E-GSM
PDC
19
CP±6±3D1441BW 1429 - 1453 15.5±
CP±6±3D1747BW 171± - 1785 14.±±
CP±6±3D1842BW 18±5 - 188±
CP±6±3D188±BW 185± - 191± 13.5±
CP±6±3D196±BW 193± - 199±
±.4±
±.5±
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
PCN
Frequency (GHz)
PCS
±.55
±.7±
27
24
PHP
DECT
CP±6±3D19±7BW 1895 - 192±
CP±6±3D189±BW 188± - 19±±
13.±±
Wireless LAN CP±6±3D2442BW 24±± - 2484 11.±±
Important: Couplers can be used at any frequency within the indicated range.
45
Thin-Film Directional Couplers
CP0805 Type
GENERAL DESCRIPTION
ITF (Integrated Thin-Film) TECHNOLOGY
DIMENSIONS:
(Top View)
millimeters (inches)
The ITF SMD Coupler is based on thin-film multilayer technology.
The technology provides a miniature part with excellent high frequency
performance and rugged construction for reliable automatic assembly.
W
B
L
The ITF Coupler is offered in a variety of frequency bands compatible with
various types of high frequency wireless systems.
T
FEATURES
APPLICATIONS
• Small Size: 0805
• Mobile Communications
• Satellite TV Receivers
• GPS
A
• Frequency Range: 800MHz - 3GHz
• Characteristic Impedance: 50Ω
0805
• Operating / Storage Temp.:
• Vehicle Location Systems
• Wireless LAN’s
L
W
T
2.±3±±.1 (±.±8±±±.±±4ꢀ
1.55±±.1 (±.±61±±.±±4ꢀ
±.98±±.1 (±.±39±±.±±4ꢀ
±.56±±.25 (±.±22±±.±1±ꢀ
±.35±±.15 (±.±14±±.±±6ꢀ
-40°C to +85°C
• Power Rating: 3W Continuous
• Low Profile
• Rugged Construction
• Taped and Reeled
A
B
3
HOW TO ORDER
CP
0805
0902
A
W
TR
A
Style
Directional Coupler
Size
0805
Frequency
Sub Type
(see layout
sub-types)
Termination
Code
W = Nickel/Solder
(Sn/Pb)
Packaging Code
TR = Tape and Reel
Layout Type
(see layout types)
MHz
QUALITY INSPECTION
Finished parts are 100ꢀ tested for electrical parameters and
visual characteristics. Each production lot is evaluated on a
sample basis for:
Recommended Pad Layout Dimensions mm (inches)
2.33
(0.092)
0.60
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
(0.024)
TERMINATION
Nickel/Solder coating (Sn, Pb) compatible with automatic
soldering technologies: reflow, wave soldering, vapor phase
and manual.
2.25
(0.089)
0.65
(0.026)
NOTE: Components must be mounted on the board with the white
(Alumina) side DOWN.
46
Thin-Film Directional Couplers
CP0805 Layout Types
LAYOUT
LAYOUT
5± OHM
(External
Resistorꢀ
COUP
Port
5± OHM
(External
Resistorꢀ
COUP
Port
RF OUT
Port
RF IN
Port
RF IN
Port
RF OUT
Port
Type: A
Sub-Type: A
Type: A
Sub-Type: B
0
0
0
0
I. Loss
I. Loss
-5
-1
-2
-3
-4
-1
-5
-10
-15
-20
-10
-15
-20
-25
-30
-35
-40
Coupling
Isolation
R. Loss
Coupling
R. Loss
-5
-6
-7
-8
-9
-10
-25
-30
-35
-40
Isolation
3
-45
-50
0.60
-45
-50
0.60
0.80
1.00
1.20
1.40
1.60
1.80
2.00
0.80
1.00
1.20
1.40
1.60
1.80
2.00
Frequency (GHz)
Frequency (GHz)
P/N
Examples
Frequency
Band [MHz]
Coupling I. Loss VSWR
Application
AMPS
P/N
Examples
Frequency
Band [MHz]
Coupling I. Loss VSWR
[dB]
max
max
Application
AMPS
[dB]
16.5±1
16±1
max
max
CP±8±5A±836BW
CP±8±5A±881BW
CP±8±5A±9±2BW
CP±8±5A±947BW
CP±8±5A±897BW
CP±8±5A±942BW
CP±8±5A1441BW 1429 - 1453
CP±8±5A1747BW 171± - 1785
CP±8±5A1842BW 18±5 - 188±
CP±8±5A188±BW 185± - 191±
CP±8±5A196±BW 193± - 199±
CP±8±5A19±7BW 1895 - 192±
CP±8±5A189±BW 188± - 19±±
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
19±1
18.5±1
18±1
CP±8±5A±836AW
CP±8±5A±881AW
CP±8±5A±9±2AW
CP±8±5A±947AW
CP±8±5A±897AW
CP±8±5A±942AW
CP±8±5A1441AW 1429 - 1453
CP±8±5A1747AW 171± - 1785
CP±8±5A1842AW 18±5 - 188±
CP±8±5A188±AW 185± - 191±
CP±8±5A196±AW 193± - 199±
CP±8±5A19±7AW 1895 - 192±
CP±8±5A189±AW 188± - 19±±
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
±.25
1.2
±.25
GSM
16±1
15.5±1
16±1
15.5±1
12±1
1±.5±1
1±±1
9.5±1
9.5±1
9.5±1
9.5±1
18±1
GSM
1.2
1.3
1.4
18.5±1
18±1
14.5±1
12.5±1
12.5±1
12±1
E-GSM
PDC
E-GSM
PDC
±.35
±.5
±.5
±.7
±.8
PCN
PCN
±.6
±.7
±.6
PCS
11.5±1
12±1
1.4
PCS
PHP
DECT
PHP
DECT
12±1
1±±1
Wireless LAN CP±8±5A2442BW 24±± - 2484
±.9
LAYOUT
5± OHM
COUP
Type: A
Sub-Type: C
IN
OUT
0
I. Loss
-5
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
-10
-15
-20
Application
AMPS
Coupling
Isolation
[dB]
14±1
13.5±1
13.5±1
13±1
13.5±1
13±1
9.5±1
8±1
max
max
CP±8±5A±836CW
CP±8±5A±881CW
CP±8±5A±9±2CW
CP±8±5A±947CW
CP±8±5A±897CW
CP±8±5A±942CW
CP±8±5A1441CW 1429 - 1453
CP±8±5A1747CW 171± - 1785
CP±8±5A1842CW 18±5 - 188±
CP±8±5A188±CW 185± - 191±
Cp±8±5A196±CW 193± - 199±
CP±8±5A19±7CW 1895 - 192±
CP±8±5A189±CW 188± - 19±±
±.5
-25
-30
GSM
R. Loss
1.4
1.8
2.2
E-GSM
PDC
-35
-40
1.15
1.6
-45
-50
PCN
8±1
7.5±1
7.5±1
7.5±1
7.5±1
6±1
1.75
0.60 0.80 1.00 1.20 1.40 1.60 1.80
2.00 2.20 2.40
PCS
Frequency (GHz)
PHP
DECT
Wireless LAN CP±8±5A2442CW 24±± - 2484
2.5
Important: Couplers can be used at any frequency within the indicated range.
47
Thin-Film Directional Couplers
CP0805 Layout Types
LAYOUT
LAYOUT
5± OHM
COUP
5± OHM
COUP
IN
OUT
IN
OUT
Type: A
Sub-Type: D
Type: A
Sub-Type: E
0
0
-5
I. Loss
I. Loss
-5
-10
-15
-20
Coupling
Isolation
Coupling
-10
-15
-20
-25
-30
R. Loss
Isolation
R. Loss
-35
-40
-25
-30
3
-45
-50
0.50
0.75
1.00
1.25
1.50
1.75
2.00
0.60 0.80 1.00 1.20 1.40 1.60 1.80
2.00 2.20 2.40
Frequency (GHz)
Frequency (GHz)
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
P/N
Examples
Frequency
Coupling I. Loss VSWR
Application
AMPS
Application
AMPS
[dB]
13.±±1
12.5±1
12.5±1
12±1
12.5±1
12±1
8.5±1
7±1
7±1
7±1
6.5±1
6.5±1
7±1
max
max
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
[dB]
11±1
1±.5±1
1±.5±1
1±±1
1±.5±1
1±±1
7±1
max
max
CP±8±5A±836DW
CP±8±5A±881DW
CP±8±5A±9±2DW
CP±8±5A±947DW
CP±8±5A±897DW
CP±8±5A±942DW
CP±8±5A1441DW 1429 - 1453
CP±8±5A1747DW 171± - 1785
CP±8±5A1842DW 18±5 - 188±
CP±8±5A188±DW 185± - 191±
Cp±8±5A196±DW 193± - 199±
CP±8±5A19±7DW 1895 - 192±
CP±8±5A189±DW 188± - 19±±
CP±8±5A±836EW
CP±8±5A±881EW
CP±8±5A±9±2EW
CP±8±5A±947EW
CP±8±5A±897EW
CP±8±5A±942EW
CP±8±5A1441EW 1429 - 1453
CP±8±5A1747EW 171± - 1785
CP±8±5A1842EW 18±5 - 188±
CP±8±5A188±EW 185± - 191±
Cp±8±5A196±EW 193± - 199±
CP±8±5A19±7EW 1895 - 192±
CP±8±5A189±EW 188± - 19±±
±.5
1.4
±.85
1.4
GSM
GSM
E-GSM
PDC
E-GSM
PDC
1.25
1.85
2.15
1.8
2.1
1.8
2.7
1.8
2.2
5.5±1
5.5±1
5±1
PCN
PCN
PCS
PCS
5±1
5±1
5±1
4±1
PHP
DECT
PHP
DECT
3.15
4.2
2.4
1.85
2.4
1.8
2.1
Wireless LAN CP±8±5A2442DW 24±± - 2484
5.5±1
Wireless LAN CP±8±5A2442EW 24±± - 2484
LAYOUT
RF IN
Port
COUP Port
Type: B
Sub-Type: A
0
0
I. Loss
-5
-1
-2
RF OUT
Port
-10
Coupling
5± OHM (External Resistorꢀ
Frequency Coupling I. Loss VSWR
-15
-3
-4
-5
-6
-7
-8
-20
P/N
R. Loss
Application
AMPS
-25
Examples
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
[dB]
21.5±1
21±1
21±1
2±.5±1
21±1
2±.5±1
17±1
15.5±1
15.5±1
15±1
14.5±1
15±1
15±1
max
max
-30
CP±8±5B±836AW
CP±8±5B±881AW
CP±8±5B±9±2AW
CP±8±5B±947AW
CP±8±5B±897AW
CP±8±5B±942AW
CP±8±5B1441AW 1429 - 1453
CP±8±5B1747AW 171± - 1785
Cp±8±5B1842AW 18±5 - 188±
CP±8±5B188±AW 185± - 191±
CP±8±5B196±AW 193± - 199±
CP±8±5B19±7AW 1895 - 192±
CP±8±5B189±AW 188± - 19±±
Isolation
-35
-40
GSM
±.25
-45
-50
1.00
-9
-10
2.40
E-GSM
1.20
1.40
1.60
1.80
2.00
2.20
PDC
PCN
Frequency (GHz)
1.2
±.3
PCS
±.4
±.3
PHP
DECT
Wireless LAN CP±8±5B2442AW 24±± - 2484
13±1
±.4
Important: Couplers can be used at any frequency within the indicated range.
48
Thin-Film Directional Couplers
CP0805 Layout Types
LAYOUT
LAYOUT
RF IN
Port
COUP Port
RF IN
Port
COUP Port
RF OUT
Port
RF OUT
Port
5± OHM (External Resistorꢀ
5± OHM (External Resistorꢀ
Type: B
Sub-Type: C
Type: B
Sub-Type: B
0
0
-5
0
-5
0
I. Loss
I. Loss
-1
-2
-3
-4
-5
-1
-2
-10
-10
-15
-20
-3
-4
-5
-15
-20
-25
-30
-35
-40
Coupling
Coupling
R. Loss
-25
-30
R. Loss
-6
-6
-7
-35
-40
-7
Isolation
-8
Isolation
-8
-45
-50
-9
-9
-45
-50
1.10
3
-10
1.00 1.20 1.40 1.60 1.80 2.00 2.20 2.40 2.60
-10
2.50
1.30
1.50
1.70
1.90
2.10
2.30
Frequency (GHz)
Frequency (GHz)
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
P/N
Examples
Frequency
Band [MHz]
824 - 849
869 - 894
89± - 915
935 - 96±
88± - 915
925 - 96±
Coupling I. Loss VSWR
Application
AMPS
Application
AMPS
[dB]
23.5±1
23±1
max
max
[dB]
max
max
CP±8±5B±836BW
CP±8±5B±881BW
CP±8±5B±9±2BW
CP±8±5B±947BW
CP±8±5B±897BW
CP±8±5B±942BW
CP±8±5B1441BW 1429 - 1453
CP±8±5B1747BW 171± - 1785
CP±8±5B1842BW 18±5 - 188±
CP±8±5B188±BW 185± - 191±
CP±8±5B196±BW 193± - 199±
CP±8±5B19±7BW 1895 - 192±
CP±8±5B189±BW 188± - 19±±
CP±8±5B±836CW
CP±8±5B±881CW
CP±8±5B±9±2CW
CP±8±5B±947CW
CP±8±5B±897CW
CP±8±5B±942CW
CP±8±5B1441CW 1429 - 1453
CP±8±5B1747CW 171± - 1785
Cp±8±5B1842CW 18±5 - 188±
CP±8±5B188±CW 185± - 191±
Cp±8±5B196±CW 193± - 199±
CP±8±5B19±7CW 1895 - 192±
CP±8±5B189±CW 188± - 19±±
25±1
24.5±1
24±1
22.5±1
22±1
GSM
GSM
24±1
23±1
22±1
24.5±1
24±1
E-GSM
PDC
E-GSM
PDC
±.25
±.25
18.5±1
17±1
16.5±1
16.5±1
16±1
2±±1
18.5±1
18.5±1
18±1
PCN
PCN
1.2
1.2
PCS
PCS
17.5±1
18±1
18±1
PHP
DECT
16±1
16±1
PHP
DECT
Wireless LAN CP±8±5B2442BW 24±± - 2484
14±1
±.4
Wireless LAN CP±8±5B2442CW 24±± - 2484
16±1
±.4
Important: Couplers can be used at any frequency within the indicated range.
49
Thin-Film Directional Couplers
CP0805 and CP0603 Test Jig
ITF TEST JIG FOR COUPLER TYPES 0805 AND 0603 SMD
GENERAL DESCRIPTION
MEASUREMENT PROCEDURE
This jig is designed for the testing of CP0805 and CP0603
series Directional Couplers using a vector network analyzer.
When measuring a component, it can be either soldered or
pressed by a non-metallic stick until all four ports touch the
appropriate pads. To measure the coupling (and the R. Loss)
place the component on the Port 1 & Port 2 pads. Use two
SMA 50Ω terminations (male) to terminate the ports, which
are not connected to the network analyzer, and connect
the network analyzer to the two ports. A 90° rotation of
the component on its pads allows measuring a second
parameter (I. Loss).
It consists of a FR4 multi-layer substrate, having 50Ω
microstrips as conducting lines and a ground plane in the
middle layer, located at a distance of 0.2mm from the
microstrips.
The connectors are SMA type (female), ‘Johnson Components
Inc.’ Product P/N: 142-0701-881.
The jig is designed for a full 2-port calibration. LOAD calibration
can be done either by a 50Ω SMA termination, or by soldering
a 50Ω chip resistor at the 50Ω ports.
Connector (1 of 12ꢀ
P/N 142-±7±1-881
Load & Thru
Calibration Area
Short
Open
3
Port 1
Port 2
Coupler 0805
5±Ω
5±Ω
Port 1
Coupler 0603
5±Ω
Port 2
5±Ω
CP0805 SERIES DIRECTIONAL COUPLERS
Orientation and Tape and Reel Packaging Specification
(Top View)
5±
OHM
5±
OHM
COUP
COUP
RF
IN
RF
OUT
RF
IN
RF
OUT
TYPE AA
TYPE AC
TYPE BA
TYPE AB
TYPE AD
TYPE BB
5±
5±
5±
COUP
COUP
COUP
OHM
OHM
OHM
RF
IN
RF
OUT
RF
IN
RF
OUT
RF
IN
RF
OUT
TYPE AE
RF
IN
RF
IN
RF
IN
COUP
COUP
COUP
5±
OHM
5±
OHM
5±
OHM
RF
OUT
RF
OUT
RF
OUT
TYPE BC
The parts should be mounted on the PCB with White (Alumina)
side down and the "dark" side up.
5±
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
GENERAL DESCRIPTION
ITF TECHNOLOGY
The ITF SMD 3dB 90° Coupler is based on thin-film multilayer
technology. The technology provides a miniature part with excellent
high frequency performance and rugged construction for reliable
automatic assembly.
FEATURES
• Miniature 0805 size
APPLICATIONS
• Balanced Amplifiers and
Signal Distribution in
• Low I. Loss
Mobile Communications
• High Isolation
• Power Handling:
10W RF CW
The ITF 3dB 90° Coupler is offered in a variety of frequency bands
compatible with various types of high frequency wireless
systems.
