LMH6401IRMZR [TI]
4.5GHz 超宽带数字可变增益放大器 | RMZ | 16 | -40 to 85;型号: | LMH6401IRMZR |
厂家: | TEXAS INSTRUMENTS |
描述: | 4.5GHz 超宽带数字可变增益放大器 | RMZ | 16 | -40 to 85 放大器 |
文件: | 总49页 (文件大小:2458K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
LMH6401 直流至 4.5GHz、全差分数字可变增益放大器
1 特性
3 说明
1
•
3dB 带宽:4.5GHz(26dB 增益时)
增益范围:–6dB 至 26dB(步长为 1dB)
LMH6401 是一款面向直流到射频 (RF)、中频 (IF) 和
高速时域应用的宽带、数控可变增益放大器 (DVGA)。
对于需要自动增益控制 (AGC) 的直流或交流耦合应用
而言,该器件是一款理想的 ADC 驱动器。
•
•
•
•
差分输入阻抗:100Ω
支持共模控制的差分输出
最大增益条件下的失真(VO = 2 VPPD,RL =
200Ω):
该器件对噪声和失真性能进行了优化,以便驱动超宽带
ADC。 放大器在最大增益条件下的噪声系数为 8dB,
在 1GHz 满量程信号电平条件下的谐波失真为 -
63dBc。 该器件支持单电源和分离电源供电,以驱动
ADC。 该器件提供了共模参考输入引脚,以便使放大
器输出共模符合 ADC 输入要求。
–
–
–
–
200MHz:HD2 为 –73dBc,HD3 为 –80dBc
500 MHz:HD2 为 –68dBc,HD3 为 –72dBc
1 GHz:HD2 为 –63dBc,HD3 为 –63dBc
2 GHz:HD2 为 –58dBc,HD3 为 –54dBc
•
•
输出 IP3:
该器件通过 SPI™ 接口执行增益控制,并且支持 32dB
的增益范围(–6dB 至 26dB,步长为 1dB)。 此外,
还可以通过外部 PD 引脚或串行外设接口 (SPI) 控制提
供掉电功能。
–
–
–
200MHz 时为 43dBm
1GHz 时为 33dBm
2GHz 时为 27dBm
输出 IP2:
–
–
–
200MHz 时为 67dBm
这一性能水平在 345mW 的低功耗下才能实现。 器件
工作的环境温度范围为 –40°C 至 85°C。
1GHz 时为 60dBm
2GHz 时为 52dBm
器件信息(1)
•
•
•
•
1GHz、RS = 100Ω 时的噪声系数为 8dB
82ps 上升/下降时间脉冲响应
供电电源:5.0V/69mA
器件型号
LMH6401
封装
UQFN (16)
封装尺寸(标称值)
3.00mm x 3.00mm
(1) 要了解所有可用封装,请见数据表末尾的可订购产品附录。
支持单电源和 (±) 分离电源供电:
–
直流和交流耦合应用
谐波失真与频率间的关系 (VO = 2 VPPD
)
0
•
•
采用先进的互补 BiCMOS 工艺制成
HD2
HD3
-10
3mm × 3mm 超薄四方扁平无引线 (UQFN)-16 封装
-20
-30
-40
2 应用
-50
-60
•
•
•
•
•
•
测试和测量
-70
超宽带模数转换器 (ADC) 驱动器
通信接收器
-80
-90
-100
-110
10
射频 (RF) 采样子系统
表面声波 (SAW) 滤波缓冲器和驱动器
国防设备和雷达
100
1000 2000
D038
Frequency (MHz)
IF 采样接收器应用
LMH6401
1-dB Attenuator Steps
0 dB to 32 dB
Zin ~ 100
10
INP
OUTP
Ultra-
Wideband
ADC
Av =
26 dB
RF
INM
OUTM
10
PD
CS
SCLK
SDI
VOCM
LO
SPI
SDO
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
English Data Sheet: SBOS730
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
目录
1
2
3
4
5
6
7
特性.......................................................................... 1
应用.......................................................................... 1
说明.......................................................................... 1
修订历史记录 ........................................................... 2
Device Options....................................................... 3
Pin Configuration and Functions......................... 4
Specifications......................................................... 5
7.1 Absolute Maximum Ratings ...................................... 5
7.2 ESD Ratings.............................................................. 5
7.3 Recommended Operating Conditions....................... 5
7.4 Thermal Information.................................................. 5
7.5 Electrical Characteristics........................................... 6
7.6 SPI Timing Requirements ......................................... 8
7.7 Typical Characteristics.............................................. 9
Parameter Measurement Information ................ 16
8.1 Setup Diagrams ...................................................... 16
8.2 Output Measurement Reference Points.................. 17
8.3 ATE Testing and DC Measurements ...................... 17
8.4 Frequency Response ............................................. 17
8.5 Distortion................................................................. 17
8.6 Noise Figure............................................................ 18
9
Detailed Description ............................................ 19
9.1 Overview ................................................................. 19
9.2 Functional Block Diagram ....................................... 19
9.3 Feature Description................................................. 20
9.4 Device Functional Modes........................................ 20
9.5 Programming........................................................... 20
9.6 Register Maps......................................................... 23
10 Application and Implementation........................ 26
10.1 Application Information.......................................... 26
10.2 Typical Application ................................................ 30
10.3 Do's and Don'ts .................................................... 35
11 Power-Supply Recommendations ..................... 36
11.1 Single-Supply Operation ....................................... 36
11.2 Split-Supply Operation .......................................... 36
12 Layout................................................................... 37
