F2270 [IDT]
Voltage Variable Attenuator;型号: | F2270 |
厂家: | INTEGRATED DEVICE TECHNOLOGY |
描述: | Voltage Variable Attenuator |
文件: | 总29页 (文件大小:1862K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
75Ω Voltage Variable Attenuator
5MHz to 3000MHz
F2270
Datasheet
Description
Features
The F2270 is a 75Ω, low insertion loss voltage variable RF
attenuator (VVA) designed for a multitude of wireless and other RF
applications. This device covers a broad frequency range from
5MHz to 3000MHz. In addition to providing low insertion loss, the
F2270 provides excellent linearity performance over its entire
attenuation range.
.
.
.
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.
.
.
.
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Frequency range: 5MHz to 3000MHz
Low insertion loss: 1.1dB at 300MHz
Typical/Minimum IIP3 ≥ 50MHz: 62dBm / 46dBm
Typical/Minimum IIP2 ≥ 50MHz: 98dBm / 77dBm
Up to 35dB attenuation range
Attenuation slope versus VCTRL: 10dB/Volt
Bi-directional RF ports
The F2270 uses a positive supply voltage of 3.3V or 5V. Other
features include a VMODE pin allowing either a positive or negative
voltage control slope versus attenuation and multi-directional
operation where the RF input can be applied to either the RF1 or
RF2 pins. The attenuation control voltage range is from 0V to 5V
using either a 3.3V or 5V power supply.
+36dBm input P1dB
VMODE pin allows either positive or negative attenuation control
response
.
.
.
.
.
Linear-in-dB attenuation characteristic
Nominal supply voltage: 3.3V or 5V
Competitive Advantage
VCTRL range: 0V to 5V using 3.3V or 5V supply
-40°C to +105°C operating temperature range
3 × 3 mm, 16-VFQFPN package
The F2270 provides extremely low insertion loss and superb IP3,
IP2, return loss performance, and slope linearity across the control
range. Compared to the previous state-of-the-art for silicon VVAs,
this device provides superior performance:
Block Diagram
Figure 1. Block Diagram
.
.
.
.
.
Operation down to 5MHz
Insertion loss at 300MHz of 1.1dB
Typical attenuation slope: 10dB/Volt
Minimum OIP3 (maximum attenuation): +35dBm
Minimum IIP2 (maximum attenuation, > 35MHz): +85dBm
VMODE VDD VCTRL
Control
Typical Applications
.
CATV/Broadband Applications
.
.
Headend
RF1
RF2
Fiber/HFC Distribution Nodes
.
CATV Test Equipment
© 2019 Integrated Device Technology, Inc.
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F2270 Datasheet
Pin Assignments
Figure 2. Pin Assignments for 3 x 3 x 0.9 mm 16-VFQFPN Package – Top View
16
15
14
13
12
11
10
9
GND
NC
GND
NC
1
2
3
4
CONTROL
RF1
NC
RF2
NC
EP
5
6
7
8
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F2270 Datasheet
Pin Descriptions
Table 1.
Pin Descriptions
Number
Name
Description
1, 5 – 8, 12,
13
GND
Internally grounded. This pin must be grounded as close to the device as possible.
No internal connection. These pins can be left unconnected, have a voltage applied, or be connected to
ground (recommended).
2, 4, 9, 11
NC
RF Port 1. Matched to 75Ω. Since the RF pin internally has DC present, an external AC coupling capacitor
must be used. For low-frequency operation, increase the capacitor value to result in a low reactance at the
frequency of interest. An external series inductor of 2.4nH can also be used to improve the high frequency
match. This inductor, if used, should be placed as close to the device as possible.
3
RF1
RF Port 2. Matched to 75Ω. Since the RF pin internally has DC present, an external AC coupling capacitor
must be used. For low-frequency operation, increase the capacitor value to result in a low reactance at the
frequency of interest. An external series inductor of 2.8nH can also be used to improve the high frequency
match. This inductor, if used, should be placed as close to the device as possible.
10
RF2
Attenuator control voltage. Apply a voltage in the range specified in under “Recommended Operating
Conditions.” See the “Application Information” section for details about VCTRL. This pin is connected to an
internal 100kΩ series resistor that drives a biased voltage divider network.