• Surface Mountable
• Supplied on Tape and Reel
• Operating Temperature
-40°C to +85°C
Recommended Pad Layout Dimensions
mm (inches)
DIMENSIONS:
millimeters (inches)
2.24 (0.088)
Bottom View
0.70
(0.028)
2.±3±±.1±
(±.±8±±±.±±4ꢀ
L
W
1.55±±.1±
(±.±61±±.±±4ꢀ
B
L
W
±.98±±.15
(±.±37±±.±±6ꢀ
T
T
3
±.56±±.25
(±.±22±±.±1±ꢀ
±.35±±.15
A
B
1.76
(0.069)
0.64
(0.025)
GROUND
(±.±14±±.±±6ꢀ
A
TERMINALS (Top View)
Orientation in Tape
0.15 (0.006) TYP.
5±
5±
OUT1
OUT2
OUT1
OHM
OHM
Code Letter
Marking
IN
IN
OUT2
ELECTRICAL PARAMETERS*
Frequency FO I. Loss @ FO Phase Balance Code Letter
Part Number
[MHz]
[dB]
±.35
±.35
±.35
±.35
±.35
±.3±
±.3±
±.3±
±.25
±.25
±.25
[deg] max.
Marking
DB±8±5A±88±AWTR
DB±8±5A±915AWTR
DB±8±5A±967AWTR
DB±8±5A135±AWTR
DB±8±5A165±AWTR
DB±8±5A18±±AWTR
DB±8±5A185±AWTR
DB±8±5A19±±AWTR
DB±8±5A195±AWTR
DB±8±5A214±AWTR
DB±8±5A2325AWTR
88±±3±
915±3±
967±3±
3
3
3
3
3
3
3
3
3
3
3
Y
V
V
C
F
135±±5±
165±±5±
18±±±5±
185±±5±
19±±±5±
195±±5±
214±±5±
2325±5±
F
K
K
K
L
T
*With Recommended Pad Layout
All intermediate frequencies within the
indicated range are readily available.
Important:
51
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
880 30MHz DB0805A0880AWTR
-3.±
I. Loss 1
-3.2
-3.4
I. Loss 2
-3.6
3
-3.8
85±
865
88±
895
91±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
R. Loss
Isolation
-24
-26
-28
-3±
85±
855
88±
9±5
93±
Frequency (MHzꢀ
52
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
915 30MHz DB0805A0915AWTR
-2.8
-3.±
-3.2
I. Loss 1
-3.4
I. Loss 2
3
-3.6
-3.8
885
9±±
915
93±
945
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
Isolation
R. Loss
-24
-26
-28
-3±
865
89±
915
94±
965
Frequency (MHzꢀ
53
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
967 30MHz DB0805A0967AWTR
-2.8
-3.±
-3.2
I. Loss 1
-3.4
I. Loss 2
3
-3.6
-3.8
937
952
967
982
997
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
R. Loss
Isolation
917
942
967
992
1±17
Frequency (MHzꢀ
54
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1350 50MHz DB0805A1350AWTR
-3.±
-3.2
I. Loss 1
-3.4
I. Loss 2
-3.6
3
-3.8
13±±
135±
14±±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
Isolation
R. Loss
-24
-26
-28
-3±
13±±
135±
14±±
Frequency (MHzꢀ
55
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1650 50MHz DB0805A1650AWTR
-2.8
-3.±
I. Loss 1
-3.2
-3.4
3
I. Loss 2
-3.6
155±
16±±
165±
17±±
175±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
Isolation
R. Loss
-24
-26
-28
-3±
155±
16±±
165±
17±±
175±
Frequency (MHzꢀ
56
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1800 50MHz DB0805A1800AWTR
-2.8
-3.±
I. Loss 1
-3.2
I. Loss 2
-3.4
3
-3.6
175±
1775
18±±
1825
185±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
Isolation
R. Loss
175±
1775
18±±
1825
185±
Frequency (MHzꢀ
57
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1850 50MHz DB0805A1850AWTR
-2.8
-3.±
I. Loss 1
-3.2
I. Loss 2
-3.4
3
-3.6
18±±
1825
185±
1875
19±±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
R. Loss
Isolation
18±±
1825
185±
1875
19±±
Frequency (MHzꢀ
58
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1900 50MHz DB0805A1900AWTR
-3.±
I. Loss 1
-3.2
I. Loss 2
-3.4
3
-3.6
185±
1875
19±±
1925
195±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
Isolation
R. Loss
185±
1875
19±±
1925
195±
Frequency (MHzꢀ
59
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
1950 50MHz DB0805A1950AWTR
-2.8
-3.±
I. Loss 1
-3.2
I. Loss 2
-3.4
-3.6
3
19±±
1925
195±
1975
2±±±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
R. Loss
Isolation
19±±
1925
195±
1975
2±±±
Frequency (MHzꢀ
6±
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
2140 50MHz DB0805A2140AWTR
-2.6
-2.8
-3.±
I. Loss 1
-3.2
I. Loss 2
-3.4
-3.6
-3.8
3
2±4±
2±9±
214±
219±
224±
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
R. Loss
Isolation
214±
2±9±
214±
219±
224±
Frequency (MHzꢀ
61
Thin-Film Directional Couplers
DB0805 3dB 90° Couplers
2325 50MHz DB0805A2325AWTR
-3.±
-3.1
I. Loss 1
-3.2
-3.3
I. Loss 2
-3.4
3
-3.5
2275
23±±
2325
235±
2375
Frequency (MHzꢀ
-1±
-12
-14
-16
-18
-2±
-22
-24
-26
-28
-3±
R. Loss
Isolation
2275
23±±
2325
235±
2375
Frequency (MHzꢀ
62
Thin-Film Directional Couplers
DB0805 3dB 90° Test Jigs
GENERAL DESCRIPTION
These jigs are designed for testing the DB0805 3dB 90°
Couplers using a Vector Network Analyzer.
The connectors are SMA type (female), ‘Johnson Components
Inc.’ Product P/N: 142-0701-841.
They consist of a dielectric substrate, having 50Ω microstrips
as conducting lines and a bottom ground plane located at a
distance of 0.254mm from the microstrips.
Both a measurement jig and a calibration jig are provided.
The calibration jig is designed for a full 2-port calibration, and
consists of an open line, short line and through line. LOAD
calibration can be done by a 50Ω SMA termination.
The substrate used is Neltec’s NH9338ST0254C1BC.
MEASUREMENT PROCEDURE
When measuring a component, it can be either soldered or
pressed using a non-metallic stick until all four ports touch
the appropriate pads. Set the VNA to the relevant frequency
band. Connect the VNA using a 10dB attenuator on the jig
terminal connected to port 2. Follow the VNA’s instruction
manual and use the calibration jig to perform a full 2-port
calibration in the required bandwidths.
Place the coupler on the measurement jig as follows:
3
Input (Coupler) ➜ Connector 1 (Jig)
50Ω (Coupler) ➜ Connector 2 (Jig)
Output 1 (Coupler) ➜ Connector 3 (Jig)
Output 2 (Coupler) ➜ Connector 4 (Jig)
To measure R. Loss and I. Loss 1 connect:
Connector 1 (Jig) ➜ Port 1 (VNA) Connector 3 (Jig) ➜ Port 2 (VNA)
Connector 2 (Jig) ➜ 50Ω
Connector 4 (Jig) ➜ 50Ω
To measure R. Loss and I. Loss 2 connect:
Connector 1 (Jig) ➜ Port 1 (VNA) Connector 3 (Jig) ➜ 50Ω
Connector 2 (Jig) ➜ 50Ω
Connector 4 (Jig) ➜ Port 2 (VNA)
To measure Isolation connect:
Connector 1 (Jig) ➜ 50Ω
Connector 3 (Jig) ➜ Port 1 (VNA)
Connector 4 (Jig) ➜ Port 2 (VNA)
Connector 2 (Jig) ➜ 50Ω
Calibration Jig
Measurement Jig
Connector 1
Load &
Through
Connector
Johnson
P/N 142-±7±1-841
Connector 2
Load &
Through
Connector 4
Short Line
to GND
Open
Line
Connector 3
63
Thin-Film Technology
Integrated Thin-Film
Low-Pass Filters
4
64
Thin-Film Low Pass Filter
LP0603 Lead-Free LGA Type
GENERAL DESCRIPTION
APPLICATIONS
The LP0603 ITF (Integrated Thin Film) Lead-Free LGA Low
Pass Filter is based on thin-film multilayer technology. The
technology provides a miniature part with excellent high
frequency performance and rugged construction for reliable
automatic assembly.
• Mobile communications
• Satellite TV receivers
• GPS
• Vehicle location systems
• Wireless LANs
• RFID
The ITF Low Pass Filters are offered in a variety of frequency
bands compatible with various types of high frequency
wireless systems.
LAND GRID ARRAY ADVANTAGES
• Inherent Low Profile
• Self Alignment during Reflow
• Excellent Solderability
• Low Parasitics
FEATURES
• Miniature Size: 0603
• Frequency Range: 900MHz -2.4GHz
• Characteristic Impedance: 50 Ohm
• Operating/Storage Temperature: -40°C to +85°C
• Power Rating: 3W Continuous
• Low Profile
• Better Heat Dissipation
• Rugged Construction
• Lead Free
• Taped and Reeled
HOW TO ORDER
4
LP
0603
A
XXXX
A
N
TR
Style
Size
0603
Type
Frequency
Sub-Type
Termination
LGA
Taped & Reeled
MHz
Ni/Lead Free Solder
FINAL QUALITY INSPECTION
Finished parts are 100ꢀ tested for electrical parameters and
visual characteristics. Each production lot is evaluated on a
sample basis for:
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR, 4 hours
TERMINATION
Nickel/Lead-Free Solder coating compatible with automatic
soldering technologies: reflow, wave soldering, vapor phase
and manual.
65
Thin-Film Low Pass Filter
LP0603 Lead-Free LGA Type
DIMENSIONS: millimeters (inches)
(Bottom View)
TERMINALS AND ORIENTATION IN TAPE
(Top View)
S
B
A
GND
GND
GND
GND
IN
IN
OUT
OUT
L
T
W
RECOMMENDED PAD LAYOUT (mm)
1.6±±.1
±.25±±.±5
L
W
T
A
B
S
(±.±63±±.±±4ꢀ
(±.±1±±±.±±2ꢀ
±.84±±.1
(±.±33±±.±±4ꢀ
±.6±±±.1
(±.±24±±.±±4ꢀ
±.2±±±.±5
(±.±±8±±.±±2ꢀ
±.±5±±.±5
(±.±±2±±.±±2ꢀ
1.1±
(±.±43ꢀ
±.4±
(±.±16ꢀ
4
±.5±
(±.±2±ꢀ
1.75 (±.±69ꢀ
ELECTRICAL CHARACTERISTICS
(Guaranteed over –40°C to +85°C Operating Temperature Range)
P/N
Frequency
Band [MHz]
I. Loss
[dB]
VSWR
max
Attentuation
typ.
[dB]
[dB]
±.35 typ
(±.5 maxꢀ
25 @ 2xF±
14 @ 3xF±
LP±6±3A±9±2ANTR
LP±6±3A±947ANTR
LP±6±3A1747ANTR
LP±6±3A1842ANTR
LP±6±3A188±ANTR
LP±6±3A195±ANTR
LP±6±3A214±ANTR
LP±6±3A2442ANTR
89±-915
935-96±
1.4
1.4
1.4
1.4
1.4
1.4
1.4
1.4
±.35 typ
(±.5 maxꢀ
25 @ 2xF±
17 @ 3xF±
±.3 typ
(±.5 maxꢀ
25 @ 2xF±
17 @ 3xF±
171±-1785
18±5-188±
184±-192±
192±-198±
211±-217±
2412-2472
±.3 typ
(±.5 maxꢀ
27 @ 2xF±
15 @ 3xF±
±.3 typ
(±.5 maxꢀ
25 @ 2xF±
17 @ 3xF±
±.3 typ
(±.5 maxꢀ
27 @ 2xF±
15 @ 3xF±
±.3 typ
(±.5 maxꢀ
27 @ 2xF±
17 @ 3xF±
±.3 typ
(±.5 maxꢀ
25 @ 2xF±
17 @ 3xF±
Note: additional frequencies available upon request
66
Thin-Film Low Pass Filter
LP0603 Lead-Free LGA Type Test Jig
LP0603A0947ANTR
LP0603A0902ANTR
0
0
-5
S21
S11
S21
F0
F0
-5
-10
-15
-20
-25
-30
–35
-40
-45
-50
-10
-15
-20
-25
-30
–35
-40
-45
-50
3*F0
3*F0
S11
2*F0
2*F0
0
0.25 0.5 0.75
1
1.25 1.5 1.75
2
2.25 2.5 2.75
3
3.25 3.5 3.75
4
0
0.25 0.5 0.75
1
1.25 1.5 1.75
2
2.25 2.5 2.75
3
3.25 3.5 3.75
4
Frequency (GHz)
Frequency (GHz)
LP0603A1747ANTR
LP0603A1842ANTR
0
-5
0
-5
S21
F0
S21
F0
-10
-15
-20
-25
-30
–35
-40
-45
-50
-10
-15
-20
-25
-30
–35
-40
-45
-50
S11
S11
3*F0
3*F0
4
2*F0
2*F0
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
6.5
7
7.5
8
8.5
9
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
6.5
7
7.5
8
Frequency (GHz)
Frequency (GHz)
LP0603A1880ANTR
LP0603A1950ANTR
0
-5
0
S21
S11
S21
F0
F0
-5
-10
-15
-20
-25
-30
–35
-40
-45
-50
-10
-15
-20
-25
-30
–35
-40
-45
-50
S11
3*F0
3*F0
2*F0
2*F0
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
6.5
7
7.5
8
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
6.5
7
7.5
8
Frequency (GHz)
Frequency (GHz)
67
Thin-Film Low Pass Filter
LP0603 Lead-Free LGA Type Test Jig
LP0603A2140ANTR
LP0603A2442ANTR
0
0
-5
S21
F0
S21
S11
-5
-10
-15
-20
-25
-30
–35
-40
-45
-50
-10
-15
-20
-25
-30
–35
-40
-45
-50
S11
3*F0
3*F0
2*F0
2*F0
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
6
6.5
7
7.5
8
0
0.5
1
1.5
2
2.5
3
3.5
4 4.5 5 5.5 6 6.5 7 7.5 8 8.5 9 9.5 10
Frequency (GHz)
Frequency (GHz)
TEST JIG FOR LP0603 LEAD-FREE LGA LOW PASS FILTER
GENERAL DESCRIPTION
MEASUREMENT PROCEDURE
These jigs are designed for testing the LP0603 LGA Low
Pass Filters using a Vector Network Analyzer.
Follow the VNA’s instruction manual and use the calibration
jig to perform a full 2-Port calibration in the required band-
widths.
4
They consist of a dielectric substrate, having 50Ω microstrips
as conducting lines and a bottom ground plane located at a
distance of 0.127mm from the microstrips.
Solder the filter to the measurement jig as follows:
Input
(Filter)
➨ Connector 1 (Jig)
➨ Connector 2 (Jig)
GND (Filter) ➨ GND (Jig)
GND (Filter) ➨ GND (Jig)
The substrate used is Neltec’s NH9338ST0127C1BC (or
similar).
Output
(Filter)
The connectors are SMA type (female), ‘Johnson
Components Inc.’ Product P/N: 142-0701-841 (or similar).
Both a measurement jig and a calibration jig are provided.
Set the VNA to the relevant frequency band. Connect the
VNA using a 10dB attenuator on the jig terminal connected
to port 2 (using an RF cable).
The calibration jig is designed for a full 2-port calibration, and
consists of an open line, short line and through line. LOAD
calibration can be done by a 50Ω SMA termination.
Measurement
Calibration Jig
Short line to
GND
Open
line
Connector 1
Connector 2
Connector
Johnson
P/N 152-0701-841
Load &
Through
Load &
OUT
68
Thin-Film Low Pass Filter
LP0805 Type Harmonic
DIMENSIONS: millimeters (inches)
GENERAL DESCRIPTION
2.±3±±.1
The ITF (Integrated Thin-Film) SMD Filter is based on thin-film
multilayer technology. The technology provides a miniature
part with excellent high frequency performance and rugged
construction for reliable automatic assembly.
L
W
T
(±.±8±±±.±±4ꢀ
1.55±±.1
(±.±61±±.±±4ꢀ
1.±2±±.1
(±.±4±±±.±±4ꢀ
±.56±±.25
(±.±22±±.±1±ꢀ
±.35±±.15
(±.±14±±.±±6ꢀ
The ITF Filter is offered in a variety of frequency bands com-
patible with various types of high frequency wireless systems.
A
B
FEATURES
• Small Size: 0805
• Frequency Range: 800MHz - 3.5GHz
• Characteristic Impedance: 50Ω
• Operating / Storage Temp.: -40°C to +85°C
• Power Rating: 3W Continuous
• Low Profile
FINAL QUALITY INSPECTION
Finished parts are 100ꢀ tested for electrical parameters and
visual/mechanical characteristics. Each production lot is
evaluated on a sample basis for:
• Rugged Construction
• Taped and Reeled
• Static Humidity: 85°C, 85ꢀ RH, 160 hours
• Endurance: 125°C, IR 4 hours
APPLICATIONS
TERMINATION
Nickel/Solder coating (Sn, Pb) compatible with automatic
soldering technologies: reflow, wave soldering, vapor phase
and manual.