12.1 Layout Guidelines ................................................. 37
12.2 Layout Examples................................................... 38
13 器件和文档支持 ..................................................... 39
13.1 文档支持................................................................ 39
13.2 社区资源................................................................ 39
13.3 商标....................................................................... 39
13.4 静电放电警告......................................................... 39
13.5 术语表 ................................................................... 39
14 机械、封装和可订购信息....................................... 40
8
8.7 Pulse Response, Slew Rate, and Overdrive Recovery
................................................................................. 18
8.8 Power Down............................................................ 18
8.9 VOCM Frequency Response .................................. 18
4 修订历史记录
Changes from Original (April 2015) to Revision A
Page
•
已发布为量产数据................................................................................................................................................................... 1
2
Copyright © 2015, Texas Instruments Incorporated
LMH6401
www.ti.com.cn
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
5 Device Options
Table 1. FDA Device Companion
DEVICE
LMH5401
LMH3401
LMH6554
BW (AV = 12 dB)
6.2 GHz
DISTORTION
NOISE
–75-dBc HD2, –75-dBc HD3 at 500 MHz
–79-dBc HD2, –77-dBc HD3 at 500 MHz
–79-dBc HD2, –70-dBc HD3 at 250 MHz
1.25 nV/√Hz
1.4 nV/√Hz
0.9 nV/√Hz
7 GHz, G = 16 dB
1.6 GHz
Table 2. DVGA Device Comparison
DEVICE
LMH6517
LMH6521
LMH6881
MAX GAIN, BW
22 dB, 1.2 GHz
26 dB, 1.2 GHz
26 dB, 2.4 GHz
DISTORTION
NOISE FIGURE
43-dBm OIP3 at 200 MHz, –74-dBc HD3 at 200 MHz
49-dBm OIP3 at 200 MHz, –84-dBc HD3 at 200 MHz
42-dBm OIP3 at 200 MHz, –76-dBc HD3 at 200 MHz
5.5 dB
7.3 dB
9.7 dB
Copyright © 2015, Texas Instruments Incorporated
3
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
6 Pin Configuration and Functions
RMZ Package
UQFN-16
Top View
VS-
16
CS
15
SCLK
14
VS+
13
1-dB Attenuator Steps
0 dB to 32 dB
GND
1
SDI
INP
12
11
10
10 ꢀ
OUTP
OUTM
2
3
Av = 26 dB
INM
10 ꢀ
SDO
4
GND
9
5
6
7
8
VS-
PD
VOCM
VS+
Pin Functions
PIN
NAME
FUNCTION
DESCRIPTION
NO.
1
2
3
4
5
SDI
INP
Input
Input
Serial interface input data
Positive input pin
INM
SDO
VS–
Input
Negative input pin
Output
Power
Serial interface output data
Negative supply voltage
Power-down pin.
6
PD
Input
0 = amplifier enabled, 1 = amplifier disabled
7
8
9
VOCM
VS+
Input
Power
Power
Output
Output
Power
Power
Input
Input pin to set amplifier output common-mode voltage
Positive supply voltage
Ground
GND
OUTM
OUTP
GND
VS+
10
11
12
13
14
15
16
Negative output pin
Positive output pin
Ground
Positive supply voltage
Serial interface clock
Chip select
SCLK
CS
Input
VS–
Power
Negative supply voltage
4
Copyright © 2015, Texas Instruments Incorporated
LMH6401
www.ti.com.cn
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
–0.3
VS–
MAX
5.5
UNIT
V
Supply voltage
V = (VS+) – (VS–)
Digital input pins
VS+
2.1
V
Maximum input difference voltage
Maximum input voltage
V
VS+
150
125
85
V
Maximum junction, TJ
°C
°C
°C
°C
Maximum junction, continuous operation, long-term reliability
Temperature
Operating free-air, TA
Storage, Tstg
–40
–65
150
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
7.2 ESD Ratings
VALUE
±2000
±1000
UNIT
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
Charged-device model (CDM), per JEDEC specification JESD22-C101(2)
V(ESD)
Electrostatic discharge
V
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
7.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
4.0
NOM
MAX
UNIT
Supply voltage
5.0
5.25
V
V
Minimum operating positive (VS+) supply voltage
Ambient operating air temperature, TA
Operating junction temperature, TJ
2.0
–40
–40
25
85
°C
°C
125
7.4 Thermal Information
LMH6401
THERMAL METRIC(1)
RMZ (UQFN)
UNIT
16 PINS
78
RθJA
Junction-to-ambient thermal resistance
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
RθJC(top)
RθJB
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
43
24
ψJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
2.3
ψJB
24
RθJC(bot)
n/a
(1) For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
Copyright © 2015, Texas Instruments Incorporated
5
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
7.5 Electrical Characteristics
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted.