14
15
16
VCTRL
VDD
Power supply input. Bypass to ground (GND) with capacitors as close as possible to the pin.
Attenuator slope control. Set to logic LOW to enable negative attenuation slope (maximum attenuation at
maximum VCTRL). Set to logic HIGH to enable positive attenuation slope (maximum attenuation at minimum
VCTRL). This pin is internally connected to a 170kΩ pull-down resistor to ground.
VMODE
Exposed paddle. Internally connected to ground. Solder this exposed paddle to a printed circuit board (PCB)
pad that uses multiple ground vias to provide heat transfer out of the device into the PCB ground planes.
These multiple ground vias are also required to achieve the specified RF performance.
– EPAD
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F2270 Datasheet
Absolute Maximum Ratings
Stresses above those listed below may cause permanent damage to the device. Functional operation of the device at these or any other
conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions
for extended periods may affect device reliability.
Table 2.
Absolute Maximum Ratings
Parameter
Symbol
Minimum
Maximum
Units
VDD to GND
VDD
-0.3
6.0
V
Lower of
(VDD, 3.9)
VMODE to GND
VMODE
-0.3
V
Lower of
(VDD + 3.0, 5.3)
VCTRL to GND
VCTRL
VRF
-0.3
-0.3
V
V
RF1, RF2 to GND
0.3
RF1 or RF2 Input Power Applied for 24 Hours Maximum
(VDD applied at 1GHz and TEP [Exposed Paddle] = +85°C, ZS = ZL = 75Ω)
PMAX24
+28
dBm
Junction Temperature
TJMAX
TSTOR
TLEAD
+150
+150
+260
°C
°C
°C
Storage Temperature Range
Lead Temperature (soldering, 10s)
-65
2000
(Class 2)
Electrostatic Discharge – HBM
(JEDEC/ESDA JS-001-2012)
VESDHMB
V
V
500
(Class C2)
Electrostatic Discharge – CDM
(JEDEC 22-C101F)
VESDHCDM
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F2270 Datasheet
Recommended Operating Conditions
Table 3.
Recommended Operating Conditions
Parameter
Symbol
Condition
Minimum
Typical
Maximum
Units
Power Supply Voltage
Mode Voltage [a]
VDD
3.15
5.5
V
Lower of
(VDD, 3.6)
VMODE
VCTRL
0
0
V
V
Lower of
(VDD + 3.0, 5.0)
Control Voltage [a]
Operating Temperature Range
RF Frequency Range
TEP
fRF
Exposed Paddle
-40
5
+105
3000
°C
MHz
Power can be applied to
RF1 or RF2
Maximum Input RF Power
PMAX
See Figure 3
dBm
RF1 Port Impedance
RF2 Port Impedance
ZRF1
ZRF2
75
75
Ω
Ω
[a] The power supply voltage must be applied before all other voltages.
Figure 3. Maximum Operating CW RF Input Pow er vs. Frequency (ZS = ZL = 75Ω)
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F2270 Datasheet
Electrical Characteristics
Table 4.
Electrical Characteristics (General)
Refer to the application circuit in Figure 60 for the required circuit and use L1 = L2 = 0Ω. The specifications in this table apply at VDD = +5.0V,
EP = +25°C, fRF = 500MHz, ZS = ZL = 75Ω, signal applied to RF1, minimum attenuation, PIN = 0dBm for small signal parameters, PIN = +20dBm
T
per tone for two tone tests, VMODE is LOW or HIGH, and Evaluation Board (EVKit) trace and connector losses are de-embedded, unless
otherwise noted.