• Mobile Communications
• Satellite TV Receivers
• GPS
4
• Vehicle Location Systems
• Wireless LAN’s
HOW TO ORDER
LP
0805A
0902
AW
TR
Style
Low Pass
Size
0805
Frequency
Termination
Nickel/Solder (Sn/Pb)
Packaging Code
TR = Tape and Reel
MHz
TERMINALS AND LAYOUT (Top View)
Orientation in Tape
TYPE A
TYPE B
TYPE C
TYPE D
IN
GND
IN
GND
IN
GND
GND
IN
GND
GND
OUT
GND OUT
GND
OUT
OUT
69
Thin-Film Low Pass Filter
LP0805 Type Harmonic
ELECTRICAL CHARACTERISTICS
Part
Frequency
Band (MHz)
880 - 915
925 - 960
890 - 915
935 - 960
1007 - 1231
824 - 849
I. Loss
max
VSWR
max
Attenuation
(dB) Typical
Layout
Application
Number
Type
A
E-GSM
LP0805A0897AW
LP0805A0942AW
LP0805A0902AW
LP0805A0947AW
LP0805A1119AW
LP0805A0836AW
LP0805A0881AW
LP0805A1747AW
LP0805A1842AW
LP0805A1880AW
LP0805A1960AW
LP0805A1907AW
LP0805A1890AW
LP0805A2150AW
A
A
A
A
A
A
D
D
D
D
D
D
B
GSM
AMPS
PCN
PCS
869 - 894
1710 - 1785
1805 - 1880
1850 - 1910
1930 - 1990
1895 - 1920
1880 - 1900
1935 - 2365
2400 - 2484
3400 ~ 3600
0.4dB
(0.3dB typ)
1.7
30 @ 2XFo
20 @ 3xFo
PHP
DECT
3G
Wireless LAN LP0805A2442AW
B
C
WLL
LP0805A3500AW
Typical Electrical Performance
LP0805A0902AWTR
LP0805A0836AWTR
LP0805A0881AWTR
±
±
±
Fo
Fo
Fo
-1±
-2±
-3±
-4±
-1±
-2±
-3±
-4±
-1±
-2±
-3±
4
3Fo
3Fo
-4±
3Fo
2Fo
2Fo
2Fo
-5±
-5±
-5±
-6±
-7±
-6±
-7±
-6±
-7±
±
±.5
1
1.5
2
2.5
3
3.5
4
±
±.5
1
1.5
2
2.5
3
3.5
4
±
±.5
1
1.5
2
2.5
3
3.5
Frequency (GHzꢀ
Frequency (GHzꢀ
Frequency (GHzꢀ
LP0805A1842AWTR
LP0805A1747AWTR
LP0805A0967AWTR
±
±
±
Fo
Fo
Fo
-1±
-2±
-3±
-4±
-1±
-2±
-3±
-4±
-1±
-2±
-3±
-4±
3Fo
3Fo
2Fo
3Fo
2Fo
-5±
-5±
-5±
2Fo
-6±
-7±
-6±
-7±
-6±
-7±
±
1
2
3
4
5
6
7
8
9
1±
±
1
2
3
4
5
6
7
8
9
1±
±
±.5
1
1.5
2
2.5
3
3.5
4
Frequency (GHzꢀ
Frequency (GHzꢀ
Frequency (GHzꢀ
LP0805A1950AWTR
LP0805A2442AWTR
LP0805A3500AWTR
±
±
±
Fo
Fo
Fo
-1±
-2±
-3±
-4±
-1±
-2±
-3±
-4±
-1±
-2±
-3±
-4±
3Fo
3Fo
3Fo
2Fo
-5±
-5±
-5±
2Fo
-6±
-7±
-6±
-7±
-6±
-7±
2Fo
±
1
2
3
4
5
6
7
8
9
1±
±
1
2
3
4
5
6
7
8
9
1±
±
1
2
3
4
5
6
7
8
9
1±
11
12 13
Frequency (GHzꢀ
Frequency (GHzꢀ
Frequency (GHzꢀ
LP0805A1119AWTR
LP0805A2150AWTR
±
-1±
-2±
-3±
-4±
-5±
-6±
-7±
±
Fo
Fo
-1±
-2±
-3±
-4±
-5±
-6±
-7±
3Fo
3Fo
2Fo
2Fo
±
±.5
1
1.5
2
2.5
3
3.5
4
±
1
2
3
4
5
6
7
8
9
1±
Frequency (GHzꢀ
Frequency (GHzꢀ
7±
Thin-Film Low Pass Filter
LP0805 Test Jig
ITF TEST JIG FOR LOW PASS FILTER 0805
GENERAL DESCRIPTION
This jig is designed for the testing of the 0805 Low Pass Filter
using a vector network analyzer.
CALIBRATION AND
MEASUREMENT PROCEDURE
The jig is designed for a full 2-port calibration. LOAD calibra-
It consists of a FR4 multi-layer substrate, having 50Ω
microstrips as conducting lines and a ground plane in the
middle layer, located at a distance of 0.2mm from the
microstrips.
tion is carried out using a 50Ω SMA termination.
To measure a component, it can be either soldered or
pressed down by a non-metallic stick until all four ports
touch the appropriate pads.
The connectors are SMA type (female), ‘Johnson Components
Inc.’ Product P/N: 142-0701-881.
Calibration
Measurement
Short
4
Thru/Load
Open
Open
OUT
IN
Connector
p/n 142-0701-881
(6x)
Connector
p/n 142-0701-881
(6x)
GND
71
Thin-Film Products
Designer Kits
Accu-P®/Accu-L® Kits
5
72
RF/Microwave Thin-Film Products
Designer Kits (Special Kits Available Upon Request)
®
®
®
Accu-P
Accu-P
Accu-P
Designer Kit Type 1700
Designer Kit Type 1800
Designer Kit Type 1300
®
®
®
Order Number: Accu-P 0201KIT02
Order Number: Accu-P 0201KIT03
Order Number: Accu-P 0402KIT01
Capacitors
Value pF
Capacitors
Value pF
Capacitors
Value pF
Volts
Tolerance
Volts
Tolerance
Volts
Tolerance
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
1.5
1.8
2.0
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.7
5.6
6.8
7.5
8.2
10.0
12.0
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
G
G
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
3.0
3.1
3.3
3.4
3.6
3.9
4.1
4.3
4.5
4.7
A
A
A
A
A
A
A
A
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.5
1.8
2.0
2.2
2.4
2.7
3.0
3.3
3.9
4.7
5.6
6.8
8.2
10.0
12.0
15.0
18.0
22.0
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
G
G
G
G
G
25
25
25
16
10
16
10
16
10
600 Capacitors, 20 each of 30 values
Tolerance A = 0.05pF
B = 0.1pF
600 Capacitors, 20 each of 30 values
Tolerance A = 0.05pF
B = 0.1pF
600 Capacitors, 20 each of 30 values
Tolerance A = 0.05pF
B = 0.1pF
G = 2ꢀ
G = 2ꢀ
®
®
®
Accu-P
Accu-P
Accu-P
Designer Kit Type 1400
Designer Kit Type 900
Designer Kit Type 800
®
®
®
Order Number: Accu-P 0402KIT02
Order Number: Accu-P 0603KIT01
Order Number: Accu-P 0805KIT02
5
Capacitors
Capacitors
Capacitors
Volts
Tolerance
Volts
Tolerance
Volts
Tolerance
Value pF
Value pF
Value pF
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.5
1.8
2.0
2.2
2.4
2.7
3.0
3.3
3.9
4.7
5.6
6.8
8.2
10.0
12.0
15.0
18.0
22.0
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
G
G
G
G
G
0.1
A
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
G
G
G
G
G
J
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
3.0
3.1
3.3
3.4
3.6
3.9
4.1
4.3
4.5
4.7
A
A
A
A
A
A
A
A
A
A
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
0.2
0.3
0.4
0.5
0.7
0.8
0.9
1.0
1.2
100
1.5
1.8
2.0
50
2.2
25
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10.0
12.0
15.0
18.0
22.0
27.0
33.0
39.0
47.0
50
25
J
25
J
J
600 Capacitors, 20 each of 30 values
Tolerance A = 0.05pF
B = 0.1pF
300 Capacitors, 10 each of 30 values
Tolerance A = 0.05pF G = 2ꢀ
B = 0.1pF J = 5ꢀ
600 Capacitors, 20 each of 30 values
Tolerance A = 0.05pF
B = 0.1pF
G = 2ꢀ
73
RF/Microwave Thin-Film Products
Designer Kits (Special Kits Available Upon Request)
®
®
Accu-P
Accu-P
Designer Kit Type 700
Designer Kit Type 2100
®
®
Order Number: Accu-P 1210KIT02
Order Number: Accu-P 0402KIT03
Capacitors
Value pF
Capacitors
Value pF
Volts
Tolerance
Volts
Tolerance
1.0
B
B
B
B
B
B
B
B
B
G
G
G
G
G
G
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
0.75
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
1.5
1.8
2.2
2.7
3.3
4.7
100
5.6
25
6.8
10.0
12.0
18.0
22.0
27.0
33.0
150 Capacitors, 10 each of 15 values
Tolerance B = 0.1pF
G = 2ꢀ
300 Capacitors, 20 each of 15 values
Tolerance P = 0.02pF
®
®
Accu-P
Accu-P
Designer Kit Type 2200
Designer Kit Type 2000
®
®
Order Number: Accu-P 0603KIT02
Order Number: Accu-P 0201KIT04
Capacitors
Value pF
Capacitors
Value pF
Volts
Tolerance
Volts
Tolerance
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
0.75
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
0.75
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
50
25
5
300 Capacitors, 20 each of 15 values
Tolerance P 0.02pF
300 Capacitors, 20 each of 15 values
Tolerance P 0.02pF
=
=
®
®
Accu-L
Accu-L
Designer Kit Type 1600
Designer Kit Type 1100
®
®
Order Number: Accu-L 0603KIT02
Order Number: Accu-L 0805KIT02
Inductance
Tolerance
Value (nH)
Inductance
Tolerance
Value (nH)
1.2
1.5
1.8
2.2
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10
C
C
C
C
C
C
C
C
C
C
C
G
G
G
1.8
2.2
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10.0
12.0
15.0
18.0
22.0
C
C
C
C
C
C
C
D
D
J
J
J
12
15
J
J
280 Inductors, 20 each of 14 values
280 Inductors, 20 each of 14 values
Tolerance
C = 0.2nH
G = 2ꢀ
Tolerance
C = 0.2nH
D = 0.5nH
J = 5ꢀ
74
RF/Microwave
MLC’s
AQ Series
CDR Series
Porcelain and Ceramic
RF/Microwave
Multilayer Capacitors
High Voltage RF Power Capacitors
6
75
Microwave MLC’s
AQ Series
These porcelain and ceramic dielectric multilayer
capacitor (MLC) chips are best suited for RF/
Microwave applications typically ranging from 10
MHz to 4.2 GHz. Characteristic is a fine grained,
high density, high purity dielectric material imper-
vious to moisture with heavy internal palladium
electrodes.
L
W
A
L
T
W
1±1J
W
T
L
1R5
T
These characteristics lend well to applications
requiring:
bw
bw
bw
1) high current carrying capabilities;
2) high quality factors;
Approx. L x W x T
L = .±63"/1.6±mm
W = .±32"/.813mm
Approx. L x W x T
L = .±55"/1.4mm
W = .±55"/1.4mm
Approx. L x W x T
L = .11±"/2.8mm
3) very low equivalent series resistance;
4) very high series resonance;
5) excellent stability under stresses of
changing voltage, frequency, time
and temperature.
W = .11±"/2.8mm
T = .1±2"/2.59mm max.
T = .±35"/.889mm max. T = .±57"/1.45mm max.
AQ06
AQ11/12
AQ13/14
MECHANICAL DIMENSIONS: inches (millimeters)
Case
Length (L)
Width (W)
Thickness (T)
Band Width (bw)
.±63±.±±6
(1.6±±.152ꢀ
.±32±.±±6
(.813±.152ꢀ
.±35 Max.
(.889ꢀ
.±14±.±±6
(.357 +.152ꢀ
AQ±6
.±55±.±15
.±55±.±15
.±2±/.±57
.±1± + .±1± -.±±5
(.254 +.254 -.127ꢀ
AQ11
AQ12
AQ13
AQ14
(1.4±±.381ꢀ
(1.4±±.381ꢀ
(.5±8/1.45ꢀ
.±55 + .±15 - .±1±
(1.4±+ .381 - .254ꢀ
.±55±.±15
(1.4±±.381ꢀ
.±2±/.±57
(.5±8/1.45ꢀ
.±1± + .±1± -.±±5
(.254 +.254 -.127ꢀ
.11±±.±2±
(2.79±.5±8ꢀ
.11±±.±2±
(2.79±.5±8ꢀ
.±3±/.1±2
(.762/2.59ꢀ
.±15±.±1±
(.381±.254ꢀ
.11± + .±2± - .±1±
(2.79 +.889 -.254ꢀ
.11±±.±1±
(2.79±.5±8ꢀ
.±3±/.1±2
(.762/2.59ꢀ
.±15±.±1±
(.381±.254ꢀ
*For Tape and Reel packaging details see page 88
HOW TO ORDER
AQ
11
E
M
100
J
A
1
ME
6
Case Size
(See Chart)
Capacitance
Failure Rate
Packaging*
Code
3A = 13" Reel
(AQ06 only)
6A = Waffle Pack
(AQ06 only)
ME = 7" Reel
RE = 13" Reel
WE = Waffle Pack
1A = 7" Reel
(AQ06 only)
EIA Capacitance Code in pF.
Code
A = Not
First two digits = significant
figures or “R” for decimal
place.
AVX Style
AQ06, AQ11,
AQ12, AQ13,
AQ14
Voltage
Code
Applicable
5 = 50V
1 = 100V
E = 150V
2 = 200V
V = 250V
9 = 300V
7 = 500V
Third digit = number of zeros
or after “R” significant figures.
Termination
Style Code
1 = Pd/Ag
(AQ11/13 only)
7 = Ag/Ni/Au
(AQ11/13 only)
J = Nickel Barrier
Sn/Pb (60/40) -
(AQ06/12/14
only)
Capacitance
Tolerance Code
A = .05 pF
B = .1 pF
C = .25 pF
D = .5 pF
F = 1ꢀ
Temperature
Coefficient Code
M = +90 20ppm/°C (AQ06/11/12/13/14)
A = 0 30ppm/°C (AQ11/12/13/14)
C = 15ꢀ (“J” Termination only) (AQ12/14)
G = 2ꢀ
J = 5ꢀ
K = 10ꢀ
M = 20ꢀ
N = 30ꢀ
PACKAGING
Standard Packaging = Waffle Pack (for T&R packaging see page 88)
AQ11/12 maximum quantity per waffle pack is 100.
AQ13/14 maximum quantity is 80.
76
Microwave MLC’s
AQ Series
ELECTRICAL SPECIFICATIONS
AQ06, AQ11, AQ12, AQ13, AQ14
M & A
C
Temperature Coefficient
(M) +90 20PPM/°C and
15ꢀ
(A) 0 30PPM/°C
0.1 pF to 5100 pF
0.1 pF to 20ꢀ
Capacitance Range
0.001µF to 0.1µF
10ꢀ, 20ꢀ, 30ꢀ
-55°C to +125°C
2.5ꢀ @ 1kHz
Capacitance Tolerance
Operating Temperature
Quality Factor or Dissipation Factor
Insulation Resistance
-55°C + 125°C
Per MIL-PRF-55681/4
Per MIL-PRF-55681
106 megohm to 470 pF @ +25°C
105 megohm to 470 pF @ +125°C
105 megohm above 470 pF @ +25°C
104 megohm above 470 pF @ +125°C
104 megohm min @ 25°C & R VDC
103 megohm min @ 25°C & R VDC
Aging
None
None
2.5 x rated voltage
<3ꢀ per decade hour
None
2.5 x rated voltage
Piezoelectric Effects
Dielectric Withstanding Voltage
(for 500V rated 1.5 x rated voltage)
(for 500V rated 1.5 x rated voltage)
ENVIRONMENTAL CHARACTERISTICS
Will meet or exceed performance characteristics as outlined in MIL-PRF-55681/4.
REQUIREMENT
MIL-STD-202
METHOD
Life
Shock
1±8, Condition F
213, Condition J
2±4, Condition B
1±4, Condition B
1±1, Condition B
2±8
Vibration
Immersion
Salt Spray
Solderability
Thermal Shock
1±7, Condition B
211
Terminal Strength
Temperature Cycling
Moisture Resistance
Barometric Pressure
Resistance to Soldering Heat
1±2, Condition C
1±6
1±5, Condition B
21±, Condition C
6
QUALITY FACTOR vs. FREQUENCY (Typical)
Capacitance
@ 30 MHz
3±±±±
9±±±
@ 150 MHz
@ 500 MHz
@ 1000 MHz
1 pF
4±±±
8±±
4±±
2±±
7±
35±
15±
6±
1± pF
2±±±
3± pF
5±±±
8±±
1±± pF
2±± pF
28±±
4±±
25
15±±
25±
4±
12
CAPACITANCE AND SIZE vs.