TEST
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LEVEL(1)
DYNAMIC PERFORMANCE
SSBW
LSBW
Small-signal, –3-dB bandwidth
AV = 26 dB, VO = 200 mVPPD
AV = 26 dB, VO = 2.0 VPPD
AV = 26 dB, VO = 2.0 VPPD
VO = 2-V step
4.5
4.5
GHz
GHz
MHz
V/µs
ps
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
Large-signal, –3-dB bandwidth
Bandwidth for 0.1-dB flatness
Slew rate
500
18200
82
SR
tR, tF
Rise and fall time
VO = 2-V step, 10% to 90%
Overdrive = ±0.5 V
Overdrive recovery
Output balance error
Settling time to 1%
600
–47
700
–73
–68
–63
–58
–80
–72
–63
–54
67
ps
f = 1 GHz
dB
ts
VO = 2-V step, RL= 200 Ω
f = 200 MHz, VO = 2.0 VPPD
f = 500 MHz, VO = 2.0 VPPD
f = 1 GHz, VO = 2.0 VPPD
ps
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBm
dBm
dBm
dBm
dBm
dBm
dBm
dBm
HD2
Second-harmonic distortion
Third-harmonic distortion
f = 2 GHz, VO = 2.0 VPPD
f = 200 MHz, VO = 2.0 VPPD
f = 500 MHz, VO = 2.0 VPPD
f = 1 GHz, VO = 2.0 VPPD
HD3
OIP2
OIP3
f = 2 GHz, VO = 2.0 VPPD
f = 200 MHz, PO = –2 dBm per tone
f = 500 MHz, PO = –2 dBm per tone
f = 1 GHz, PO = –2 dBm per tone
f = 2 GHz, PO = –2 dBm per tone
f = 200 MHz, PO = –2 dBm per tone
f = 500 MHz, PO = –2 dBm per tone
f = 1 GHz, PO = –2 dBm per tone
f = 2 GHz, PO = –2 dBm per tone
65
Output second-order intercept point
Output third-order intercept point
60
52
43
40
33
27
Second-order intermodulation
distortion
IMD2
IMD3
P1dB
f = 500 MHz, VO = 1.0 VPP per tone
f = 500 MHz, VO = 1.0 VPP per tone
–68
–83
dBc
dBc
dBm
C
C
C
Third-order intermodulation
distortion
f = 500 MHz, power measured at amplifier
output
1-dB compression point
Noise figure
18.3
f = 200 MHz
7.7
8
dB
dB
C
C
C
C
C
NF
RS = 100 Ω
f = 1 GHz
Output-referred noise voltage
Reverse transmission (S12)
Input return loss (S11)
AV = 26 dB, f > 1 MHz
f = 1 GHz
30.4
–65
–15
nV/√Hz
dB
S12
S11
100-Ω system, f = 2 GHz
dB
GAIN PARAMETERS
Maximum voltage gain
25.5
–7.5
26.0
–6.0
32
26.5
–4.5
dB
dB
dB
dB
A
A
C
A
Minimum voltage gain
Gain range
Gain step size
0.9
1
1.1
0.5
AV = 26 dB to 10 dB
(referenced to 26-dB gain)
–0.5
dB
A
Cumulative gain error
AV = 26 dB to –6 dB
(referenced to 26-dB gain)
–1
1
dB
ns
A
C
Gain step transition time
1
(1) Test levels: (A) 100% DC tested at 25°C unless otherwise specified. Over-temperature limits by characterization and simulation. (B)
Limits set by bench verification and simulation. (C) Typical value only for information.
6
Copyright © 2015, Texas Instruments Incorporated
LMH6401
www.ti.com.cn
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
Electrical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted.
TEST
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LEVEL(1)
ANALOG INPUT CHARACTERISTICS
Ri
Input resistance
Differential
Differential
85
100
0.8
112
0.3
Ω
pF
V
A
C
A
Ci
Input capacitance
VICM
Input common-mode voltage
Self-biased to mid-supply
Differential gain shift < 1 dB
–0.3
Low-level input common-mode
voltage range
VICLR
VICHR
(VS–) + 1.5
(VS+) – 1.5
V
V
C
C
High-level input common-mode
voltage range
Differential gain shift < 1 dB
ANALOG OUTPUT CHARACTERISTICS
Ro
Output resistance
Differential
18
(VS+) – 1.1
38.4
20
25
Ω
V
A
A
A
C
A
VOL
Low-level output voltage range
High-level output voltage range
Maximum output voltage swing
Common-mode rejection ratio
Low-level clipping level
High-level clipping level
Differential
(VS–) + 1 (VS–) + 1.1
VOH
VOM
CMRR
(VS+) – 1
6.0
V
VPPD
dB
±0.3-V input common-mode shift
45
POWER SUPPLY
VS
Supply voltage [V = (VS+) – (VS–)]
4.0
2.0
5.0
5.25
V
V
A
A
Minimum positive (VS+) supply
voltage
VS–, measured at 1-kHz sine-wave
VS+, measured at 1-kHz sine-wave
PD = 0 (device enabled)
66
66
60
1
70
70
69
7
dB
dB
A
A
A
A
PSRR
IQ
Power-supply rejection ratio
Quiescent current
78
12
mA
mA
PD = 1 (device disabled)
OUTPUT COMMON-MODE CONTROL (VOCM Pin)
SSBW
Small-signal bandwidth
VOCM voltage range low
VOCM voltage range high
Output offset voltage
VOCM gain
VOCM = 200 mVPP
VOCM gain < 2%
VOCM gain < 2%
All gain settings
160
MHz
V
C
A
A
A
C
A
–0.5
–40
–10
1
0.5
40
V
VOO
mV
V
1.0
VOCM
Common-mode offset voltage
VOCM pin driven to GND
10
mV
POWER DOWN (PD Pin)
Power-down quiescent current
7
80
70
10
12
mA
µA
ns
A
A
C
C
PD bias current
Turn-on time delay
PD = 2.5 V
100
Time to VO = 90% of final value
Time to VO = 10% of original value
Turn-off time delay
ns
DIGITAL INPUT/OUTPUT
VIH
VIL
High-level input voltage
Low-level input voltage
High-level output voltage
Low-level output voltage
Referred to GND
Referred to GND
1 kΩ to GND
1.2
1.4
VS+
0.8
V
V
V
V
A
A
A
A
VOH
VOL
1 kΩ to GND
0.4
Copyright © 2015, Texas Instruments Incorporated
7
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
7.6 SPI Timing Requirements(1)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Limits set by bench verification and simulation.