Parameter
Symbol
Condition
3.9V ≤ VDD ≤ 5.5V
VDD < 3.9V
Minimum
1.07 [a]
1.07
Typical
Maximum
3.6
Units
VMODE Logic Input HIGH
VIH
V
VDD – 0.3
0.63
VMODE Logic Input LOW
VDD Current
VIL
IDD
0
V
1.4
25
mA
μA
μA
2.5
VMODE Current
IMODE
ICTRL
VCTRL Current
50
VMODE = LOW
VMODE = HIGH
10
Attenuation Slope
ATTSLOPE
dB/V
dB
-10
fRF = 50MHz
(-40°C to 105°C, over full
signal range of VCTRL
Attenuation Variation over
Temperature (reference to +25°C)
ATTVAR
1
)
Any 1dB step in the 0dB to
33dB control range,
50% of VCTRL signal to RF
settled to within 0.1dB
Settling Time
tSETTLE
25
µs
[a] Specifications in the minimum/maximum columns that are shown in bold italics are guaranteed by test. Specifications in these
columns that are not shown in bold italics are guaranteed by design characterization.
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F2270 Datasheet
Electrical Characteristics (continued)
Table 5.
Electrical Characteristics (No External RF Tuning)
Refer to the application circuit in Figure 60 for the required circuit and use L1 = L2 = 0Ω. The specifications in this table apply at VDD = +5.0V,
EP = +25°C, fRF = 500MHz, ZS = ZL = 75Ω, signal applied to RF1, minimum attenuation, PIN = 0dBm for small signal parameters, PIN = +20dBm
T
per tone for two tone tests, VMODE is LOW or HIGH, and Evaluation Board (EVKit) trace and connector losses are de-embedded, unless
otherwise noted.
Parameter
Insertion Loss, IL
Symbol
Condition
Minimum
Typical
Maximum
Units
1.8 [a]
AMIN
Minimum attenuation
fRF = 5MHz
1.1
23
dB
fRF = 10MHz
28
Maximum Attenuation
AMAX
dB
fRF = 500MHz
35
33
300MHz < fRF ≤ 1800MHz
VCTRL = 1.0 V, VMODE = LOW
VCTRL = 2.1 V, VMODE = LOW
35
1.5
2.8
Attenuation Variation [c]
Relative Insertion Phase
AVAR
dB
At maximum attenuation relative
to minimum attenuation
ΦΔMAX
9
deg
5MHz ≤ fRF ≤ 300MHz
23
15
12
23
15
12
36
45
57
RF1 Return Loss
(over control voltage range)
S11
300MHz < fRF ≤ 1220MHz
1220MHz < fRF ≤ 1800MHz
5MHz ≤ fRF ≤ 300MHz
dB
RF2 Return Loss
(over control voltage range)
S22
300MHz < fRF ≤ 1220MHz
1220MHz < fRF ≤ 1800MHz
dB
Input Power Compression [b]
Input IP3
IP1dB
dBm
fRF = 5MHz, 1MHz spacing
fRF = 50MHz, 5MHz spacing
IIP3
dBm
300MHz < fRF < 2GHz,
50MHz spacing
60
Input IP3 over Attenuation
Minimum Output IP3
IIP3ATTEN All attenuation settings
OIP3MIN Maximum attenuation
46
35
98
77
82
50
dBm
dBm
dBm
dBm
dBm
dBm
Input IP2
IIP2
IIP2MIN
IIPH2
IM2 term is f1 + f2
All attenuation settings
PIN + H2dBc
Minimum Input IP2
Input 2nd Harmonic Intercept Point
Input 3rd Harmonic Intercept Point
IIPH3
PIN + (H3dBc /2)
[a] Specifications in the minimum/maximum columns that are shown in bold italics are guaranteed by test. Specifications in these
columns that are not shown in bold italics are guaranteed by design characterization.
[b] The input 1dB compression point is a linearity figure of merit. Refer to the “Absolute Maximum Ratings” section for the
maximum RF input power.
[c] This value is for part to part variation at the given voltage.
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F2270 Datasheet
Electrical Characteristics (continued)
Table 6.
Electrical Characteristics – Extended Bandw idth Tuning (EBT) using external components
Refer to the application circuit in Figure 60 for the required circuit and use L1 = 2.4nH and L2 =2.8nH. The specifications in this table apply at
DD = +5.0V, TEP = +25°C, fRF = 500MHz, ZS = ZL = 75Ω, signal applied to RF1, minimum attenuation, PIN = 0dBm for small signal parameters,
V
PIN = +20dBm per tone for two tone tests, VMODE is LOW or HIGH, and Evaluation Board (EVKit) trace and connector losses are de-embedded,
unless otherwise noted.