SERIES SELF RESONANT FREQUENCY (Typical)
DIMENSIONS: inches (millimeters)
Case
Size (Nominal)
1 pF
10 pF
50 pF
100 pF
.±63 x .±32 x .±35
(1.6± x .813 x .889ꢀ
AQ±6
9.6 GHz
3.2 GHz
1.5 GHz
1.± GHz
.±55 x .±55 x .±57
(1.4± x 1.4± x 1.45ꢀ
AQ11/12
AQ13/14
9.6 GHz
6.4 GHz
3.2 GHz
2.2 GHz
1.5 GHz
1.± GHz
1.± GHz
±.7 GHz
.11± x .11± x .1±2
(2.79 x 2.79 x 2.59ꢀ
77
Microwave MLC’s
AQ Series Available Capacitance/Size/WVDC/T.C.
TABLE I: TC: M (+90 20PPM/°C)
CASE SIZE 06, 11, 12, 13 & 14
DIMENSIONS: inches (millimeters)
Case
Length
Width
Thickness
Band Width
Avail. Term.
06
.063 .006 (1.60 .152)
.055 .015 (1.40 .381)
.055 .025 (1.40 .635)
.110 .020 (2.79 .508)
.032 .006 (.813 .152)
.055 .015 (1.40 .381)
.055 .015 (1.40 .381)
.110 .020 (2.79 .508)
.035 Max. (.889)
.014 .006 (.357 +.152)
J
1 & 7
J
1 & 7
J
11
12
13
14
.020/.057 (.508/1.45) .010 +.010 -.005 (.254 +.254 -.127)
.020/.057 (.508/1.45) .010 +.010 -.005 (.254 +.254 -.127)
.030/.102 (.762/2.59)
.030/.102 (.762/2.59)
.015 .010 (.381 .254)
.015 .010 (.381 .254)
.110 +0.035 -0.020 (2.79 +.889 -.508) .110 .020 (2.79 .508)
Case: AQ11, AQ12
Case: AQ13, AQ14
Case: AQ06
Cap. pF
Cap. Tol.
WVDC Cap. pF
Cap. Tol.
WVDC Cap. pF
Cap. Tol.
WVDC Cap. pF
Cap. Tol.
WVDC
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
250
250
250
250
250
250
250
250
250
250
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
150
150
150
150
150
150
150
150
150
150
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
500
500
500
500
500
500
500
500
500
500
100
110
120
130
150
160
180
200
220
240
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
300
300
300
300
300
300
300
200
200
B
B
B
B,C
B,C
B,C
B,C
B,C
B,C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
250
250
250
250
250
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
150
150
150
150
150
150
150
150
150
150
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
500
500
500
500
500
270
300
330
360
390
430
470
510
560
620
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
200
200
200
200
200
200
200
150
150
150
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
250
250
250
250
250
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
150
150
150
150
150
150
150
150
150
150
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
500
500
500
500
500
680
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
750
820
910
1000
5.6
6.2
6.8
7.5
8.2
B, C, D
250
250
250
250
250
250
250
250
250
250
5.6
6.2
6.8
7.5
8.2
9.1
10
11
12
13
B, C, D
150
150
150
150
150
150
150
150
150
150
5.6
6.2
6.8
7.5
8.2
9.1
10
11
12
13
B, C, D
500
500
500
500
500
500
500
500
500
500
B, C, D
B, C, D
B, C, D
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
6
9.1
10
11
12
13
15
16
18
20
22
24
27
30
33
36
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
250
250
250
250
250
250
250
250
250
50
15
16
18
20
22
24
27
30
33
36
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
150
150
150
150
150
15
16
18
20
22
24
27
30
33
36
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
500
500
500
500
500
500
500
500
500
39
43
47
51
56
62
68
75
82
91
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
39
43
47
51
56
62
68
75
82
91
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
150
150
150
150
150
39
43
47
51
56
62
68
75
82
91
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
500
500
500
500
500
500
500
500
500
100
120
F, G, J, K, M
F, G J K M
50
50
100
F, G, J, K, M
150
78
Microwave MLC’s
AQ Series Available Capacitance/Size/WVDC/T.C.
TABLE II: TC: A (0 30PPM/°C)
CASE SIZE 06, 11, 12, 13 & 14
DIMENSIONS: inches (millimeters)
Case
Length
Width
Thickness
Band Width
Avail. Term.
06
.063 .006 (1.60 .152)
.055 .015 (1.40 .381)
.055 .025 (1.40 .635)
.110 .020 (2.79 .508)
.032 .006 (.813 .152)
.055 .015 (1.40 .381)
.055 .015 (1.40 .381)
.110 .020 (2.79 .508)
.035 Max. (.889)
.014 .006 (.357 +.152)
J
1 & 7
J
1 & 7
J
11
12
13
14
.020/.057 (.508/1.45) .010 +.010 -.005 (.254 +.254 -.127)
.020/.057 (.508/1.45) .010 +.010 -.005 (.254 +.254 -.127)
.030/.102 (.762/2.59)
.030/.102 (.762/2.59)
.015 .010 (.381 .254)
.015 .010 (.381 .254)
.110 +0.035 -0.020 (2.79 +.889 -.508) .110 .020 (2.79 .508)
Case: AQ06
Case: AQ11, AQ12
Case: AQ13, AQ14
Cap. pF
Cap. Tol.
WVDC
Cap. pF
Cap. Tol.
WVDC
Cap. pF
Cap. Tol.
WVDC
Cap. pF
Cap. Tol.
WVDC
Cap. pF
Cap. Tol.
WVDC
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
B
500
500
500
500
500
500
500
500
500
500
51
56
62
68
75
82
91
100
110
120
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
500
500
500
500
500
500
500
300
300
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
B
250
250
250
250
250
250
250
250
250
250
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
B
B
150
150
150
150
150
150
150
150
150
150
24
27
30
33
36
39
43
47
51
56
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
150
150
150
150
150
B,C
B,C
B,C
B,C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B,C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B,C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
1.1
1.2
1.3
1.4
1.5
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
130
150
160
180
200
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
300
300
300
300
300
1.1
1.2
1.3
1.4
1.5
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
1.1
1.2
1.3
1.4
1.5
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
150
150
150
150
150
62
68
75
82
91
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
220
240
270
300
330
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
200
200
200
200
200
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
1.6
1.7
1.8
1.9
2.0
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
150
150
150
150
150
100
110
120
130
150
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
50
50
50
50
2.2
2.4
2.7
3.0
3.3
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
360
390
430
470
510
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
200
200
200
200
150
2.2
2.4
2.7
3.0
3.3
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
2.2
2.4
2.7
3.0
3.3
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
150
150
150
150
150
160
180
200
220
240
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
3.6
3.9
4.3
4.7
5.1
5.6
6.2
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
560
620
680
750
820
910
1000
1100
1200
1300
1500
1600
1800
2000
2200
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
150
150
150
150
150
150
150
50
50
50
50
50
50
50
50
3.6
3.9
4.3
4.7
5.1
5.6
6.2
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
250
250
250
250
250
250
250
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, J, K, M 150
B, C, J, K, M 150
B, C, J, K, M 150
B, C, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
150
150
150
150
150
150
150
270
300
330
360
390
430
470
510
560
620
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
6.8 B, C, J, K, M
7.5 B, C, J, K, M
8.2 B, C, J, K, M
9.1 B, C, J, K, M
10
11
12
13
6.8 B, C, J, K, M 250
7.5 B, C, J, K, M 250
8.2 B, C, J, K, M 250
9.1 B, C, J, K, M 250
10
11
12
13
9.1
680
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
10
750
11
820
12
910
13
1000
15
16
18
20
22
24
27
30
33
36
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
500
500
500
500
500
500
500
500
500
2400
2700
3000
3300
3600
3900
4300
4700
5000
5100
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
15
16
18
20
22
24
27
30
33
36
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
15
16
18
20
22
F, G, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
F, G, J, K, M 150
6
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M 250
F, G, J, K, M
50
39
43
47
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
500
500
500
39
43
47
51
56
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
62
68
75
82
91
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
100
120
F, G, J, K, M
F, G J K M
50
50
TABLE III: TC: C ( 15ꢀ)
CASE SIZE 12 & 14
Case: AQ12
Case: AQ14
Cap. pF Cap. Tol. WVDC
Cap. pF Cap. Tol. WVDC
Cap. pF Cap. Tol. WVDC
Cap. pF Cap. Tol. WVDC
Cap. pF Cap. Tol. WVDC
Cap. pF Cap. Tol. WVDC
1000
1200
1500
1800
2000
K, M, N
K, M, N
K, M, N
K, M, N
K, M, N
50
50
50
50
50
2200 K, M, N
2700 K, M, N
3300 K, M, N
3900 K, M, N
4700 K, M, N
50
50
50
50
50
5100
5600
6800
8200
10000
K, M, N
K, M, N
K, M, N
K, M, N
K, M, N
50
50
50
50
50
5000
6800
K, M, N
K, M, N
K, M, N
K, M, N
K, M, N
50
50
50
50
50
15000 K, M, N
18000 K, M, N
27000 K, M, N
33000 K, M, N
39000 K, M, N
50
50
50
50
50
47000 K, M, N
68000 K, M, N
50
50
8200
82000 K, M, N
100000 K, M, N
50
50
10000
12000
79
Microwave MLC’s
CDR Series — MIL-PRF-55681 (RF/Microwave Chips)
MILITARY DESIGNATION PER MIL-PRF-55681
L
W
A
L
T
W
47±J
T
1±±J
bw
bw
CDR11/12
CDR13/14
CROSS REFERENCE: AVX/MIL-PRF-55681
Per MIL-C-55681
AVX
Length (L)
Width (W)
Thickness (T)
Termination Band (bw)
Style
Max
Min
Max
Min
.±55±.±15
.±55±.±15
.±57
.±2±
.±2±
.±±5
CDR11
CDR12
CDR13
CDR14
AQ11
AQ12
AQ13
AQ14
(1.4±±.381ꢀ
(1.4±±.381ꢀ
(1.45ꢀ
(.5±8ꢀ
(.5±8ꢀ
(.127ꢀ
.±55±.±25
.±55±.±15
.±57
.±2±
.±2±
.±±5
(1.4±±.635ꢀ
(1.4±±.381ꢀ
(1.45ꢀ
(.5±8ꢀ
(.5±8ꢀ
(.127ꢀ
.11±±.±2±
.11±±.±2±
.1±2
.±3±
.±25
.±±5
(2.79±.5±8ꢀ
(2.79±.5±8ꢀ
(2.59ꢀ
(.762ꢀ
(.635ꢀ
(.127ꢀ
.11± +.±35 -±.2±
(2.79 +.889 -.5±8ꢀ
.11±±.±2±
.1±2
.±3±
.±25
.±±5
(2.79±.5±8ꢀ
(2.59ꢀ
(.762ꢀ
(.635ꢀ
(.127ꢀ
HOW TO ORDER
CDR12
BG
101
A
K
U
S
MIL Style
CDR11, CDR12,
CDR13, CDR14
Capacitance
EIA Capacitance Code in pF.
Capacitance
Tolerance Code
B = .1 pF
C = .25 pF
D = .5 pF
F = 1ꢀ
Failure Rate
Level
M = 1.0ꢀ
P = .1ꢀ
First two digits = significant figures
or “R” for decimal place.
R = .01ꢀ
S = .001ꢀ
6
Third digit = number of zeros or
after “R” significant figures.
Termination
Finish (Military
Designations)
Code
G = 2ꢀ
J = 5ꢀ
K = 10ꢀ
M = 20ꢀ
Voltage
Temperature
Limits
Rated Voltage
Code
M = Palladium/Silver
(CDR11 & 13 only)
N = Silver, Nickel, Gold
(CDR11 & 13 only)
S = Solder Coated, Final
(CDR12 & 14 only)
U = Base Metallization, Barrier Metal,
Solder Coated.
(Solder M.P. 200°C or less)
(CDR12 & 14 only)
W = Base Metallization, Barrier Metal,
Tinned (Tin or Tin/Lead Alloy)
(CDR12 & 14 only)
A = 50V
B = 100V
C = 200V
D = 300V
E = 500V
BG = +90 20 ppm/°C
with and without
rated voltage from
-55°C to + 125°C
BP = 0 30ppm/°C
with and without
rated voltage from
-55°C to +125°C
Y = 100ꢀ Tin
Z = Base Metallization, Barrier Metal
(TIn Lead Alloy With 4ꢀ Lead Min.)
PACKAGING
Standard Packaging = Waffle Pack (for T&R packaging see page 88)
AQ11/12 maximum quantity per waffle pack is 100.
AQ13/14 maximum quantity is 80.
8±
Microwave MLC’s
CDR Series — MIL-PRF-55681 (RF/Microwave Chips)
TABLE I: STYLES CDR11 AND CDR12 CAPACITOR CHARACTERISTICS
Type
Rated temperature
Type
Rated temperature
Designation Capacitance Capacitance
and
WVDC
Designation Capacitance Capacitance
and
WVDC
1/
in pF
tolerance
V/Temperature
1/
in pF
tolerance
V/Temperature
CDR1 -B-±R1AB--
CDR1 -B-±R2AB--
CDR1 -B-±R3A---
CDR1 -B-±R4A---
CDR1 -B-±R5A---
CDR1 -B-±R6A---
CDR1 -B-±R7A---
CDR1 -B-±R8A---
CDR1 -B-±R9A---
CDR1 -B-1R±A---
CDR1 -B-1R1A---
CDR1 -B-1R2A---
CDR1 -B-1R3A---
CDR1 -B-1R4A---
CDR1 -B-1R5A---
CDR1 -B-1R6A---
CDR1 -B-1R7A---
CDR1 -B-1R8A---
CDR1 -B-1R9A---
CDR1 -B-2R±A---
CDR1 -B-2R1A---
CDR1 -B-2R2A---
CDR1 -B-2R4A---
CDR1 -B-2R7A---
CDR1 -B-3R±A---
CDR1 -B-3R3A---
CDR1 -B-3R6A---
CDR1 -B-3R9A---
CDR1 -B-4R3A---
CDR1 -B-4R7A---
CDR1 -B-5R1A---
CDR1 -B-5R6A---
CDR1 -B-6R2A---
CDR1 -B-6R8A---
CDR1 -B-7R5A---
CDR1 -B-8R2A---
CDR1 -B-9R1A---
CDR1 -B-1±±A---
CDR1 -B-11±A---
CDR1 -B-12±A---
CDR1 -B-13±A---
CDR1 -B-15±A---
CDR1 -B-16±A---
CDR1 -B-18±A---
CDR1 -B-2±±A---
CDR1 -B-22±A---
CDR1 -B-24±A---
CDR1 -B-27±A---
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
1.±
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.±
2.1
2.2
2.4
2.7
3.±
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
1±
B
B
B, C
B, C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
CDR1 -B-3±±A---
CDR1 -B-33±A---
CDR1 -B-36±A---
CDR1 -B-39±A---
CDR1 -B-43±A---
CDR1 -B-47±A---
CDR1 -B-51±A---
CDR1 -B-56±A---
CDR1 -B-62±A---
CDR1 -B-68±A---
CDR1 -B-75±A---
CDR1 -B-82±A---
CDR1 -B-91±A---
CDR1 -B-1±1A---
CDR1 -B-111A---
CDR1 -B-121A---
CDR1 -B-131A---
CDR1 -B-151A---
CDR1 -B-161A---
CDR1 -B-181A---
CDR1 -B-2±1A---
CDR1 -B-221A---
CDR1 -B-241A---
CDR1 -B-271A---
CDR1 -B-3±1A---
CDR1 -B-331A---
CDR1 -B-361A---
CDR1 -B-391A---
CDR1 -B-431A---
CDR1 -B-471A---
CDR1 -B-511A---
CDR1 -B-561A---
CDR1 -B-621A---
CDR1 -B-681A---
CDR1 -B-751A---
CDR1 -B-821A---
CDR1 -B-911A---
CDR1 -B-1±2A---
3±
33
36
39
43
47
51
56
62
68
75
82
91
1±±
11±
12±
13±
15±
16±
18±
2±±
22±
24±
27±
3±±
33±
36±
39±
43±
47±
51±
56±
62±
68±
75±
82±
91±
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
B, C, D
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
1±±±
11
12
13
15
16
18
2±
22
1/Complete type designation will include additional symbols to indicate style,
voltage-temperature limits, capacitance tolerance (where applicableꢀ, termina-
tion finish (“M” or “N” for style CDR11, and “S”, “U” or “W” for style CDR12ꢀ
and failure rate level.