MIN
NOM
MAX
UNIT
MHz
ns
fs_c
tPH
SCLK frequency
SCLK pulse duration, high
SCLK pulse duration, low
SDI setup
50
10
10
3
tPL
ns
tSU
ns
tH
SDO hold
3
ns
tIZ
SDO tri-state
3
5
3
3
ns
tODZ
tOZD
tOD
tCSS
tCSH
tIAG
SDO driven to tri-state(2)
SDO tri-state to driven
SDO output delay(2)
CS setup(3)
ns
ns
ns
3
3
ns
CS hold
ns
Inter-access gap
20
ns
(1) Ensured by design.
(2) Reference to negative edge of SCLK.
(3) Reference to positive edge of SCLK.
8
Copyright © 2015, Texas Instruments Incorporated
LMH6401
www.ti.com.cn
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
7.7 Typical Characteristics
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
30
25
20
15
10
5
30
29
28
27
26
25
24
MaxGain
-40°C
25°C
85°C
0
-5
-10
10
100
1000
10000 24000
10
100
1000
10000
Frequency (MHz)
Frequency (MHz)
D013
D021
Figure 1. Voltage Gain vs Frequency (1-dB Gain Steps)
Figure 2. Maximum Gain vs Temperature
40
0
-5
200 MHz
500 MHz
1000 MHz
2000 MHz
20
0
-10
-15
-20
-25
-30
-35
-40
-20
-40
-60
Sdd21
Sdd12
Sdd11
Sdd22
-80
-100
50
100
1000
10000
-6
-2
2
6
10
14
18
22
26
Frequency (MHz)
Voltage Gain (dB)
D027
D042
Figure 3. S-Parameters vs Frequency
Figure 4. Input Return Loss vs Gain Settings
10
0
50
45
40
35
30
25
20
-10
-20
-30
-40
No Cap
1 pF
2.4pF
4.7pF
10pF
Gain = 26dB
Gain = 18dB
Gain = 10dB
Gain = 2dB
10
100
1000
10000
10
100
1000 2000
Frequency (MHz)
Frequency (MHz)
D024
D018
PO = –2 dBm per tone
Figure 5. Frequency Response vs Capacitive Load
Figure 6. Output IP3 vs Frequency and Gain Settings
Copyright © 2015, Texas Instruments Incorporated
9
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
50
45
40
35
30
25
20
44
42
40
38
36
34
-40°C
25°C
85°C
4.0 V
5.0 V
5.25 V
10
100
1000 2000
-45
-25
-5
15
35
55
75
90
Frequency (MHz)
Temperature (°C)
D019
D020
PO = –2 dBm per tone
f = 500 MHz, PO = –2 dBm per tone
Figure 7. Output IP3 vs Frequency and Temperature
Figure 8. Output IP3 vs Supply Voltage and Temperature
-10
60
55
50
45
40
35
30
25
20
15
IMD2
IMD3
200 MHz
500 MHz
1000 MHz
2000 MHz
-20
-30
-40
-50
-60
-70
-80
-90
-100
10
-2 -1
0
1
2
3
4
5
6
7
8
9
10
100
1000 2000
Total Output Power per tone (dBm)
Frequency (MHz)
D022
D023
PO = –2 dBm per tone
Figure 9. Output IP3 vs Total Output Power per Tone
Figure 10. Intermodulation Distortion vs Frequency
0
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
Gain = 26dB
Gain = 14dB
Gain = 2dB
Gain = -6dB
Gain = 26dB
Gain = 14dB
Gain = 2dB
Gain = -6dB
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
10
100
1000 2000
10
100
1000 2000
Frequency (MHz)
Frequency (MHz)
D003
D004
Figure 11. Second-Order Harmonic Distortion vs Frequency
Figure 12. Third-Order Harmonic Distortion vs Frequency
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Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-40°C
25°C
85°C
-40°C
25°C
85°C
10
100
1000 2000
10
100
1000 2000
Frequency (MHz)
Frequency (MHz)
D005
D006
Figure 13. Second-Order Harmonic Distortion vs Frequency
Figure 14. Third-Order Harmonic Distortion vs Frequency
-30
0
HD2
HD3
HD2
HD3
-10
-40
-20
-30
-40
-50
-60
-70
-80
-90
-50
-60
-70
-80
-90
-6 -4 -2
0
2
4
6
8
10 12 14 16 18 20 22 24 26
1
2
3
4
5
Voltage Gain (dB)
Differential Output Voltage Swing (V)
D001
D002
f = 500 MHz
f = 500 MHz
Figure 15. Harmonic Distortion vs Gain Settings
Figure 16. Harmonic Distortion vs Differential VPP
-20
-30
-40
-50
-60
-70
-80
-90
-20
-30
-40
-50
-60
-70
-80
-90
Gain = 26dB
Gain = 14dB
Gain = 2dB
Gain = 26dB
Gain = 14dB
Gain = 2dB
-45
-25
-5
15
35
55
75
90
-45
-25
-5
15
35
55
75
90
Temperature (°C)
Temperature (°C)
D009