Parameter
Insertion Loss, IL
Symbol
Condition
Minimum attenuation
fRF = 5MHz
Minimum
Typical
1.1
23
Maximum
Units
AMIN
dB
fRF = 10MHz
28
Maximum Attenuation
AMAX
dB
50MHz < fRF ≤ 300MHz
300MHz < fRF ≤ 1800MHz
VCTRL = 1.0 V, VMODE = LOW
VCTRL = 2.1 V, VMODE = LOW
35
35
1.5
2.8
Attenuation Variation [c]
Relative Insertion Phase
AVAR
dB
At maximum attenuation relative
to minimum attenuation
ΦΔMAX
9
deg
5MHz ≤ fRF ≤ 300MHz
23
18
12
23
18
12
36
45
57
RF1 Return Loss
(over control voltage range)
S11
300MHz < fRF ≤ 1220MHz
1220MHz < fRF ≤ 1800MHz
5MHz ≤ fRF ≤ 300MHz
dB
RF2 Return Loss
(over control voltage range)
S22
300MHz < fRF ≤ 1220MHz
1220MHz < fRF ≤ 1800MHz
dB
Input Power Compression [b]
IP1dB
dBm
fRF = 5MHz, 1MHz spacing
fRF = 50MHz, 5MHz spacing
Input IP3 (Minimum Attenuation)
IIP3
dBm
300MHz < fRF < 2GHz,
50MHz spacing
60
Input IP3 over attenuation
Minimum Output IP3
IIP3ATTEN All attenuation settings
OIP3MIN Maximum attenuation
46
35
98
77
82
50
dBm
dBm
dBm
dBm
dBm
dBm
Input IP2
IIP2
IIP2MIN
IIPH2
IM2 term is f1 + f2
All attenuation settings
PIN + H2dBc
Minimum Input IP2
Input 2nd Harmonic Intercept Point
Input 3rd Harmonic Intercept Point
IIPH3
PIN + (H3dBc /2)
[a] Specifications in the minimum/maximum columns that are shown in bold italics are guaranteed by test. Specifications in these
columns that are not shown in bold italics are guaranteed by design characterization.
[b] The input 1dB compression point is a linearity figure of merit. Refer to t the “Absolute Maximum Ratings” section for the
maximum RF input power.
[c] This value is for part to part variation at the given voltage.
© 2019 Integrated Device Technology, Inc.
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F2270 Datasheet
Thermal Characteristics
Table 7.
Package Thermal Characteristics
Parameter
Symbol
Value
Units
Junction to Ambient Thermal Resistance
θJA
80.6
°C/W
Junction to Case Thermal Resistance
(case is defined as the exposed paddle)
θJC-BOT
5.1
°C/W
Moisture Sensitivity Rating (Per J-STD-020)
MSL 1
Typical Operating Conditions (TOCs)
Unless otherwise noted:
.
.
.
.
VDD = +5.0V
ZS = ZL = 75Ω
TEP = +25ºC
RF trace and connector losses removed for insertion loss and attenuation results. All other results include the PCB trace and connector
losses and mismatched effects.
.
.
PIN = 0dBm for all small signal tests
. PIN = +20dBm/tone for two tone linearity tests (RF1 port driven)
Two tone frequency spacing
.
.
.
1MHz for 5MHz ≤ fRF < 50MHz
5MHz for 50MHz ≤ fRF < 500MHz
50MHz for 500MHz ≤ fRF < 3500MHz
.
.
All temperatures are referenced to the exposed paddle.
Extended band tuning uses L1 = 2.4nH and L2 = 2.8nH to improve RF1 and RF2 port match.
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 4. Insertion Loss vs. Frequency
[VMODE = LOW]
Figure 5. Relative Insertion Loss vs. VCTRL
[VMODE = LOW]
Figure 6. RF1 Return Loss vs. Frequency
[VMODE = LOW]
Figure 7. RF1 Return Loss vs. VCTRL
[VMODE = LOW]
Figure 8. RF2 Return Loss vs. Frequency
[VMODE = LOW]
Figure 9. RF2 Return Loss vs. VCTRL
[VMODE = LOW]
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 10. Relative Insertion Phase vs.