24
27
6
81
Microwave MLC’s
CDR Series — MIL-PRF-55681 (RF/Microwave Chips)
TABLE II: STYLES CDR13 AND CDR14 CAPACITOR CHARACTERISTICS
Type
Rated temperature
Type
Rated temperature
Designation Capacitance Capacitance
and
WVDC
Designation Capacitance Capacitance
and
WVDC
1/
in pF
tolerance
V/Temperature
1/
in pF
tolerance
V/Temperature
CDR1 -B-±R1*B--
CDR1 -B-±R2*B--
CDR1 -B-±R3*---
CDR1 -B-±R4*---
CDR1 -B-±R5*---
CDR1 -B-±R6*---
CDR1 -B-±R7*--
CDR1 -B-±R8*---
CDR1 -B-±R9*---
CDR1 -B-1R±*---
CDR1 -B-1R1*---
CDR1 -B-1R2*---
CDR1 -B-1R3*---
CDR1 -B-1R4*---
CDR1 -B-1R5*---
CDR1 -B-1R6*---
CDR1 -B-1R7*---
CDR1 -B-1R8*---
CDR1 -B-1R9*---
CDR1 -B-2R±*---
CDR1 -B-2R1*---
CDR1 -B-2R2*--
CDR1 -B-2R4*---
CDR1 -B-2R7*---
CDR1 -B-3R±*---
CDR1 -B-3R3*---
CDR1 -B-3R6*---
CDR1 -B-3R9*---
CDR1 -B-4R3*---
CDR1 -B-4R7*---
CDR1 -B-5R1*---
CDR1 -B-5R6*---
CDR1 -B-6R2*---
CDR1 -B-6R8*---
CDR1 -B-7R5*---
CDR1 -B-8R2*---
CDR1 -B-9R1*---
CDR1 -B-1±±*---
CDR1 -B-11±*---
CDR1 -B-12±*---
CDR1 -B-13±*---
CDR1 -B-15±*---
CDR1 -B-16±*---
CDR1 -B-18±*---
CDR1 -B-2±±*---
CDR1 -B-22±*---
CDR1 -B-24±*---
CDR1 -B-27±*---
CDR1 -B-3±±*---
CDR1 -B-33±*---
CDR1 -B-36±*---
CDR1 -B-39±*---
CDR1 -B-43±*---
CDR1 -B-47±*---
CDR1 -B-51±*---
±.1
±.2
±.3
±.4
±.5
±.6
±.7
±.8
±.9
1.±
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.±
2.1
2.2
2.4
2.7
3.±
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
1±
11
12
13
15
16
18
2±
22
24
27
3±
33
36
39
43
47
B
B
B, C
B, C
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
B, C, D
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
CDR1 -B-56±*---
CDR1 -B-62±*---
CDR1 -B-68±*---
CDR1 -B-75±*---
CDR1 -B-82±*---
CDR1 -B-91±*---
CDR1 -B-1±1*---
CDR1 -B-111‡---
CDR1 -B-121‡---
CDR1 -B-131‡---
CDR1 -B-151‡---
CDR1 -B-161‡---
CDR1 -B-181‡---
CDR1 -B-2±1‡---
CDR1 -B-221C---
CDR1 -B-241C---
CDR1 -B-271C---
CDR1 -B-3±1C---
CDR1 -B-331C---
CDR1 -B-361C---
CDR1 -B-391C---
CDR1 -B-431C---
CDR1 -B-471C---
CDR1 -B-511B---
CDR1 -B-561B---
CDR1 -B-621B---
CDR1 -B-681A---
CDR1 -B-751A---
CDR1 -B-821A---
CDR1 -B-911A---
CDR1 -B-1±2A---
CDR1 -B-112A---
CDR1 -B-122A---
CDR1 -B-132A---
CDR1 -B-152A---
CDR1 -B-162A---
CDR1 -B-182A---
CDR1 -B-2±2A---
CDR1 -B-222A---
CDR1 -B-242A---
CDR1 -B-272A---
CDR1 -B-3±2A---
CDR1 -B-332A---
CDR1 -B-362A---
CDR1 -B-392A---
CDR1 -B-432A---
CDR1 -B-472A---
CDR1 -B-5±2A---
CDR1 -B-512A---
56
62
68
75
82
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BG, BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
BP
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/5±±
2±±/3±±
2±±/3±±
2±±/3±±
2±±/3±±
2±±/3±±
2±±/3±±
2±±/3±±
2±±
2±±
2±±
2±±
2±±
2±±
2±±
2±±
2±±
1±±
1±±
1±±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
91
1±±
11±
12±
13±
15±
16±
18±
2±±
22±
24±
27±
3±±
33±
36±
39±
43±
47±
51±
56±
62±
68±
75±
82±
91±
1±±±
11±±
12±±
13±±
15±±
16±±
18±±
2±±±
22±±
24±±
27±±
3±±±
33±±
36±±
39±±
43±±
47±±
5±±±
51±±
B, C, D
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
B, C, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
5±
5±
5±
5±
5±
5±
5±
5±
5±
5±
BP
1/Complete type designation will include additional symbols to indicate style,
voltage-temperature limits, capacitance tolerance (where applicableꢀ, termina-
tion finish (“M” or “N” for style CDR13, and “S”, “U” or “W” for style CDR14ꢀ
and failure rate level.
6
51
*C=2±±V; E=5±±V.
‡C=2±±V; D=3±±V.
82
Microwave MLC’s
Performance Curves
TYPICAL Q vs. FREQUENCY
TYPICAL ESR vs. FREQUENCY
AQ11/12
AQ11/12
MIL-PRF-55681E - BG
STANDARD - M
MIL-PRF-55681E - BG
STANDARD - M
1±±±±
1
1±±±
Q
ESR (ohmsꢀ ±.1
1±±
±.±1
1±
1±±
1±±±
1±±
1±±±
Frequency (MHzꢀ
Frequency (MHzꢀ
AVX CORPORATION
AVX CORPORATION
1± Picofarad
1 Picofarad
1± Picofarad
1±± Picofarad
3.3 Picofarad
1±± Picofarad
TYPICAL ESR vs. CAPACITANCE
AQ11/12
TYPICAL Q vs. CAPACITANCE
AQ11/12
MIL-PRF-55681E - BG
STANDARD - M
MIL-PRF-55681E - BG
STANDARD - M
1
1±±±±
1±±±
1±±
6
ESR (ohmsꢀ ±.1
Q
±.±1
1±
1
1±
1±±
1
1±
1±±
Capacitance (pFꢀ
Capacitance (pFꢀ
AVX CORPORATION
5±± MHz
AVX CORPORATION
5±± MHz
25± MHz
1±±± MHz
25± MHz
1±±± MHz
83
Microwave MLC’s
Performance Curves
TYPICAL Q vs. FREQUENCY
AQ13/14
TYPICAL ESR vs. FREQUENCY
AQ13/14
MIL-PRF-55681E - BG
MIL-PRF-55681E - BG
STANDARD - M
STANDARD - M
1±±±±
1
1±±±
Q
ESR (ohmsꢀ ±.1
1±±
±.±1
1±
1±±
1±±±
1±±
1±±±
Frequency (MHzꢀ
Frequency (MHzꢀ
AVX CORPORATION
AVX CORPORATION
15 Picofarad
1 Picofarad
1± Picofarad
47 Picofarad
33± Picofarad
1 Picofarad
1±± Picofarad
TYPICAL Q vs. CAPACITANCE
AQ13/14
TYPICAL ESR vs. CAPACITANCE
AQ13/14
MIL-PRF-55681E - BG
STANDARD - M
MIL-PRF-55681E - BG
STANDARD - M
1±±±±
1
6
1±±±
1±±
1±
ESR (ohmsꢀ ±.1
Q
±.±1
1
1±
1±±
1
1±
1±±
Capacitance (pFꢀ
Capacitance (pFꢀ
AVX CORPORATION
5±± MHz
AVX CORPORATION
5±± MHz
25± MHz
1±±± MHz
25± MHz
1±±± MHz
84
Microwave MLC’s
Performance Curves
TYPICAL ESR vs. FREQUENCY
AQ11/12
TYPICAL Q vs. FREQUENCY
AQ11/12
MIL-PRF-55681E - BP
STANDARD - A
MIL-PRF-55681E - BP
STANDARD - A
1
1±±±±
1±±±
ESR (ohmsꢀ ±.1
Q
1±±
±.±1
1±
1±±
1±±±
1±±
1±±±
Frequency (MHzꢀ
Frequency (MHzꢀ
AVX CORPORATION
15 Picofarad
AVX CORPORATION
15 Picofarad
1 Picofarad
1±± Picofarad
1 Picofarad
1±± Picofarad
TYPICAL Q vs. CAPACITANCE
AQ11/12
TYPICAL ESR vs. CAPACITANCE
AQ11/12
MIL-PRF-55681E - BP
STANDARD - A
MIL-PRF-55681E - BP
STANDARD - A
1±±±±
1±±±
1±±
1
6
ESR (ohmsꢀ ±.1
Q
1±
±.±1
1
1±
1±±
1
1±
1±±
Capacitance (pFꢀ
Capacitance (pFꢀ
AVX CORPORATION
5±± MHz
AVX CORPORATION
5±± MHz
25± MHz
1±±± MHz
25± MHz
1±±± MHz
85
Microwave MLC’s
Performance Curves
TYPICAL ESR vs. FREQUENCY
AQ13/14
TYPICAL Q vs. FREQUENCY
AQ13/14
MIL-PRF-55681E - BP
STANDARD - A
MIL-PRF-55681E - BP
STANDARD - A
1
1±±±±
1±±±
ESR (ohmsꢀ ±.1
Q
1±±
±.±1
1±
1±±
1±±±
1±±
1±±±
Frequency (MHzꢀ
Frequency (MHzꢀ
AVX CORPORATION
47 Picofarad
AVX CORPORATION
15 Picofarad
15 Picofarad
1±± Picofarad
2 Picofarad
1±± Picofarad
TYPICAL Q vs. CAPACITANCE
AQ13/14
TYPICAL ESR vs. CAPACITANCE
AQ13/14
MIL-PRF-55681E - BP
STANDARD - A
MIL-PRF-55681E - BP
STANDARD - A
1±±±±
1±±±
1±±
1
6
ESR (ohmsꢀ ±.1
Q
1±
±.±1
1
1±
1±±
1
1±
1±±
Capacitance (pFꢀ
Capacitance (pFꢀ
AVX CORPORATION
5±± MHz
AVX CORPORATION
5±± MHz
25± MHz
1±±± MHz
25± MHz
1±±± MHz
86
Microwave MLC’s
Performance Curves
6
F r e q u e n c y ( G H z ꢀ
F r e q u e n c y ( G H z ꢀ
87
Microwave MLC’s
Automatic Insertion Packaging
TAPE & REEL: All tape and reel specifications are in compliance with EIA RS481 (equivalent to IEC 286 part 3ꢀ.
“U” Series - 0603/0805/1210 Size Chips
Sizes AQ11/12 through 13/14, CDR11/12 through 13/14.
—8mm carrier
—8mm carrier
—7" reel: 0603 & 0805 ≤0.40" thickness = 4000 pcs
0805 . 0.040" thickness & 1210= 2000 pcs
—13" reel: ≤0.075" thickness = 10,000 pcs
—7" reel: ≤0.040" thickness = 2000 pcs
≤0.075" thickness = 2000 pcs
—13" reel: ≤0.075" thickness = 10,000 pcs
REEL DIMENSIONS: millimeters (inches)
Tape
A
B*
C
D*
N
W2
Max.
W3
W1
Size(1) Max. Min.
Min. Min.
7.9 Min.
(.311ꢀ
(.567ꢀ 1±.9 Max.
(.429ꢀ
1.±
8mm
8.4 +-±.±
14.4
(.331+.±6±
ꢀ
-±.±
33±
1.5 13.±±±.2± 2±.2
5±
(12.992ꢀ (.±59ꢀ (.512±.±±8ꢀ (.795ꢀ (1.969ꢀ
11.9 Min.
(.469ꢀ
ꢀ (.724ꢀ 15.4 Max.
(.6±7ꢀ
12mm
12.4 +-±2..±±
18.4
+.±76
-±.±
(.488
Metric dimensions will govern.
English measurements rounded and for reference only.
(1ꢀ For tape sizes 16mm and 24mm (used with chip size 364±ꢀ consult EIA RS-481 latest revision.
EMBOSSED CARRIER CONFIGURATION
8 & 12 MM TAPE ONLY
CONSTANT DIMENSIONS
Tape
Size
8mm
and
D0
E
P0
P2
T
T1
G1
G2
Max.
8.4 -+±±..±1±
1.75 ± ±.1±
4.± ± ±.1±
2.± ± ±.±5
±.6±± ±.1± ±.75 ±.75
(.±59 +.±±4
ꢀ
(.±69 ± .±±4ꢀ (.157 ± .±±4ꢀ (.±79 ± .±±2ꢀ (.±24ꢀ (.±±4ꢀ (.±3±ꢀ (.±3±ꢀ
Max. Min. Min.
-±.±
12mm
See
See
Note 3 Note 4
VARIABLE DIMENSIONS
Tape Size
B1
D1
F
P1
R
T2
W
A0B0K0
Max.
Min.
Min.
See Note 6
See Note 5
See Note 2
8.± +-±±..13
6
4.55
(.179ꢀ
1.±
(.±39ꢀ
3.5 ± ±.±5
(.138 ± .±±2ꢀ
5.5 ± ±.±5
(.217 ± .±±2ꢀ
4.± ± ±.1±
(.157 ± .±±4ꢀ
4.± ± ±.1±
(.157 ± .±±4ꢀ
25
(.984ꢀ
3±
(1.181ꢀ
2.5 Max
(.±98ꢀ
6.5 Max
(.256ꢀ
8mm
See Note 1
See Note 1
(.315 +.±12
-.±±4ꢀ
8.2
(.323ꢀ
1.5
(.±59ꢀ
12.± ± .3±
(.472 ± .±12ꢀ
12mm
NOTES:
3. G dimension is the flat area from the edge of the sprocket hole to either the
outward deformation of the carrier tape between the embossed cavities or to
the edge of the cavity whichever is less.
1
1.
A
0,
B
0, and K are determined by the max. dimensions to the ends of the
0
terminals extending from the component body and/or the body dimensions of
the component. The clearance between the end of the terminals or body of the
component to the sides and depth of the cavity (A0,
B
0, and K ) must be within
0
4. G dimension is the flat area from the edge of the carrier tape opposite the
sprocket holes to either the outward deformation of the carrier tape between the
embossed cavity or to the edge of the cavity whichever is less.
2
0.05 mm (.002) min. and 0.50 mm (.020) max. The clearance allowed must also
prevent rotation of the component within the cavity of not more than 20 degrees
(see sketches C & D).
5. The embossment hole location shall be measured from the sprocket hole
controlling the location of the embossment. Dimensions of embossment
location and hole location shall be applied independent of each other.
2. Tape with components shall pass around radius “R” without damage. The
minimum trailer length (Note 2 Fig. 3) may require additional length to provide R
min. for 12mm embossed tape for reels with hub diameters approaching N min.
(Table 4).
6. B dimension is a reference dimension for tape feeder clearance only.
1
88
®
Hi-Q High RF Power
MLC Surface Mount Capacitors
For 600V to 4000V Application
PRODUCT OFFERING
®
Hi-Q , high RF power, surface mount MLC capacitors from AVX
Corporation are characterized with ultra-low ESR and dissipation factor
at high frequencies. They are designed to handle high power and
high voltage levels for applications in RF power amplifiers, inductive
heating, high magnetic field environments (MRI coils), medical and
industrial electronics.
HOW TO ORDER
HQCC
A
A
271
J
A
T
1
A
AVX
Voltage Temperature Capacitance Code
Capacitance
Tolerance
F = 1ꢀ
G = 2ꢀ
J = 5ꢀ
K = 10ꢀ
M = 20ꢀ
Test
Termination
Packaging
1 = 7" Reel
3 = 13" Reel
9 = Bulk
Special
Code
A = Standard
Style
600V = C Coefficient
(2 significant digits
+ no. of zeros)
Examples:
Level
1 = Pd/Ag
HQCC 1000V = A
HQCE 1500V = S
2000V = G
C0G = A
A = Standard T = Solderable
Plate
10 pF = 100
2500V = W
100 pF = 101
1,000 pF = 102
22,000 pF = 223
3000V = H
4000V = J
DIMENSIONS
millimeters (inches)
HQCE
L
STYLE
HQCC
W
(L) Length
5.84 0.51
9.4 0.51
(0.230 0.020)
(0.370 0.020)
(W) Width
6.35 0.51
(0.250 0.020)
9.9 0.51
(0.390 0.020)
T
(T) Thickness
Max.
3.3 max.
(0.130 max.)
3.3 max.
(0.130 max.)
(t) terminal
0.64 0.38
(0.025 0.015)
0.64 0.38
(0.025 0.015)
t
DIELECTRIC PERFORMANCE CHARACTERISTICS
6
Capacitance Range
10pF to 6,800pF
(25°C, 1.0 0.2 Vrms at 1kHz, for ≤ 1000 pF use 1MHz)
1ꢀ, 2ꢀ, 5ꢀ, 10ꢀ, 20ꢀ
0.1ꢀ Max (+25°C, 1.0 0.2 Vrms at 1kHz, for ≤ 1000 pF use 1MHz)
-55°C to +125°C
C0G: 0 30 ppm/°C (-55°C to +125°C)
600, 1000, 1500, 2000, 2500, 3000, 4000VDC
100K MΩ min. @ +25°C and 500VDC
10K MΩ min. @ +125°C and 500VDC
120ꢀ of rated WVDC
Capacitance Tolerances
Dissipation Factor 25°C
Operating Temperature Range
Temperature Characteristic
Voltage Ratings
Insulation Resistance
Dielectric Strength
HIGH VOLTAGE CAPACITANCE VALUES (pF)
600
1000
WVDC
1500
WVDC
2000
WVDC
min./max.
2500
WVDC
min./max.
3000
WVDC
min./max.
4000
WVDC
min./max.
Style
WDC
min./max.
min./max.
min./max.
HQCC
HQCE
2,200 - 2,700
5,600 - 6,800
1,500 - 1,800
3,300 - 4,700
820 - 1,200
470 - 680
330 - 390
10 - 270
470-680
2,200 - 2,700
1,200 - 1,800
820 - 1,000
10-390
89
RF/Microwave
NP0 Capacitors
“U” Series
Ceramic C±G (NP±ꢀ Microwave
Multilayer Capacitors
7
9±
RF/Microwave C0G (NP0) Capacitors
Ultra Low ESR, “U” Series, C0G (NP0) Chip Capacitors
GENERAL INFORMATION
are met on each value producing lot to lot uniformity.