D010
f = 500 MHz
f = 500 MHz
Figure 17. Second-Order Harmonic Distortion vs
Temperature
Figure 18. Third-Order Harmonic Distortion vs
Temperature
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Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
-20
-30
-40
-50
-60
-70
-80
-20
-30
-40
-50
-60
-70
-80
Gain = 26dB
Gain = 14dB
Gain = 2dB
Gain = 26dB
Gain = 14dB
Gain = 2dB
-45
-25
-5
15
35
55
75
90
-45
-25
-5
15
35
55
75
90
Temperature (°C)
Temperature (°C)
D007
D008
f = 500 MHz, (VS+) – (VS–) = 4 V
f = 500 MHz, (VS+) – (VS–) = 4 V
Figure 19. Second-Order Harmonic Distortion vs
Temperature
Figure 20. Third-Order Harmonic Distortion vs
Temperature
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
HD2
HD3
HD2
HD3
-1.5
-1
-0.5
0
0.5
1
1.5
-1.5
-1
-0.5
0
0.5
1
1.5
Output Common Mode Control (V)
Input Common Mode Control (V)
D011
D012
f = 500 MHz
f = 500 MHz, gain = –6 dB
Figure 21. Harmonic Distortion vs
Output Common-Mode Voltage
Figure 22. Harmonic Distortion vs Input CM Voltage
24
22
20
18
16
14
12
24
22
20
18
16
14
12
4.0 V
5.0 V
5.25 V
4.0 V
5.0 V
5.25 V
10
100
1000 2000
-45
-25
-5
15
35
55
75
90
Frequency (MHz)
Temperature (°C)
D039
D040
Figure 23. Output P1dB vs Frequency
Figure 24. Output P1dB vs Temperature
12
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Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
14
12
10
8
40
35
30
25
20
15
10
5
-40°C
25°C
85°C
50 MHz
500 MHz
1000 MHz
2000 MHz
6
4
10
100
1000 2000
-6
-2
2
6
10
14
18
22
26
Frequency (MHz)
Voltage Gain (dB)
D014
D015
Figure 25. Noise Figure vs Frequency
Figure 26. Noise Figure vs Gain Settings
0
0
-10
-20
-30
-40
-50
-60
-70
-80
-10
-20
-30
-40
-50
10
100
Frequency (MHz)
1000
5000
10
100
Frequency (MHz)
1000
5000
D025
D026
Scc21 / Sdd21
Sdc21/Sdd21
Figure 27. CMRR vs Frequency
Figure 28. Output Balance Error vs Frequency
0.22
4
1.4
4.2
Vin
Vout
Vin
Vout
1.2
1
3.6
3
0.8
0.6
0.4
0.2
0
2.4
1.8
1.2
0.6
0
0.11
0
2
0
-0.2
-0.4
-0.6
-0.8
-1
-0.6
-1.2
-1.8
-2.4
-3
-0.11
-0.22
-2
-1.2
-1.4
-3.6
-4.2
-4
Time (1 nsec/div)
Time (1 nsec/div)
D029
D030
Figure 29. Overdrive Recovery (AV = 26 dB)
Figure 30. Overdrive Recovery (AV = 10 dB)
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Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
250
200
150
100
50
0.4
0.3
0.2
0.1
0
16
12
8
R
jX
|Z|
4
0
-0.1
-0.2
-0.3
-0.4
-4
-8
-12
-16
0
Gain error
Phase error
-50
-6 -4 -2
0
2
4
6
8
10 12 14 16 18 20 22 24 26
10
100
Frequency (MHz)
1000
5000
Voltage Gain (dB)
D043
D016
f = 500 MHz
Figure 31. Cumulative Gain and Phase Step Error vs
Gain Settings
Figure 32. Input Impedance vs Frequency
120
90
85
80
75
70
65
60
55
R
jX
|Z|
4.0 V
5.0 V
5.25 V
100
80
60
40
20
0
-20
-40
10
100
Frequency (MHz)
1000
5000
-45
-25
-5
15
35
55
75
90
Temperature (°C)
D017
D041
Figure 33. Output Impedance vs Frequency
Figure 34. Supply Current vs Temperature
0.3
3
2.5
2.4
Vin
Output
2VppOut
4VppOut
PowerDown Pin
2
1.5
1
2
0.2
0.1
0
2
1.6
1.2
0.8
0.4
0
1
0
0.5
0
-0.1
-0.2
-0.3
-1
-2
-0.5
-1
-3
-0.4
Time (1 nsec/div)
Time (20 nsec/div)
D037
D028
Figure 35. Output Step Response
Figure 36. Power-Down Transition Response
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Typical Characteristics (continued)
At TA = 25°C, VS– = –2.5 V, VS+ = 2.5 V, VOCM = 0 V, RLOAD = 200-Ω differential (Ro(internal, diff) = 20 Ω), VO = 2 VPPD, and AV
= 26 dB, unless otherwise noted. Differential input and output, and input and output pins referenced to mid-supply, unless
otherwise noted. Measured using an EVM as discussed in the Parameter Measurement Information section.