Frequency [VMODE = LOW]
Figure 11. Relative Insertion Phase vs. VCTRL
[VMODE = LOW]
Figure 12. Insertion Loss vs. Frequency
Figure 13. Attenuation Slope vs. VCTRL
[VMODE = LOW]
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 14. Insertion Loss vs. Frequency
[VMODE = HIGH]
Figure 15. Relative Insertion Loss vs. VCTRL
[VMODE = HIGH]
Figure 16. RF1 Return Loss vs. Frequency
[VMODE = HIGH]
Figure 17. RF1 Return Loss vs. VCTRL
[VMODE = HIGH]
Figure 18. RF2 Return Loss vs. Frequency
[VMODE = HIGH]
Figure 19. RF2 Return Loss vs. VCTRL
[VMODE = HIGH]
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 20. Relative Insertion Phase vs.
Frequency [VMODE = HIGH]
Figure 21. Relative Insertion Phase vs. VCTRL
[VMODE = HIGH]
Figure 22. Attenuation Slope vs. VCTRL
[VMODE = HIGH]
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 23. Input IP3 vs. VCTRL
[5MHz, VMODE = LOW]
Figure 24. Input IP3 vs. VCTRL
[5MHz, VMODE = HIGH]
Figure 25. Input IP3 vs. VCTRL
[50MHz, VMODE = LOW]
Figure 26. Input IP3 vs. VCTRL
[50MHz, VMODE = HIGH]
Figure 27. Input IP3 vs. VCTRL
[1.2GHz, VMODE = LOW]
Figure 28. Input IP3 vs. VCTRL
[1.2GHz, VMODE = HIGH]
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F2270 Datasheet
Typical Performance Characteristics (No External RF Tuning)
Figure 29. Compression vs. Input Pow er
[5MHz, VMODE = LOW,VCTRL = 0V]
Figure 30. Compression vs. Input Pow er
[5MHz, VMODE = HIGH, VCTRL = 5V]
Figure 31. Compression vs. Input Pow er
[100MHz, VMODE = LOW, VCTRL = 0V]
Figure 32. Compression vs. Input Pow er
[100MHz, VMODE = HIGH, VCTRL = 5V]
Figure 33. Compression vs. Input Pow er
[1.2GHz, VMODE = LOW, VCTRL = 0V]
Figure 34. Compression vs. Input Pow er
[1.2GHz, VMODE = HIGH, VCTRL = 5V]
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F2270 Datasheet
Typical Performance Characteristics (Extended Bandw idth Tuning)
Figure 35. Insertion Loss vs. Frequency
[VMODE = LOW]
Figure 36. Relative Insertion Loss vs. VCTRL
[VMODE = LOW]
Figure 37. RF1 Return Loss vs. Frequency
[VMODE = LOW]
Figure 38. RF1 Return Loss vs. VCTRL
[VMODE = LOW]
Figure 39. RF2 Return Loss vs. Frequency
[VMODE = LOW]
Figure 40. RF2 Return Loss vs. VCTRL
[VMODE = LOW]
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F2270 Datasheet
Typical Performance Characteristics (Extended Bandw idth Tuning)
Figure 41. Relative Insertion Phase vs.
Frequency [VMODE = LOW]
Figure 42. Relative Insertion Phase vs. VCTRL
[VMODE = LOW]
Figure 43. RF1 Return Loss vs. Frequency
[VMODE = LOW]
Figure 44. Attenuation Slope vs. VCTRL
[VMODE = LOW]
Figure 45. RF2 Return Loss vs. Frequency
[VMODE = LOW]
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F2270 Datasheet
Typical Performance Characteristics (Extended Bandw idth Tuning)
Figure 46. Insertion Loss vs. Frequency
[VMODE = HIGH]
Figure 47. Relative Insertion Loss vs. VCTRL
[VMODE = HIGH]
Figure 48. RF1 Return Loss vs. Frequency
[VMODE = HIGH]
Figure 49. RF1 Return Loss vs. VCTRL
[VMODE = HIGH]
Figure 50. RF2 Return Loss vs. Frequency
[VMODE = HIGH]
Figure 51. RF2 Return Loss vs. VCTRL
[VMODE = HIGH]
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F2270 Datasheet
Typical Performance Characteristics (Extended Bandw idth Tuning)
Figure 52. Relative Insertion Phase vs.