Sizes available are EIA chip sizes 0603, 0805, and 1210.
“U” Series capacitors are C0G (NP0) chip capacitors spe-
cially designed for “Ultra” low ESR for applications in the
communications market. Max ESR and effective capacitance
DIMENSIONS: inches (millimeters)
0402
0603
0805
1210
A
A
E
A
A
E
C
B
B
C
B
B
C
C
D
D
D
D
D
D
E
inches (mm)
Size
0402
0603
0805
1210
A
B
C
D
N/A
E
N/A
0.039 0.004 (1.00 0.1)
0.060 0.010 (1.52 0.25) 0.030 0.010 (0.ꢀ6 0.25)
0.0ꢀ9 0.008 (2.01 0.2)
0.126 0.008 (3.2 0.2)
0.020 0.004 (0.50 0.1)
0.024 (0.6) max
0.036 (0.91) max
0.010 0.005 (0.25 0.13)
0.030 (0.ꢀ6) min
0.020 (0.51) min
0.049 0.008 (1.25 0.2)
0.098 0.008 (2.49 0.2)
0.040 0.005 (1.02 0.12ꢀ) 0.020 0.010 (0.51 0.254)
0.050 0.005 (1.2ꢀ 0.12ꢀ) 0.025 0.015 (0.635 0.381) 0.040 (1.02) min
HOW TO ORDER
0805
1
U
100
J
A
T
2
A
Case Size
0402
Dielectric =
Ultra Low
ESR
Capacitance
Tolerance
Code
Termination
T= Plated Ni
and Tin
Special
Code
A = Standard
0603
0805
1210
B = 0.1pF
C = 0.25pF
D = 0.5pF
F = 1%
G = 2%
J = 5%
K = 10%
M = 20%
Voltage
Code
3 = 25V
5 = 50V
1 = 100V
2 = 200V
Failure Rate
Code
Packaging
Code
2 = ꢀ" Reel
4 = 13" Reel
9 = Bulk
A = Not
Capacitance
Applicable
EIA Capacitance Code in pF.
First two digits = significant figures
or “R” for decimal place.
Third digit = number of zeros or
after “R” significant figures.
ELECTRICAL CHARACTERISTICS
Dielectric Working Voltage (DWV):
7
Capacitance Values and Tolerances:
Size 0402 - 0.2 pF to 22 pF @ 1 MHz
Size 0603 - 1.0 pF to 100 pF @ 1 MHz
Size 0805 - 1.6 pF to 160 pF @ 1 MHz
Size 1210 - 2.4 pF to 1000 pF @ 1 MHz
250% of rated WVDC
Equivalent Series Resistance Typical (ESR):
0402 - See Performance Curve, page 92
0603 - See Performance Curve, page 92
0805 - See Performance Curve, page 92
1210 - See Performance Curve, page 92
Temperature Coefficient of Capacitance (TC):
0 30 ppm/ꢁC (-55ꢁ to +125ꢁC)
Marking: Laser marking EIA J marking standard
(except 0603) (capacitance code and
tolerance upon request).
Insulation Resistance (IR):
1012 Ω min. @ 25ꢁC and rated WVDC
1011 Ω min. @ 125ꢁC and rated WVDC
Working Voltage (WVDC):
MILITARY SPECIFICATIONS
Size
Working Voltage
Meets or exceeds the requirements of MIL-C-55681
0402 - 50, 25 WVDC
0603 - 200, 100, 50 WVDC
0805 - 200, 100 WVDC
1210 - 200, 100 WVDC
91
RF/Microwave C0G (NP0) Capacitors
Ultra Low ESR, “U” Series, C0G (NP0) Chip Capacitors
CAPACITANCE RANGE
Size
Cap (pF) Tolerance 0402 0603 0805 1210
Size
Cap (pF) Tolerance 0402 0603 0805 1210
Size
Size
Cap (pF) Tolerance 0402 0603 0805 1210
Available
Available
Available
Available
Cap (pF) Tolerance 0402 0603 0805 1210
7.5
8.2
9.1
10
11
12
13
15
18
20
22
24
27
30
33
36
39
43
47
51
56
68
75
82
91
B,C,J,K,M 50V 200V 200V 200V
100
110
120
130
140
150
160
180
200
220
270
300
330
360
390
430
470
510
560
620
680
750
820
910
F,G,J,K,M N/A 100V 200V 200V
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
B,C
50V N/A N/A N/A
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
B,C,D
50V 200V 200V 200V
ꢀ
ꢀ
ꢀ
50V
ꢀ
ꢀ
ꢀ
B,C,J,K,M
F,G,J,K,M
200V
B,C
ꢀ
100V
B,C,D
ꢀ
ꢀ
50V
ꢀ
ꢀ
N/A 100V
N/A
ꢀ
ꢀ
ꢀ
ꢀ
B,C,D
ꢀ
100
ꢀ
50V
N/A
ꢀ
100
ꢀ
ꢀ
ꢀ
B,C,D
B,C,J,K,M
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
F,G,J,K,M
1000 F,G,J,K,M
ULTRA LOW ESR, “U” SERIES
TYPICAL ESR vs. FREQUENCY
0402 “U” SERIES
TYPICAL ESR vs. FREQUENCY
0603 “U” SERIES
1
1
10 pF
15 pF
3.3 pF
3.9 pF
4.7 pF
5.1 pF
6.8 pF
10.0 pF
15.0 pF
0.1
0.1
0.01
0.01
2500
2500
0
0
500
1000
Frequency (MHz)
2000
500
1000
Frequency (MHz)
2000
1500
1500
TYPICAL ESR vs. FREQUENCY
1210 “U” SERIES
TYPICAL ESR vs. FREQUENCY
0805 “U” SERIES
7
1
1
100 pF
10.0 pF
10 pF
100 pF
0.1
0.1
300 pF
0.01
0.01
2500
0
0
500
1000
2000
500
1000
Frequency (MHz)
2000
1500
1500
Frequency (MHz)
ESR Measured on the Boonton 34A
92
RF/Microwave C0G (NP0) Capacitors
Ultra Low ESR, “U” Series, C0G (NP0) Chip Capacitors
7
F r e q u e n c y ( G H z )
93
RF/Microwave
AQ 12 & 14 and “U” Series
Designer Kits
8
94
Designer Kits
Tuning Kits: AQ12/AQ14 Series
TUNING KITS
Solder Plated, Nickel Barrier
Porcelain (+90)
Ceramic (NP0)
AQ12
Kit 1500 UZ
AQ14
Kit 2500 UZ
AQ12
Kit 1501 UZ
AQ14
Kit 2501 UZ
Capacitor
Value pF
Capacitor
Value pF
Capacitor
Value pF
Capacitor
Value pF
Tolerance*
Tolerance*
Tolerance*
Tolerance*
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
10.0
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
10.0
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
10.0
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.4
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
10.0
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
38± Capacitors 1± each of 38 values. All chips are laser marked.
*Tolerance: B =±±.1pF, C =±±.25pF, J =±5ꢁ.
8
95
Designer Kits
Evaluation Kits: AQ12/AQ14 Series
EVALUATION KITS
Solder Plated, Nickel Barrier
Porcelain (+90)
Ceramic (NP0)
AQ12
AQ14
AQ12
AQ14
Kit 1000 UZ
Kit 2000 UZ
Kit 1001 UZ
Kit 2001 UZ
Capacitor
Capacitor
Capacitor
Capacitor
Value pF
Tolerance*
Value pF
Tolerance*
Value pF
Tolerance*
Value pF
Tolerance*
.5
B
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
1.0
B
B
B
B
B
B
C
C
C
C
C
C
C
C
C
C
C
J
.5
B
B
B
B
B
B
C
C
C
C
C
C
C
C
J
1.0
B
B
B
B
B
C
C
C
C
C
C
C
C
C
C
C
J
1.0
1.2
1.0
1.5
1.2
1.5
1.5
1.8
1.5
1.8
1.8
2.0
1.8
2.0
2.0
2.2
2.0
2.2
2.2
2.4
2.2
2.4
2.4
2.7
2.4
2.7
2.7
3.0
2.7
3.0
3.0
3.3
3.0
3.3
3.3
3.6
3.3
3.6
3.6
3.9
3.6
3.9
3.9
4.3
3.9
4.3
4.3
4.7
4.3
4.7
4.7
5.1
4.7
5.1
6.8
5.6
6.8
5.6
8.2
J
6.2
8.2
J
6.2
10.0
12.0
15.0
22.0
27.0
33.0
39.0
47.0
56.0
68.0
82.0
100.0
470.0
1000.0
J
6.8
10.0
12.0
15.0
18.0
22.0
27.0
33.0
39.0
47.0
56.0
68.0
82.0
100.0
J
6.8
J
8.2
J
J
8.2
J
J
10.0
12.0
15.0
22.0
27.0
33.0
39.0
47.0
56.0
68.0
82.0
100.0
120.0
150.0
180.0
220.0
240.0
270.0
330.0
390.0
470.0
560.0
680.0
820.0
1000.0
2700.0
5100.0
J
J
10.0
12.0
15.0
18.0
22.0
27.0
33.0
39.0
47.0
56.0
68.0
82.0
100.0
120.0
150.0
180.0
220.0
240.0
270.0
330.0
390.0
470.0
560.0
680.0
820.0
1000.0
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
J
3±± Capacitors 1± each of 3± values.
All chips are laser marked.
3±± Capacitors 1± each of 3± values.
All chips are laser marked.
J
J
J
J
*Tolerance: B = ±±.1 pF, C = ±±.25
pF, J = ±5ꢁ.
*Tolerance: B = ±±.1 pF, C = ±±.25
pF, J = ±5ꢁ.
J
J
J
J
J
K
K
K
K
K
K
K
K
K
K
J
K
K
K
K
K
K
K
K
45± Capacitors 1± each of 45 values.
All chips are laser marked.
45± Capacitors 1± each of 45 values.
All chips are laser marked.
*Tolerance: B = ±±.1 pF, C = ±±.25
pF, J = ±5ꢁ, K = ±1±ꢁ
*Tolerance: B = ±±.1 pF, C = ±±.25
pF, J = ±5ꢁ, K = ±1±ꢁ
NOTE: Order by Kit Number
Example: Kit 1±±± UZ
8
96
Designer Kits
Communication Kits “U” Series
“U” SERIES KITS
Solder Plated, Nickel Barrier
0402
0603
Kit 5000 UZ*
Kit 4000 UZ**
Cap.
Value
pF
Cap.
Tol.† Value
pF
Cap.
Value
pF
Cap.
Tol.† Value
pF
Tol.†
Tol.†
0.5
1.0
1.5
1.8
2.2
2.4
3.0
3.6
B
B
B
B
B
B
B
B
4.7
5.6
6.8
B
B
B
B
J
J
J
1.0
1.2
1.5
1.8
2.0
2.4
2.7
3.0
3.3
3.9
4.7
5.6
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
.25pF
6.8
7.5
8.2
.25pF
.25pF
.25pF
5ꢀ
5ꢀ
5ꢀ
5ꢀ
5ꢀ
5ꢀ
5ꢀ
8.2
10.0
12.0
15.0
18.0
22.0
27.0
33.0
39.0
47.0
10.0
12.0
15.0
* 150 Capacitors 10 each of 15 values.
5ꢀ
5ꢀ
** 240 Capacitors 10 each of 24 values.
0805
1210
Kit 3000 UZ***
Kit 3500 UZ***
Cap.
Value
pF
Cap.
Tol.† Value
pF
Cap.
Value
pF
Cap.
Value
pF
Cap.
Tol.† Value
pF
Cap.
Value
pF
Tol.†
Tol.†
Tol.†
Tol.†
1.0
1.5
2.2
2.4
2.7
3.0
3.3
3.9
4.7
5.6
C
C
C
C
C
C
C
C
C
C
7.5
8.2
9.1
10.0
12.0
15.0
18.0
22.0
24.0
27.0
C
C
C
J
J
J
J
J
J
J
33
36
39
47
56
68
82
100
130
160
J
J
J
J
J
J
J
J
J
J
2.2
2.7
4.7
5.1
6.8
8.2
9.1
10
C
C
C
C
C
C
C
J
18
20
24
27
30
36
39
47
51
56
J
J
J
J
J
J
J
J
J
J
68
82
J
J
J
J
J
J
J
J
J
J
100
120
130
240
300
390
470
680
13
15
J
J
*** 300 Capacitors 10 each of 30 values.
†Tolerance – B = 0.1pꢀ
C = 0.25pꢀ
J = 5ꢁ
8
97
Introduction
to
Microwave Capacitors
9
98
Introduction to
Microwave Capacitors
Microwave Capacitors in MICs
The top side of the capacitor should be completely metal-
lized so that the bond wire from the FET to the edge of the
capacitor is minimized.
Typical Microwave Circuit Applications
Microwave MLC, SLC, or Thin-Film capacitor applications in
MIC circuits can be grouped into the following categories:
The height of the capacitor must be less than or equal to the
height of the FET, usually about 0.005 inches. If the capaci-
tor is higher than the FET, the capacitor will interfere with the
bonding tool when wire bonding to the FET.
• DC Block (in series with an MIC transmission line)
• RF Bypass (in shunt with transmission lines)
• Source Bypass (in shunt with active device)
• Impedance Matching
Impedance Matching
The impedance matching application is to use the chip
capacitor to provide the required reactance at a specific
point in the circuit.
This chapter discusses these applications and the perfor-
mance parameters of microwave capacitors affecting these
applications.
This is usually the most critical application in terms of the
capacitor maintaining a tight tolerance over temperature and
from unit-to-unit.
DC Block
In the DC block application, the chip capacitor is placed in
series with the transmission line to prevent the DC voltage
from one circuit from affecting another circuit.
The other applications only require that the capacitance for
the DC block and RF bypass maintains a low reactance and
the tolerance can be as much as 50ꢀ. Whereas the imped-
ance matching function often requires 1ꢀ tolerance.
The capacitance is chosen so that the reactance is only a
fraction of an ohm at the lowest microwave frequency of
interest.
In general, microwave capacitors should have the following
properties:
The largest value capacitor is used as long as the self-resonant
frequency is still much higher than the highest frequency of
interest.
• Low-loss
• Operate very much below the self-resonant frequency
RF Bypass
• The power handling capability should be commensurate
with the expected power performance of the circuit
The RF bypass application is used to effectively short out the
RF to ground. The capacitor value is also picked to be as
large as possible without approaching the self-resonance of
the capacitor.
• Capable of wire bonding and gap welding
• Low variation of capacitance over temperature
• Low unit-to-unit variations in capacitance
• Low dimensional variations from unit-to-unit
Typical SLC applications in MIC circuits are shown in:
Source Bypass
The source bypass application is the same as the RF bypass
except the capacitor is used in conjunction with an active
device.
In this application the chip capacitor is butted up to the
source of the microwave FET device mounted on the MIC
circuit. This is done to minimize the length of the wire bond
from the source of the FET to the capacitor. The shorter the
wire bond, the lower the corresponding inductance.
RF
IN
R
C
C
D
D
SIMPLIFIED RF SPECTRUM
5±± MHz
DISTRIBUTED NET
LUMPED NET
C
6± cm
3 GHz
WAVEGUIDE
SYSTEMS
COAXIAL
SYSTEMS
D
C
C
R
D
RF
OUT
R
1± cm
D
MF. HF
VHF
UHF
SHF. EHF
BIAS
Figure 2. Typical MIC Microwave Attenuator Hybrid with SLC’s.
“C” indicates SLC locations.
3± MHz
1± m
3 MHz
1±± m
AM
3±± MHz
1 m
3±± KHz
1 km
3 GHz
1± cm
3± GHz
1 cm
9
FM
SATELLITE
(COMMERCIALꢀ
BROADCAST
BROADCAST
Figure 1
99
Introduction to
Microwave Capacitors
Microwave Parameters
Scattering Parameters
return loss can be related to the reflection coefficient and
VSWR:
Generally, transmission and reflections coefficient measure-
ments completely characterize any black box or network.
Transmission and reflections parameters — attenuation
(gain), phase shift, and complex impedance — can be
described in terms of a set of linear parameters called
“scattering” or “s” parameters. Knowing these characteristic
parameters, one can predict the response of cascaded
or parallel networks accurately. Unlike y or h parameters
which require short circuit and open circuit terminations, “s”
parameters are determined with the input and output ports
terminated in the characteristic impedance of the transmis-
sion line which is a much more practical condition to obtain
at RF and microwave frequencies.
Eq. 2. RL (dB) = 10 log (Pinc/Pref)
*
= 20 log (Einc/Eref) = 20 log (1/Rho)
*
*
Eq. 3. Rho = (VSWR - 1)/(VSWR + 1)
Eq. 4. VSWR = (1 + Rho)/(1 - Rho)
where Rho = reflection coefficient
RL = return loss
Pinc = power incident
Pref = power reflected
Einc = voltage incident
Eref = voltage reflected
VSWR = voltage standing wave ratio
To summarize, “s” parameters are more useful at microwave
frequencies because:
By the above equation, when the reflection coefficient is 1,
the return loss is zero. In this case, no signal is lost and all
the signal incident upon the discontinuity was returned to the
source. As the reflection coefficient approaches zero, the
return loss approaches infinity. That is, the more perfect the
load, the less the reflection from that load.