2.5
2.5
2.5
2.5
SCLK
SCLK
Vo(pp)diff
Vo(pp)diff
2
2
2
2
1.5
1
1.5
1
1.5
1
1.5
1
0.5
0
0.5
0
0.5
0
0.5
0
-0.5
-1
-0.5
-1
-0.5
-1
-0.5
-1
Time (5 nsec/div)
Time (5 nsec/div)
D031
D032
Figure 37. Gain Switching Response (AV = 26 dB to 18 dB)
Figure 38. Gain Switching Response (AV = 18 dB to 26 dB)
2.5
2.5
2.5
2.5
SCLK
SCLK
Vo(pp)diff
Vo(pp)diff
2
1.5
1
2
2
1.5
1
2
1.5
1
1.5
1
0.5
0
0.5
0
0.5
0
0.5
0
-0.5
-1
-0.5
-1
-0.5
-1
-0.5
-1
Time (5 nsec/div)
Time (5 nsec/div)
D035
D036
Figure 39. Gain Switching Response (AV = 26 dB to 10 dB)
Figure 40. Gain Switching Response (AV = 10 dB to 26 dB)
2.5
2.5
2.5
2.5
SCLK
SCLK
Vo(pp)diff
Vo(pp)diff
2
1.5
1
2
2
1.5
1
2
1.5
1
1.5
1
0.5
0
0.5
0
0.5
0
0.5
0
-0.5
-1
-0.5
-1
-0.5
-1
-0.5
-1
Time (5 nsec/div)
Time (5 nsec/div)
D033
D034
Figure 41. Gain Switching Response (AV = 26 dB to 2 dB)
Figure 42. Gain Switching Response (AV = 2 dB to 26 dB)
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8 Parameter Measurement Information
8.1 Setup Diagrams
LMH6401EVM
VS+
Vector Network
Vector Network
Analyzer
Analyzer
PD
LMH6401
50 ꢀ
10 ꢀ
50 ꢀ
40 ꢀ
40 ꢀ
Port 1
Port 3
Port 2
INP
INM
OUTP
+
-
+
-
OUT_AMP
10 ꢀ
OUT_LOAD
Port 4
OUTM
VOCM
50 ꢀ
50 ꢀ
Test Equipment
Test Equipment
with 50-ꢀ,QSXWV, Outputs
with 50-ꢀ,QSXWV, Outputs
SPI
VS-
GND
USB
Figure 43. Frequency Response Differential Test Setup
LMH6401EVM
VS+
PD
LMH6401
2:1, ZO = 50 ꢀ
ZO = 50 , 1:2
6-dB Pads
10 ꢀ
40 ꢀ
40 ꢀ
INP
INM
OUTP
0º
0º
50 ꢀ
50 ꢀ
+
-
DC Block
6-dB Pads
6-dB Pads
OUT_AMP
10 ꢀ
180º
180º
OUTM
VOCM
Signal Generator
with 50-ꢀ2XWSXWV
Spectrum Analyzer
with 50-ꢀ,QSXWV
Band-Pass
Filter
BAL-0010
BAL-0010
SPI
VS-
GND
USB
Figure 44. Single-Tone Harmonic Distortion Test Setup
LMH6401EVM
VS+
50 ꢀ
PD
LMH6401
2:1, ZO = 50 ꢀ
ZO = 50 , 1:2
Signal Generator
with 50-ꢀ2XWSXWV
10 ꢀ
40 ꢀ
40 ꢀ
INP
INM
OUTP
0º
0º
50 ꢀ
6-dB
Attenuation
Pads
+
-
Band-Pass
Filter
BAL-0010
6-dB Pads
OUT_AMP
10 ꢀ
DC Block
180º
180º
OUTM
VOCM
Spectrum Analyzer
with 50-ꢀ,QSXWV
BAL-0010
BAL-0010
50 ꢀ
SPI
VS-
GND
Signal Generator
with 50-ꢀ2XWSXWV
USB
Figure 45. Two-Tone Linearity Test Setup (OIP3, OIP2)
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Setup Diagrams (continued)
LMH6401EVM
VS+
PD
LMH6401
2:1, ZO = 50 ꢀ
ZO = 50 , 1:2
10 ꢀ
40 ꢀ
40 ꢀ
INP
INM
OUTP
0º
0º
50 ꢀ
50 ꢀ
+
-
346B
Noise Source
+
-
OUT_AMP
10 ꢀ
OUT_LOAD
180º
180º
OUTM
VOCM
Agilent E4443A
Agilent E4443A
with 50-ꢀ,QSXWV
with 50-ꢀ2XWSXWV
BAL-0010
BAL-0010
SPI
GND
VS-
USB
Figure 46. Noise Figure Test Setup
8.2 Output Measurement Reference Points
The LMH6401 has two on-chip, 10-Ω output resistors. When matching the output to a 100-Ω load, the evaluation
module (EVM) uses an external 40-Ω resistor on each output leg to complete the output matching. Having on-
chip output resistors creates two potential reference points for measuring the output voltage. The first reference
point is at the internal amplifier output (OUT_AMP), and the second reference point is at the externally-matched
100-Ω load (OUT_LOAD). The measurements in the Electrical Characteristics table and in the Typical
Characteristics section are referred to the (OUT_AMP) reference point unless otherwise specified. The
conversion between reference points is a straightforward correction of 3 dB for power and 6 dB for voltage, as
shown in Equation 1 and Equation 2. The measurements are referenced to OUT_AMP when not specified.