Frequency [VMODE = HIGH]
Figure 53. Relative Insertion Phase vs. VCTRL
[VMODE = HIGH]
Figure 54. RF1 Return Loss vs. Frequency
[VMODE = HIGH]
Figure 55. Attenuation Slope vs. VCTRL
[VMODE = HIGH]
Figure 56. RF2 Return Loss vs. Frequency
[VMODE = HIGH]
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F2270 Datasheet
Application Information
The F2270 has been optimized for use in high performance RF applications from 5MHz to 1800MHz and has a full operating range of 5MHz to
3000MHz.
Default Start-up
VMODE should be tied to either logic LOW (ground) or logic HIGH. If the VCTRL pin is left floating, the part will power up in the minimum attenuation
state when VMODE = LOW or in the maximum attenuation state when VMODE = HIGH.
VMODE
The VMODE pin is used to set the slope of the attenuation. The attenuation is varied by VCTRL as described in the next section. Setting VMODE to
a logic LOW (HIGH) will set the attenuation slope to negative (positive). A negative (positive) slope is defined as an increased (decreased)
attenuation with increasing VCTRL voltage. The Evaluation Kit provides has an on-board jumper to manually set VMODE. Install a jumper on header
J7 from VMODE to the pin marked Lo (Hi) to set the device for a negative (positive) slope (see Figure 58).
VCTRL
The voltage level on the VCTRL pin is used to control the attenuation of the F2270. At VCTRL =0V, the attenuation is a minimum (maximum) in the
negative (positive) slope mode. An increasing voltage on VCTRL produces an increasing (decreasing) attenuation respectively. The VCTRL pin
has an on-chip pull-up ESD diode so VDD should be applied before VCTRL is applied (see “Recommended Operating Conditions” for details). If
this sequencing is not possible, then resistor R5 in the application circuit (see Figure 60) should be set to 1kΩ to limit the current into the VCTRL
pin.
RF1 and RF2 Ports
The F2270 is a bi-directional device, allowing RF1 or RF2 to be used as the RF input. RF1 has some enhanced linearity performance, and
therefore should be used as the RF input, when possible, for best results. The F2270 has been designed to accept high RF input power levels;
therefore, VDD must be applied prior to the application of RF power to ensure reliability. DC blocking capacitors are required on the RF pins and
should be set to a value that results in a low reactance over the frequency range of interest. External series inductors can be added on the RF1
and RF2 lines close to the device to improve the higher frequency match.
Power Supplies
The VDD supply pin should be bypassed with external capacitors to minimize noise and fast transients. Supply noise can degrade performance,
and fast transients can trigger ESD clamps and cause them to fail. Supply voltage changes or transients should have a slew rate smaller than
1V/20µs. In addition, all control pins should remain at 0V (+/- 0.3V) while the supply voltage ramps or while it returns to zero.
Control Pin Interface
If control signal integrity is a concern and clean signals cannot be guaranteed due to overshoot, undershoot, or ringing, etc., then implementing
the circuit shown in Figure 57 at the input of each control pin is recommended. This applies to control pins 14 (VCTRL) and 16 (VMODE) as
shown in Figure 57. Note the recommended resistor and capacitor values do not necessarily match the Evaluation Kit BOM for the case of poor
control signal integrity.
Extended Bandwidth Tuning (EBT)
There are cases where the return loss for the RF ports needs to be better than 18 dB across the frequency range. For this case, adding series
inductors just next to the package on the RF ports will accomplish this. The addition of these inductors, 2.4nH on RF1 and 2.8nH on RF2, will
degrade the insertion loss and return loss at frequencies above 2GHz.
© 2019 Integrated Device Technology, Inc.