1. Equipment to measure total voltage and total currents
at the ports of the networks is not readily available.
2. Short and open circuits are difficult to achieve over a
broad band of frequencies because of lead inductance
and capacitance. Furthermore, these measurements
typically require tuning stubs separately adjusted at
each frequency to reflect short and open circuits to the
device terminals, and this makes the process inconve-
nient and tedious.
The return loss can be improved by an attenuator.
Assume that we connect a perfectly matched 3 dB attenua-
tor into a short circuit as shown in Figure 3.
PINC
3. Active devices such as transistors and negative resis-
tance diodes are very often not short- or open-circuit
stable.
SHORT CIRCUIT
PREF
3 dB ATTEN
There are four scattering parameters for a two-port network:
S11, S12, S21, and S22.
PREF
____
PINC
= -6 dB
S11 is the reflection coefficient at the input port with the
output port terminated in a 50 ohm load.
Figure 3
The indicated 100 mw is decreased to 50 mw at the output
of the 3 dB attenuator. This 50 mw is reflected from the short
circuit back through the attenuator in the reverse direction
and one-half of this reflected power is lost in the 3 dB atten-
uator. The reflected power at the input is 25 mw. Notice the
return loss is equal to twice the attenuation because it is the
“round trip” loss. This example shows that VSWR is
decreased when attenuation exists on a transmission line
and also that a high VSWR can be decreased by placing an
attenuator in the line.
S12 is the reverse transmission coefficient in a 50 ohm
system.
S21 is the forward transmission coefficient in a 50 ohm
system.
S22 is the reflection coefficient at the output port with the
input port terminated into a 50 ohm load.
The reflection coefficients can be directly related to the
impedance of the device by the equation:
Eq.1. ZIN/ZO = (1 + S11)/(1 - S11)
where ZIN= input impedance
ZO = characteristic impedance of
the transmission line
Mismatch Loss
Mismatch loss is a measure of power loss caused by reflec-
tion. It is the ratio of incident power to the difference between
incident and reflected power and is expressed in dBs as
follows:
This equation also defines the Smith Chart.
Return Loss
Eq. 5. Mismatch loss (dB) = 10 log
*
Return loss is the ratio of the incident power to the reflected
power at a point on the transmission line and is expressed in
decibels. The reflected power from a discontinuity is
expressed as a certain number of decibels below the inci-
dent power upon the discontinuity. It can be shown that
[Pinc/(Pinc - Pref)]
= 10 log
*
[1/(1-Rho = 2)]
9
1±±
Introduction to
Microwave Capacitors
Microwave Parameters
(1)
(2)
(3)
(4)
(5)
(6)
(7)
N
GPC-7
SMA
SMA
GPC-7
GPC-7
SWR
AUTOTESTING
SWEEP
GENERATOR
GPC-7
TO SMA
GPC-7
TO SMA
DUT
DET
ATTEN
(8)
SCALAR
ANALYZER
TRANSMISSION
REFLECTION
(1ꢀ Wiltron 6647A 1±MHz - 18GHz sweepers
(2ꢀ Wiltron 56±-97-A5±
Test set-up for:
______________
(3ꢀ OSM 2±82-27±±-±±
(4ꢀ Device under test
(1ꢀ Insertion loss
(2ꢀ VSWR
(5ꢀ OSM 2±82-27±±-±±
(6ꢀ OSM 7±82-6193-1±
(7ꢀ Wiltron 56±-7A5±
Figure 4
The mismatch loss for various values of VSWR is tabulated
as follows:
mismatch losses due to the two VSWRs to a small fraction
of the expected insertion loss of the DUT.
In using the scalar network analyzer it is a temptation to nor-
malize the amplitude response regardless what the actual
response is during calibration. It is advisable to eliminate the
amplitude ripple first before normalizing the scalar analyzer.
One way is to make use of the fact that VSWRs can be
improved by the use of matched attenuators. Often, 10 dB
attenuators are placed before and after the DUT to provide a
minimum of 20 dB return loss which corresponds to source
and load VSWRs of less than 1.20:1. This will reduce the
uncertainties due to mismatch losses to less than 0.02 dB.
Table I
VSWR
1.00
1.20
1.40
1.50
1.70
2.00
2.50
3.00
Mismatch Loss
0.00 dB
0.04 dB
0.12 dB
0.18 dB
0.30 dB
0.51 dB
0.88 dB
1.25 dB
Return Loss Measurement
Insertion Loss Measurement
The return loss is measured by the following method: The
test port is terminated by a short circuit so that all the inci-
dent power is reflected. A detector on the bridge measures
this power and this power is used as the reference for the
incident power. The test port is then terminated by the DUT
and the reflected power now measured. The difference
between the power levels is the return loss.
Insertion loss is measured by the substitution method. The
insertion loss of the measurement system is used as a refer-
ence. Then the DUT (Device Under Test) is inserted into the
setup and the new insertion loss is measured. The difference
between the two losses is the insertion loss of the DUT.
The insertion loss is measured using the test setup as shown
in Figure 5.
SWR BRIDGE
In order to accurately measure the insertion loss, source
VSWR and load VSWR must be extremely Iow. It is assumed
during calibration (loss of the measurement system with
the DUT removed from the test setup) that the VSWR of the
generator and the load does not contribute any mismatch
losses. As discussed in the section on mismatch loss, any
VSWR above 1.2:1 may cause a minimum error of 0.04 dB.
In addition, the two VSWRs may be additive or subtractive
depending on the phasing of the reflections. For example,
source and load VSWRs of 1.2:1 can add to create an error
of 0.08 dB. The mismatches usually exhibit themselves as
amplitude ripple as a function of frequency. It is important
when measuring low insertion losses that precautions are
taken to ensure low source and load VSWRs and to keep the
INCIDENT
POWER
DETECTOR
9
Figure 5. Return Loss Measurement:
Establishing a Reference
1±1
Introduction to
Microwave Capacitors
Microwave Parameters
Note that the insertion loss and return loss can be measured
simultaneously by using the dual trace feature of the Wiltron
Scalar Analyzer. Furthermore, the two measurements can be
done by using a controller such as the HP85 computer for
semi-automatic testing.
SWR BRIDGE
INCIDENT
INPUT
5± OHM
TERMINATION
DUT
REFLECTED
The calibration for 0 dB return loss can be improved by aver-
aging the short circuit and open circuit reflected powers.
Since the phase difference is 180 degrees, the average
closely approximates the actual full reflection.
DETECTOR
Decibels
DUT IN PLACE
The decibel, abbreviated “dB,” is one-tenth of the interna-
tional transmission unit known as the “bel.” The origin of the
bel is the logarithm to the base 10 of the power ratio. It is
the power to which the number 10 must be raised in order
to equal the given number. The number 10 is raised to the
second power, or squared, in order to get 100. Therefore,
the log of 100 is 2.
Figure 6
• All incident power is reflected at the short circuit.
• The detector measures the reflected power.
• An SWR bridge usually has a directivity of 35 to 40 dB.
In other words, only a minute fraction of the incident power
reaches the detector (the dotted line path) that is not
reflected off the short circuit.
The decibel is expressed mathematically by the equation:
Eq. 6 dB = 10 * log (P /P )
1
2
• The DUT is substituted for the short circuit and the oppo-
site port is terminated by a matched termination (50 ohms).
P2 = larger power
P1 = lower power
• The reflected power depends on the DUT and is sensed by
the detector.
The use of log tables can be avoided in practical applications
where exact values of the power are not required. One only
needs to know that a factor of 2 is equal to 3 dB and a fac-
tor of 10 is equal to 10 dB and the rest of the conversions
are derived from these two relationships. The use of dBs
reduces multiplication into an addition. For example:
• The return loss is the difference between this reflected
power and that measured with a reference short circuit.
• A significant improvement in calibrating a 0 dB return loss
reference by averaging the short circuit and open circuit
reflected powers.
3dB =
6dB = 2 x 2
2
4
=
• The dotted line in the figure below shows the reflections
due to an open circuit.
9dB = 2 x 2 x 2 =
10dB =
20dB =
8
10
100
• The solid line in the figure below shows the reflections due
to a short circuit.
The technique is based on the fact that 3, 6, and/or 9 dB
can be added or subtracted (in some combination) to any
decibel value. Adding or subtracting 10 to a decibel value
simply multiplies or divides the number by ten. Examples:
• Since the phase difference between short circuit and open
circuit is 180 degrees.
• By taking the average between these two voltages, the
actual full reflection is very closely approximated.
1. 17dB = 20dB - 3dB
20dB is 10dB + 10dB or is equal to 100.
3dB is equal to 2
AVERAGING THE SHORT CIRCUIT AND OPEN CIRCUIT
REFERENCES FOR HIGHER ACCURACY
Therefore, 20 dB - 3dB = 100/2 = 50
1
A
B
C
B
2. 36dB = 30dB + 6dB
1000 x 4 = 4000
SHORT
1
C
OPEN
±
1
A
Decibel:
E
The decibel is not a unit of power but merely is a logarithmic
expression of a ratio of two numbers. The unit of power may
be expressed in terms of dBm, where “m” is the unit, mean-
ing above or below one milliwatt. Since one mw is neither
above nor below 1 mw, 1 mw= 0 dBm.
ACTUAL
FULL
REFLECTION
f
1
f
2
PREFERRED REFLECTION CALIBRATION
Nepers:
Figure 7
An alternate unit called the neper is defined in terms of the
logarithm to the base “e.” e = 2.718.
9
1 neper = 8.686dB
1dB = 0.1151 neper
1±2
Introduction to
Microwave Capacitors
Electrical Model
Figures 9 and 10 also show the point of series resonance (LS
in series with C), and parallel resonance (LS in parallel with
Capacitance
Microwave chip capacitors, although closely approx-
imating an ideal capacitor, nonetheless also contain
parasitic elements that are important at microwave fre-
quencies. The equivalent circuit is shown below:
CP).
RS ꢀ QP2
INDUCTIVE
ꢁLS
C
RS
LS
RS
ꢁP
Z (ꢁꢀ
ꢁS
RS
1
ꢁC
___
1
ꢁCP
___
CP
CAPACITIVE
Figure 8. Equivalent Circuit of a
Microwave Capacitor
RS ꢀ QP2
where, C = desired capacitance
LS = parasitic series inductance
RS = series resistance
Figure 9. SLC Impedance Magnitude vs. Frequency
SERIES RESONANCE
j5±
j1±±
j25
j15±
CP = parasitic parallel capacitance,
j1±
j25±
Rp, the parallel resistance is not shown as it is of concern
only at dc and low frequencies.
PARALLEL
RESONANCE
25
1±
5±
1±± 15± 25± 5±±
±
The primary capacitance, C, is typically determined by mea-
surement at 1 MHz where the effects of Rs, Ls, and Cp
become negligible compared to the reactance of C. The
value of C determined at this low frequency is also valid
at microwave frequencies when the dielectric constant has
a very low variation versus frequency, as is typical in the
modern dielectrics employed in microwave capacitors.
-j1±
-j25±
-j15±
-j1±±
-j25
-j5±
COORDINATES IN OHMS
FREQUENCY IN GHz
The equivalent impedance of the capacitor at any frequency is:
Figure 10. SLC Impedance on Smith Chart
1
1
Eq. 7. Zs =
Because there is always some parasitic inductance associat-
ed with capacitors, there will be a frequency at which the
inductive reactance will equal that of the capacitor. This is
known as the series resonant frequency (SRF). At the SRF,
the capacitor will appear as a small resistor (RS). The trans-
mission loss through a series mounted capacitor at its series
resonant frequency will be low.
sCp +
1/s
Cs
Rs + sLs +
where s = j2ꢀf, f = frequency
Series and Parallel Resonance
At frequencies above the SRF, the capacitor begins to act
like an inductor.
Ideally, the impedance magnitude of a series mounted
capacitor will vary monotonically from infinite at dc to zero at
infinite frequency. However, the parasitics associated with
any capacitor result in a nonideal response.
When used as a DC block, the capacitor will begin to exhib-
it gradually higher insertion loss above the SRF. In other
words, the capacitor will cause a high frequency rolloff of its
transmission amplitude response.
Figure 9 shows the magnitude, :Z (F):, as a function of
frequency.
When used as an RF bypass, as for the source of an FET, the
inductance will cause the FET to become unstable which can
cause oscillations or undesirable effects on the gain
response of the FET amplifier.
Figure 10 shows Z(f) on the Smith Chart, which includes
magnitude and phase.
Eq. 8. In general, an impedance is represented by Z=R + j X.
The Smith Chart maps the entire impedance half plane for
R > 0 into the interior of a unit circle. The Smith Chart is a
mapping of the reflection coefficient, S11, of an impedance.
S11 = (Z- ZO) / (Z + ZO). ZO is a reference impedance, typ-
ically 50 ohms, and is in the center of the chart. The central
horizontal axis is for X = O, with R < 50 to the left of center,
and R > 50 to the right of center.
Beyond the SRF, there is a frequency called the parallel
resonant frequency (PRF). This occurs when the reactance of
the series inductor equals that of the parallel capacitor.
9
1±3
Introduction to
Microwave Capacitors
Electrical Model
At this parallel resonant frequency, the capacitor will appear
as a large resister whose value is RPRF defined as:
Equivalent Series Resistance
The equivalent series resistance is the RS in the electrical
model. At the SRF, the ESR can be readily determined on the
Smith Chart display of the capacitor’s impedance. However,
the ESR is not necessarily constant with frequency and its
value is typically determined by an insertion loss measure-
ment of the capacitor at the desired frequency.
Eq. 9. RPRF = Rs x Q
P
X QP; where,
QP = 1/R
S
WP/CP
WP = 2ꢀfPRF
The parasitic parallel capacitance is usually very small which
results in a parallel resonant frequency that is much higher
than the series resonance.
The insertion loss is a combination of reflective and absorp-
tive components. The absorptive component is the part
associated with the value of the ESR (i.e., the loss in RS).
Because of the low values of ESR in microwave capacitors
(on the order of 0.01 ohm), the insertion loss measurement
is very difficult to make, but can be made with a test fixture
similar to that shown in Figure 11, but with the input and out-
put 50 ohm impedances transformed down to some more
convenient impedance level, Rref, to obtain a more accurate
measurement.
For capacitor usage in RF impedance matching and tuning
applications, the maximum practical frequency for use is up
to 0.5 times the SRF.
For DC filtering and RF shorting applications, best perfor-
mance is obtained near the SRF.
At frequencies above the SRF, but below the PRF, the SLC
can be used as a low loss inductor with a built-in DC block
for bypassing and decoupling.
The series resonant frequency (SRF) of an SLC can be
measured by mounting the capacitor in series on a 50 ohm
transmission line as shown in Figure 11.
When used as a DC block in the transmission line test fixture,
the forward transmission coefficient, S21, and the input
reflection coefficient, S11, can be measured to determine:
CHIP CAPACITOR
Eq. 10. Dissipative Loss.
DL=(1-:S11:^2)/(:S21:^2)
Eq. 11. Reflection Loss.
RL=(1-:S11:^2) where S11 and S21 are expressed
as complex phasors.
From the dissipative loss, DL, the ESR can be determined
as:
5± ohm
LINE
5± ohm
LINE
Eq. 12. ESR = Rref * [1 - SQRT(DL)]/[1 + SQRT(DL)]
The ESR typically increases with operating temperature and
self-heating under high power. This increase can be seen
directly in the lab by measuring the insertion loss of the
capacitor as a function of temperature.
A low ESR is especially necessary in SLC’s when used in
series with transistors in low noise amplifiers, high gain
amplifiers, or high power amplifiers. For example, an ESR of
1 ohm in series with a base input impedance of 1 ohm would
result in a serious compromise in ampIifier gain and noise
figure by up to 3 dB.
Figure 11
At its series resonant frequency (SRF), the SLC will appear as
a small resistance. This measurement can be performed with
a vector network analyzer such as the Hewlett Packard
8510. The SRF is at the frequency for which the phase of the
input reflection coefficient, S11, is crossing the real axis on
the Smith Chart at 180 degrees.
Power Rating
The RF power rating of chip capacitors is dependent on:
The resonant frequency will be lowered by the inductance
associated with the bonding attachment to the capacitor
(i.e., bonding wires, ribbons, leads, etc.). The actual resonant
frequency of the capacitor by itself can be determined by
taking out the effects of the bonding attachment inductance.
Using the low frequency measurements of the primary
capacitance alone, the inductance of the capacitor can be
derived from the resonant frequency. With AVX SLC’s, the
inductance is low enough so that the practical operating fre-
quencies achieved can be beyond 20 GHz.
• Thermal Breakdown
• Voltage Breakdown
Thermal Breakdown
Thermal breakdown is self-heating caused by RF power dis-
sipated in the capacitor.
If the resultant heat generated is greater than what can be
conducted away through the leads or other means of heat
sinking, the capacitor temperature will rise.
9
1±4
Introduction to
Microwave Capacitors
Electrical Model
As the capacitor temperature increases, the dissipation fac-
tor and ESR of the capacitor also increase which creates a
thermal runaway situation.
Dielectric Constant Measurement at
Microwave Frequencies
The measurement of dielectric constants at low frequencies
is easily done by measuring the capacitance of a substrate
of known dimensions and calculating the dielectric constant.
The small signal insertion loss is used to determine the per-
centage of power which is dissipated in the capacitor.