VOUT_LOAD = (VOUT_AMP – 6 dB)
POUT_LOAD = (POUT_AMP – 3 dB)
(1)
(2)
8.3 ATE Testing and DC Measurements
All production testing and dc parameters are measured on automated test equipment capable of dc
measurements only. Some measurements (such as voltage gain) are referenced to the output of the internal
amplifier and do not include losses attributed to the on-chip output resistors. The Electrical Characteristics values
specify these conditions. When the measurement is referred to the amplifier output, the output resistors are not
included in the measurement. If the measurement is referred to the device pins, then the output resistor loss is
included in the measurement.
8.4 Frequency Response
This test is done by running an S-parameter sweep on a 4-port differential network analyzer using the standard
EVM with no baluns; see Figure 43. The inputs and outputs of the EVM are connected to the network analyzer
using 50-Ω coaxial cables with all the ports set to a characteristic impedance (ZO) of 50 Ω.
The frequency response test with capacitive load is done by soldering the capacitor across the LMH6401 output
pins. In this configuration, the on-chip, 10-Ω resistors on each output leg isolate the capacitive load from the
amplifier output pins.
8.5 Distortion
The standard EVM is used for measuring both the single-tone harmonic distortion and two-tone intermodulation
distortion; see Figure 44 and Figure 45, respectively. The distortion is measured with differential input signals to
the LMH6401. In order to interface with single-ended test equipment, external baluns (1:2, ZO = 50 Ω) are
required between the EVM output ports and the test equipment. The Typical Characteristics plots are created
with Marki™ baluns, model number BAL-0010. These baluns are used to combine two single tones in the two-
tone test plots as well as convert the single-ended input to differential output for harmonic distortion tests. The
use of 6-dB attenuator pads on both the inputs and outputs is recommended to provide a balanced match
between the external balun and the EVM.
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8.6 Noise Figure
This test is done by matching the input of the LMH6401 to a 50-Ω noise source using a 1:2 balun (see
Figure 46), with the noise figure being referred to the input impedance (RS = 100 Ω). As noted in Figure 46, an
Agilent E4443A with NF features is used for the testing.
8.7 Pulse Response, Slew Rate, and Overdrive Recovery
For time-domain measurements, the standard EVM is driven through a balun again to convert a single-ended
output from the test equipment to the differential inputs of the LMH6401. The differential outputs are directly
connected to the oscilloscope inputs, with the differential signal response calculated using trace math from the
two separate oscilloscope inputs.
8.8 Power Down
The standard EVM is used for this test by completely removing the shorting block on jumper JPD. A high-speed,
50-Ω pulse generator is used to drive the PD pin, which toggles the output signal on or off depending upon the
PD pin voltage.
8.9 VOCM Frequency Response
The standard EVM is used for this test. A network analyzer is connected to the VOCM input of the EVM and the
EVM outputs are connected to the network analyzer with 50-Ω coaxial cables. The network analyzer analysis
mode is set to single-ended input and differential output, and the output common-mode response is measured
with respect to the single-ended input (Scs21). The input signal frequency is swept with the signal level set for
100 mV (–16 dBm). Note that the common-mode control circuit gain is approximately one.
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9 Detailed Description
9.1 Overview
The LMH6401 is a very high-performance, differential I/O, digitally-controlled variable gain amplifier (DVGA). The
device is optimized for radio frequency (RF), intermediate frequency (IF), or high-speed time-domain applications
with 3-dB bandwidths up to 4.5 GHz. The device is ideal for dc- or ac-coupled applications requiring a variable
gain stage when driving an analog-to-digital converter (ADC).
The LMH6401 is best suited to optimize system linearity and noise performance over the entire gain range in the
RF and IF bands. Operating on a nominal 5-V supply or ±2.5-V split supplies, the device consists of an
attenuator stage followed by a fixed-gain amplifier to provide voltage gain control from –6 dB to 26 dB in 1-dB
steps (as shown in the Functional Block Diagram section) with an overall 32-dB gain range. The variable gain
control for the device is offered through the digital serial peripheral interface (SPI) register. The device has a
unique attenuator ladder architecture providing dynamic range improvements where the overall noise figure (NF)
remains relatively constant for the first 5-dB attenuator steps, with NF degrading proportional to the attenuator
steps on the sixth step. This behavior repeats over the entire gain range; see Figure 26.
The device has a differential input impedance of 100-Ω and is intended to be driven differentially by a matched
100-Ω differential source impedance for the best linearity and noise performance. The LMH6401 has two on-chip,
10-Ω resistors, one on each output (as shown in the Functional Block Diagram section). For most load
conditions, the 10-Ω resistors are only a partial termination. Consequently, external termination resistors are
required in most applications. See Table 11 for common load values and the matching resistors.
The LMH6401 supports a common-mode reference input (VOCM) pin to align the amplifier output common-mode
with the subsequent stage (ADC) input requirements. The output common-mode of the LMH6401 is self-biased
to mid-supply when the VOCM pin is not driven externally. The device can be operated on a power-supply
voltage range of 4.0 V to 5.25 V and supports both single- and split-supply operation. For correct digital
operation, the positive supply must not be below 2 V for ground reference logic. A power-down feature is also
available through the SPI register and the external PD pin.