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F2270 Datasheet
Figure 57. Control Pin Interface for Signal Integrity
5Kohm
5Kohm
2pf
VMODE
VCTRL
2pf
16
15
14
13
12
11
10
9
1
2
3
4
Control
RF1
RF2
5
6
7
8
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F2270 Datasheet
Evaluation Kit Pictures
Figure 58. Evaluation Kit Top View
Figure 59. Evaluation Kit Bottom View
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F2270 Datasheet
Evaluation Kit / Applications Circuit
Figure 60. Electrical Schematic
VCC
J3
75 ohm transmission line
TP2
VCC
VCC
J6
J5
Thru Cal
GND
TP3
VCTRL
MEAS
VCC
TP1
VCTRL
R4
R8
R3
J4
VCC
C1
R5
C2
C4
VCC
Voltage divider sets
logic 'Hi" level
for VMODE input.
R6
C3
VMODE SET
R7
R1
C5
C6
LO
HI
R2
J7
1
2
3
4
12
11
10
9
GND
GND
NC
RF2
J2
RF1
NC
RF2
NC
75 ohm
75 ohm
transmission line
J1
transmission line
F2270
RF1
NC
L1
L2
C7
C8
U1
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F2270 Datasheet
Table 8.
Bill of Material (BOM)
Part Reference
C1 – C8
QTY
8
Description
0.1µF 10%, 16V, X7R Ceramic Capacitor (0402)
100kΩ ±1%, 1/10W, Resistor (0402)
10Ω ±1%, 1/10W, Resistor (0402)
1kΩ 1%, 1/10W, Resistor (0402)
100Ω ±1%, 1/10W, Resistor (0402)
0Ω ±1%, 1/10W, Resistor (0402)
2.4nH 0.1nH, Inductor (0402)
0Ω ±1%, 1/10W, Resistor (0402)
2.8nH 0.1nH, Inductor (0402)
Edge Launch F TYPE 75Ω
Manufacturer Part #
GRM155R71C104K
ERJ-2RKF1003X
ERJ-2RKF10R0X
ERJ-2RKF1001X
ERJ-2RKF1000X
ERJ-2GE0R00X
LQP15MN2N4B02D
ERJ-2GE0R00X
LQP15MN2N8B02D
222181
Manufacturer
Murata
R1, R2, R3
3
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Murata
R4
R5
R7
1
1
1
0
L1 [a]
L2 [a]
1
0
Panasonic
Murata
1
J1, J2, J5, J6
4
Amphenol
J3, J4
J7
2
Edge Launch SMA (0.375 inch pitch ground, tab)
Conn Header Vertical SGL 3 X 1 Pos Gold
Test Point White
142-0701-851
961103-6404-AR
5002
Emerson Johnson
3M
1
TP1
TP2
TP3
U1
1
Keystone Electronics
Keystone Electronics
Keystone Electronics
IDT
1
Test Point Red
5000
1
Test Point Black
5001
1
75Ω Voltage Variable Attenuator
Printed Circuit Board
F2270NLGK
1
F2270 Rev 02
IDT
R6, R8
0
DNP
[a] Series inductors are added on the RF port to improve the high-frequency port match (extended band). If not required then the 0Ω
resistor can be used.
© 2019 Integrated Device Technology, Inc.
24
January 16, 2019
F2270 Datasheet
Evaluation Kit Operation
Below is a basic setup procedure for configuring and testing the F2270 Evaluation Kit (EVKit).
Pre-Configure EVKit
This section is a guide to setting up the EVKit for testing. To configure the board for a negative attenuation slope (increasing attenuation with
increasing VCTRL voltage), install a header-shunt shorting pin 2 (center pin) and pin 3 (labeled Lo) on header J7 (see Figure 58). For a positive
slope (decreasing attenuation with increasing VCTRL voltage), this header-shunt should short pin 1 (labeled Hi) to pin 2 (center pin) on J7.
Power Supply Setup
Without making any connections to the EVKit, set up one fixed power supply (VCC) for 5V with a current limit of 10mA and one variable power
supply (VCTRL) set to 0V with a current limit of 5mA. Disable both power supplies.
RF Test Setup
Set the RF test setup to the desired frequency and power ranges within the specified operating limits noted in this datasheet.
Disable the output power of all the RF sources.
Connect EVKit to the test setup.