For instance, if the insertion loss is:
The resonance method is used in measuring dielectric
constants at microwave frequencies of metallized ceramic
substrates. This is based on the model of the high dielectric
constant substrate as a parallel plate dielectrically loaded
waveguide resonator. By observing the resonant frequencies
and knowing the dimensions of the substrate, the dielectric
constant is calculated by fitting the resonances into a table
of expected fundamental and higher order modes. This
method can be measured by connecting the corners of the
substrates to the center conductors of either an APC-7 or
Type N connector. The test setup is the same as for insertion
loss measurements. This method as described in the litera-
ture for an alumina substrate with a dielectric constant of
approximately 10 and a substrate height of 0.025 inches can
be measured to an accuracy of 2ꢀ. The Napoli-Hughes
Method uses an open circuit assumption for the unmetallized
edges which can be radiative. This inaccuracy is reduced if
thinner substrates or if higher dielectric constant substrates
are used which will tend to reduce radiation. Higher accuracy
can be achieved by metallizing all six sides of the substrate
except for the corners where the RF is coupled to the sub-
strate. This method as reported by Howell provided more
consistent results.
0.01 dB then .2ꢀ of the incident power is lost as heat
0.10 dB then 2ꢀ of the incident power is lost as heat
1.00 dB then 20ꢀ of the incident power is lost as heat
The capacitor will heat up according to the amount of power
dissipated in the capacitor and the heat sinking provided.
Even very low ESR, 0.01 ohm at 1 GHz, can be significant
when passing power through a series mounted capacitor
into a typically low impedance bipolar transistor base input
with an input impedance of only 1 ohm. If 1ꢀ of 10 watts is
dissipated in the capacitor, this 100 milliwatt of power causes
a very large increase in the capacitor temperature dependent
on its heat sinking in the MIC circuit.
Voltage Breakdown
The voltage breakdown also limits the maximum power
handling capability of the capacitor.
The voltage breakdown properties of the capacitors is
dependent on the following:
• dielectric material
• voids in the material
• form factor
• separation of the electrodes
Most microwave capacitors have a DC voltage rating of 50
VDC. This is much greater than typical DC voltages of 3 to
15 volts present on an MIC circuit.
m = 2
2L
W
___
f±
2f±
f±
m = 1
L
W
___
f±
FROM
AUTO
TESTER
SCALAR
ANALYZER
SWEEP
DETECTOR
GENERATOR
4
n = 1
2
3
Figure 13
Test Configuration for Resonance Measurements
Figure 12
9
Dispersion Curve of a Rectangular Resonator
1±5
Introduction to
Microwave Capacitors
Transmission Lines
Propagation Constant and
Characteristic Impedance
Standing Waves
Standing waves on the lossless transmission line:
The incident waves of voltage and current decrease in mag-
nitude and vary in phase as one goes toward the receiving
end of the transmission line which has losses. The propaga-
tion constant is a measure of the phase shift and attenuation
along the line.
An incident wave will not be reflected if the transmission line
is terminated in either matched load or if the transmission line
is infinitely long. Otherwise, reflected waves will be present.
In other words, any impedance will cause reflections.
Let us consider the case of a lossless transmission line ter-
minated in a short line. In this case all of the incident wave
will be reflected. See Figure 15.
• attenuation per unit length of line is called the attenuation
constant. (dB or nepers per unit length)
• phase constant, phase shift per unit length. (radians per
unit length)
The dotted sine wave to the right of the short circuit in the
diagram indicates the position and distance the wave would
have traveled in the absence of the short circuit. With the
short circuit placed at X, the wave travels the same distance
back toward the generator. In order to satisfy the boundary
conditions, the voltage at the short circuit must be zero at all
times. This is accomplished by a reflected wave which is
equal in magnitude and reversed in polarity (shown by the
superimposed reflected wave and the resultant total voltage
on the line). Note that the total voltage is twice the amplitude
of the incident voltage at a quarter wavelength back toward
the generator and the total voltage is zero at one-half wave-
length from the short.
• angular frequency, 2 * pi * f
(R+jwL) - complex series impedance per unit length of line.
(G+jwC) - complex shunt admittance per unit length of line.
L
Eq. 13. Z± for lossless case: Z± =
ꢀ ⁄
C
ꢀ
WAVE
CIRCUIT
X
D
E
1
2E
1
1
1
3
2
E
i
3
1
2
±
DISTRIBUTED PARAMETER MODEL
OF A SECTION OF TRANSMISSION LINES:
RESULTANT
(aꢀ
SHORT
E
1
rꢂx
lꢂx
3
5
6
2
gꢂx
cꢂx
4
2
1
1
4
3
1
E
r
(bꢀ
RESULTANT
SHORT
ꢂx
where
G = Conductance per unit length
R = Resistance per unit length
C = Capacitance per unit length
L = Inductance per unit length
3
2
4
1
2
2
4
1
3
2E
i
= Incremental length
ꢂX
(cꢀ
SHORT
1
7
7
Figure 15
6
5
2
3
6
5
2
3
4
5
6
PURE TRAVELING WAVE
4
3
2
4
5
6
4
3
2
V
I
+
AMPLITUDE
-
1
7
1
7
(dꢀ
(eꢀ
X
Figure 14
DISTANCE ALONG LINE
This figure shows generation of standing waves on a short-
ed transmission line. Dotted lines to the right of the short cir-
cuit represent the distance the wave would have traveled in
absence of the short. Dotted vectors represent the reflected
wave. The heavy solid line represents the vector sum of the
incident and refected waves. (d) and (e) represent instanta-
neous voltages and currents at different intervals of time.
V = Instantaneous voltage
I = Instantaneous current
9
Pure traveling waves: V & I in the lossless case are in phase.
V & I also reverse polarity every half wavelength.
Figure 16
1±6
Introduction to
Microwave Capacitors
Transmission Lines
FIELD ORIENTATION OF A COAXIAL LINE
Open Circuit:
At a distance of one-quarter wavelength from the short, the
voltage is found to be twice the amplitude of the incident
voltage, which is equivalent to an open circuit. Therefore, this
same distribution would be obtained if an open circuit were
placed a quarter wavelength from the short. In the case the
first node is located a quarter wavelength from the open and
the first antinode is right as the open. The node-to-node
spacing remains half wavelength as is the antinode-to-antinode
spacing.
E
H
I
•
V
DIRECTION OF PROPAGATION
Figure 17
Voltage Standing Wave Ratio:
The voltage standing wave ratio is defined as the ratio of the
maximum voltage to the minimum voltage on a transmission
line. This ratio is most frequently referred to as VSWR (Viswar).
MICROSTRIP
TWO
COAXIAL
WIRE
RECTANGULAR
WAVEGUIDE
RIDGED
WAVEGUIDE
CIRCULAR
WAVEGUIDE
Emax
Emin
Ei + Er 1 + Rho
Eq. 14. VSWR =
=
=
Ei - Er
1 - Rho
CROSS SECTIONAL CONFIGURATIONS OF
VARIOUS TYPES OF GUIDING STRUCTURES
where Rho = reflective coefficient
If the transmission line is terminated in a short or open circuit,
the reflected voltage, Er, is equal to the incident voltage, Ei.
From the above equation the reflection coefficient is 1.0, and
the VSWR is infinite. If a matched termination is connected to
the line, the reflected wave is zero, the reflection coefficient is
zero, and the VSWR is zero.
Figure 18
The total voltage pattern is called a standing wave. Standing
waves exist as the result of two waves of the same frequency
traveling in opposite directions on a transmission line.
The total voltage at any instant has a sine wave distribution
along the line with zero voltage at the short and zero points at
half wave intervals from the short circuit. The points of zero
voltages are called voltage nodes and the points of maximum
voltage halfway between these nodes are called antinodes.
9
1±7
Introduction to
Microwave Capacitors
Incorporation of Capacitors into Microwave Integrated Circuit Hybrids
• Dielectric Constant: Increase of the dielectric constant of
the substrate will decrease the ZO of the microstrip line.
Microwave Integrated Circuit Hybrids
A Microwave Integrated Circuit Hybrid (MIC) is a microwave
Table II shows a brief listing of substrate properties.
circuit that uses integrated circuit production techniques
involving such factors as thin or thick films, substrates,
dielectrics, conductors, resistors, and microstrip lines, to
build passive assemblies on a dielectric. Active elements
such as microwave diodes and transistors are usually added
after photo resist, masking, etching, and deposition process-
es have been completed. MICs usually are enclosed as
shielded microstrip to prevent electromagnetic interference
with other components or systems. This section will discuss
some of the important characteristics of MICs, such as:
Table II
Material
Alumina
Sapphire Quartz Beryllium
Oxide
Relative
Dielectric
Constant, E
9.8*
11.7
0.0001
0.4
3.8
0.0001
0.01
6.6
0.0001
2.5
r
Loss
Tangent at
10 GHz
0.0001
0.3
• MIC substrates
• MIC metallization
• MIC components
Thermal
Conductivity
K, in W/CM/
Deg. C
MIC Substrates:
Microstrip employs circuitry that is large compared to the
wavelength of the frequency used with the circuit. For this
reason, the etched metal patterns often are distributed cir-
cuits with transmission lines etched directly onto the MIC
substrate. Figure 19 shows the pertinent dimensional para-
meters for a microstrip transmission line.
*Alumina E depends on vendor and purity.
r
The dependence of ZO to the above parameters is as shown:
Eq. 15. ZO(f) = 377 * H/(W)/Sqrt (Er)
where,
H = height of the substrate
For the current discussion we are most interested in the high-
er microwave frequencies. The MIC circuit design requires a
uniform and predictable substrate characteristic. Several
types of substrates in common usage are: alumina, sapphire,
quartz, and beryllium oxide. Key requirements for a MIC sub-
strate are that it have:
W = width of the microstrip
conductor
Er = dielectric constant of the
substrate
A graph of ZO versus W/H for several values of dielectric
constants is shown below:
• Low dielectric loss
1±±±
• Uniform dielectric constant
• Smooth finish
• Low expansion coefficient
5±±
4±±
3±±
2±±
2.3
2.55
1±±
4.8
6.8
5±
1±
4±
STRIP
CONDUCTOR
3±
2±
W
1±
5
4
DIELECTRIC
h
3
2
1
GROUND PLANE
.1
.4 .5
1
2
3
4
5
7.5 1±
2± 3±
4± 5±
1±±
.2 .3
Figure 19. MIC Microstrip Outline
MICROSTRIP W/H
The characteristic impedance of the microstrip line is depen-
dent primarily on the following:
Figure 20
The most popular substrate material is alumina which has a
dielectric constant of between 9.6 and 10.0 depending on
the vendor and the purity. Other substrates are used where
the specified unique properties of the material (beryllia for
high power, ferrites for magnetic properties) are demanded
by design.
• Width of the conductor: Increase in the width “W” of the
conductor will decrease the ZO of the microstrip line.
• Height of the substrate: Increase in the height “H” of the
substrate will increase the ZO of the microstrip line.
9
1±8
Introduction to
Microwave Capacitors
Incorporation of Capacitors into Microwave Integrated Circuit Hybrids
MIC Metallization:
Capacitors:
MIC metallization is a thin film of two or more layers of met-
als. A base metallization layer is deposited onto the sub-
strate, another layer may be optionally deposited on top of
this, and then a final gold layer is deposited onto the surface.
The base metallization is chosen for its adhesion to the sub-
strate and for compatibility with the next layer.
A lumped capacitor can be realized by the parallel gap
capacitance of an area of metallization on the top of the sub-
strate to the ground plane. Values of capacitance that can be
obtained by this method are usually less than a few pico-
farads. At microwave frequencies if the capacitor size in any
one dimension begins to approach a quarter-wavelength, a
resonance will occur.
The base metallization is usually lossy at microwave fre-
quencies. The losses due to this metallization can be kept to
a minimum if its thickness does not exceed one “skin depth”
of the metal.
Large values of capacitance can be achieved with a dielec-
tric constant between the capacitor plates while maintaining
the small size required for MIC circuits.
Skin effect defines a phenomenon at microwave frequencies
where the current travelling along a conductor does not pen-
etrate the conductor but remains on the surface of the con-
ductor. The “skin depth” indicates how far the microwave
current will penetrate into the metal. The “skin depth” is
smaller as the frequency increases.
Chip capacitors can be fabricated on substrate with a dielec-
tric constant up to 5000. This higher dielectric constant
allows a much smaller size capacitor for a given capacitance
value which is a very desirable feature both from the real
estate aspect and the self-resonance aspect.
Resistors:
By keeping the lossy metallization as thin as possible, more
of the microwave current will propagate in the top metalliza-
tion gold layer and loss is minimized.
MIC resistors are often realized by using a resistive base layer
on the MIC substrate metallization, and by etching the prop-
er pattern to expose the resistive layer in the MIC circuitry.
Typical metallization schemes used in the industry are:
The exact value of the resistor is determined by:
• Chromium-Gold:
• Nichrome-Gold:
Cr-Au
NiCr-Au
• resistivity of the resistive base layer, and
• length and width of the resistor.
• Chromium-Copper-Gold: Cr-Cu-Au
Thin film resistive base layers are usually the following:
• Titanium-Tungsten-Gold:
• Others
TiW-Au
• tantalum nitrite, or
• nickel-chrome (nichrome).
MIC Components:
When chip resistors are used, they are mounted and con-
nected in the same way as the chip capacitors.
Microstrip has advantages over other microwave circuit
topologies in that active semiconductors and passive com-
ponents can easily be incorporated to make active hybrid
circuits. It is possible to mix high and low frequency circuitry
to attain a “system-on-a substrate.”
Inductors:
Inductors are often realized by using narrow etched
microstrip lines which provides inductance on the order of
1 to 5 nanohenrys.
Passive Components:
Higher values up to 50 nanohenrys are obtained by etching
a round or square spiral onto the MIC metallization.
On MIC circuits, the passive components are either distrib-
uted or lumped elements. The distributed components are
usually realized by etched patterns on the substrate metal-
lization. The lumped components are capacitors, resistors,
and inductors; and whenever possible components are
derived by etching them directly on the MlC metallization thin
film. Chip components are used when they offer advantages
such as:
Even higher values can be obtained by using wound wire
inductors or chip inductors which are wire coils encased in a
ceramic.
Both types of discrete inductors are attached to the circuit
by the same means as the capacitors.
• Component values are beyond that realizable by thin film
techniques on the MIC substrates,
• Smaller size is required,
• High power capability is required.
Capacitors, resistors, and inductors are discussed in the
following:
9
1±9
Introduction to
Microwave Capacitors
Incorporation of Capacitors into Microwave Integrated Circuit Hybrids
temperature. Other combinations have transition states with
wider temperature ranges. For instance, the eutectic tem-
perature for the following alloys are:
Active components:
The active devices in the MIC circuit can be made of entirely
different materials than the substrates and are usually
attached to the substrates by eutectic soldering or conduc-
tive epoxy.
Table III
Eutectic
Eutectic
Typical active devices on MIC circuits are the following:
Alloy
Composition
Temperature
• GaAs FETs
Gold Germanium
Gold Tin
88ꢀ Au 12ꢀ Ge
80ꢀ Au 20ꢀ Sn
356°C
280°C
• Bipolar Transistors
• Schottky Barrier Diodes
• PIN Diodes
• Various other Semiconductors
For best results, the eutectic attach is performed under an
inert gas atmosphere, typically nitrogen, to reduce oxidation
at high temperatures. The eutectic must be selected so that
the die attach operations will not interfere with prior solder-
ing operations and itself will not be disturbed by subsequent
process steps. The metallization should be able to undergo
400°C without any blistering or other adhesion degradation.
The active devices can be either in:
• a plastic or ceramic package with metal leads, or
• chip form.
The packaged devices are commonly used at a lower
frequency range than the chip devices since they exhibit
more parasitic circuit elements that limit their performance at
higher frequency.
2. Epoxy Die Attach
The epoxy die attach method uses silver or gold conductive
particles in an epoxy. The epoxy for chip attach on MIC
circuits is a one-part type which cures at temperatures of from
125°C to 200°C. The curing time is a function of temperature.
A cure time of 30 minutes at 150°C is a good compromise for
high reliability and a reasonable cure time.
The advantages of packaged devices are protection of the
devices during transport and mounting, ease of characteri-
zation, and ease of mounting onto the MIC circuit.
Chip Component Attach:
The methods of attachment of the chip components to the
substrate are usually by:
Chip Components Interconnection:
The chip components are interconnected to the MIC circuit
by means of:
• eutectic solder die attach, and
• epoxy die attach.
1. Eutectic Die Attach
• wire bonding, and
The eutectic die attach method can be used with several
alloys. Eutectic defines the exact alloy combination at which
the solidus to liquidus transition takes place at one particular
• miniature parallel gap welding.
9
11±
Other Products
PASSIVES
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Memory Card Connectors
CF, PCMCIA, SD, MMC
MOBOTM, I/O, Board to Board and
Battery Connectors
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Varicon®
Wire to Board, Crimp or IDC
Microwave
Glass
Film
Power Film
Power Ceramic
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Trimmer
Thin Film
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Components
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herein are believed to be accurate and reliable, but are presented without guarantee, warranty, or responsibility of any kind, expressed or implied. Statements
or suggestions concerning possible use of our products are made without representation or warranty that any such use is free of patent infringement and are not
recommendations to infringe any patent. The user should not assume that all safety measures are indicated or that other measures may not be required. Specifications are
typical and may not apply to all applications.
© AVX Corporation
111
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