With the RF sources and power supplies disabled, connect the fixed 5V power supply to connector J3, the variable supply to J4, and the RF
connections to the desired RF ports.
Powering Up the EVKit
Enable the VCC power supply and observe a DC current of approximately 1.4mA.
Enable the VCTRL power supply.
Enable the RF sources. Verify that the DC current remains at about 1.4mA.
If the J7 connection is set for a negative (positive) attenuation slope, then increasing the variable supply will produce increased (decreased)
attenuation for the attenuator path (J1 to J2).
Powering Down the EVKit
Disable the RF power applied to the device.
Adjust the VCTRL power supply down to 0V and disable it.
Disable the VCC power supply.
Disconnect the EVKit from the RF test setup.
© 2019 Integrated Device Technology, Inc.
25
January 16, 2019
F2270 Datasheet
Package Outline Draw ings
The package outline drawings are appended at the end of this document and are accessible from the link below. The package information is
the most current data available.
www.idt.com/document/psc/16-vfqfpn-package-outline-drawing-30-x-30-x-09-mm-05-mm-170-x-170-mm-epad-nlnlg16p2
Marking Diagram
Line 1 “A01” is for lot code.
Line 2 “637” = has one digit for the year and week that the part was assembled.
Line 2 “W” is the assembler code.
Line 3 is the abbreviated part number.
A01
637W
F2270
Ordering Information
Operating
Orderable Part Number
Package
MSL Rating
Shipping Packaging
Temperature
-40°C to +105°C
-40°C to +105°C
F2270NLGK
F2270NLGK8
F2270EVBI
3.0 × 3.0 × 0.9 mm 16-VFQFPN
3.0 × 3.0 × 0.9 mm 16-VFQFPN
Evaluation Board
1
1
Tray
Reel
© 2019 Integrated Device Technology, Inc.
26
January 16, 2019
F2270 Datasheet
Revision History
Revision Date
Description of Change
January 16, 2019
July 25, 2017
Changed the control pin leakage current to reflect the actual measured values.
Initial release
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Fax: 408-284-2775
www.IDT.com/go/sales
DISCLAIMER Integrated Device Technology, Inc. (IDT) and its affiliated companies (herein referred to as “IDT”) reserve the right to modify the products and/or specifications described herein at any time,
without notice, at IDT's sole discretion. Performance specifications and operating parameters of the described products are determined in an independent state and are not guaranteed to perform the same
way when installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability
of IDT's products for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This document is presented only as a guide and does not
convey any license under intellectual property rights of IDT or any third parties.
IDT's products are not intended for use in applications involving extreme environmental conditions or in life support systems or similar devices where the failure or malfunction of an IDT product can be
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Integrated Device Technology, IDT and the IDT logo are trademarks or registered trademarks of IDT and its subsidiaries in the United States and other countries. Other trademarks used herein are the
property of IDT or their respective third party owners. For datasheet type definitions and a glossary of common terms, visit www.idt.com/go/glossary. All contents of this document are copyright of Integrated
Device Technology, Inc. All rights reserved.
© 2019 Integrated Device Technology, Inc.
27
January 16, 2019
16-VFQFPN Package Outline Drawing
3.0 x 3.0 x 0.9 mm, 0.5mm Pitch, 1.70 x 1.70 mm Epad
NL/NLG16P2, PSC-4169-02, Rev 05, Page 1
ꢀ,QWHJUDWHGꢀ'HYLFHꢀ7HFKQRORJ\ꢁꢀ,QFꢂ
16-VFQFPN Package Outline Drawing
3.0 x 3.0 x 0.9 mm, 0.5mm Pitch, 1.70 x 1.70 mm Epad
NL/NLG16P2, PSC-4169-02, Rev 05, Page 2
Package Revision History
Description
Rev 04 Remove Bookmak at Pdf Format & Update Thickness Tolerance
Change QFN to VFQFPN
Date Created Rev No.
Oct 25, 2017
Jan 18, 2018
Rev 05
ꢀ,QWHJUDWHGꢀ'HYLFHꢀ7HFKQRORJ\ꢁꢀ,QFꢂ
相关型号:
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