9.2 Functional Block Diagram
VS+
ZIN ~ 100 ꢀ
INM
10 ꢀ
OUTM
Fixed Gain (AV)
0-dB to 32-dB
Attenuation in 1-dB
Steps
= 26 dB
INP
OUTP
10 ꢀ
Gain
Control
Thermal
POR
Feedback Gain
and Frequency
Control Circuit
CS, SCK, SDI
SDO
SPI Decoder
VS+
VS+
-
VOCM
Error
Amplifier
Power Down
50 Nꢀ
+
VOCM
50 Nꢀ
PD
Buffer
VS-
VS-
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9.3 Feature Description
The LMH6401 includes the following features:
•
•
•
•
•
•
•
Fully-differential amplifier
Digitally-controlled variable gain: –6 dB to 26 dB in 1-dB steps
Output common-mode control
Single- or split-supply operation
Large-signal bandwidth of 4.5 GHz
Usable bandwidth up to 2 GHz
Power-down control
9.4 Device Functional Modes
9.4.1 Power-On Reset (POR)
The LMH6401 has a built-in, power-on reset (POR) that sets the device registers to their default state (see
Table 3) on power-up. Note that the LMH6401 register information is lost each time power is removed. When
power is reapplied, the POR ensures the device enters a default state. Power glitches (of sufficient duration) can
also initiate the POR and return the device to a default state.
9.4.2 Power-Down (PD)
The device supports power-down control using an external power-down (PD) pin or by writing a logic high to bit 6
of SPI register 2h (see the Register Maps section). The external PD is an active high pin. When left floating, the
device defaults to an on condition when the PD pin defaults to logic low as a result of the internal pulldown
resistor. The device PD thresholds are noted in the Electrical Characteristics table. The device consumes
approximately 7 mA in power-down mode. Note that the SPI register contents are preserved in power-down
mode.
9.4.3 Thermal Feedback Control
The LMH6401 has a thermal feedback gain and frequency control feature that allows for improved low-frequency
settling performance. The Thermal Feedback Gain Control and Thermal Feedback Frequency Control registers
set through the SPI control this feature. The default setting is described in Table 3. Graphs are Included in the
Application and Implementation section that illustrate how the thermal feedback gain and frequency control
allows for enhanced performance.
9.4.4 Gain Control
The LMH6401 gain can be controlled from 26-dB gain (0-dB attenuation) to –6-dB gain in 1-dB steps by digitally
programming the SPI register 2h. See the Register Maps section for more details.
9.5 Programming
9.5.1 Details of the Serial Interface
The LMH6401 has a set of internal registers that can be accessed by the serial interface controlled by the CS
(chip select), SCLK (serial interface clock), SDI (serial interface input data), and SDO (serial interface readback
data) pins. Serial input to the device is enabled when CS is low. SDI serial data are latched at every SCLK rising
edge when CS is active (low). Serial data are loaded into the register at every 16th SCLK rising edge when CS is
low. When the word length exceeds a multiple of 16 bits, the excess bits are ignored. Data can be loaded in
multiples of 16-bit words within a single active CS pulse. The first eight bits form the register address and the
remaining eight bits form the register data. The interface can function with SCLK frequencies from 50 MHz down
to very low speeds (of a few Hertz) and also with a non-50% SCLK duty cycle. A summary of the LMH6401 SPI
protocol follows:
•
•
•
•
•
SPI-1.1 compliant interface
SPI register contents protected in power-down
SPI-controlled power-down
Powered from the main VS+ power supply
1.8-V logic compliant
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Programming (continued)
9.5.2 Timing Diagrams
Figure 47 and Figure 48 show timing diagrams for the SPI write and read bus cycles, respectively. Figure 49 and
Figure 50 show timing diagrams for the write and read operations, respectively, of the LMH6401. Figure 51 and
Figure 52 illustrate example SPI stream write and read timing diagrams, respectively. Refer to the Electrical
Characteristics table for SPI timing requirements.
CS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SCLK
SDI
A6
A5
A4
A3
A2
A1
A0
D7
D6
D5
D4
D3
D2
D1
D0
SDO
Figure 47. SPI Write Bus Cycle
CS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SCLK
SDI
A6
A5
A4
A3
A2
A1
A0
D7
D6
D5
D4
D3
D2
D1
D0
SDO
Figure 48. SPI Read Bus Cycle
tPL
tPH
SCLK
tSU
tH
SDI
Valid Data
Figure 49. Write Operation Timing Diagram
tCSH tCSS
tCSH tCSS
CS
1st
15th
8th
Clock
Clock
Clock
SCLK
tOZD
tOD
tODZ
Hi-Z
Valid
Data
Valid
Data
Valid
Data
SDO
SDI
Hi-Z
Valid
Data
Figure 50. Read Operation Timing Diagram
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Programming (continued)
CS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
SCLK
Addr N
D4 D3
Addr N+1
D4 D3
A6
A5
A4
A3
A2
A1
A0
D7
D6
D5
D2
D1
D0
D7
D6
D5
D2
D1
D0
SDI
SDO
Figure 51. SPI Streaming Write Example
CS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
SCLK
Addr N
Addr N+1
A6
A5
A4
A3
A2
A1
A0
SDI
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
SDO
Figure 52. SPI Streaming Read Example
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9.6 Register Maps
Table 3 lists the SPI register map.
Table 3. SPI Register Map
ADDRESS
R/W
REGISTER
DEFAULT (Hex)
(A[6:0])
0
R
Revision ID
Product ID
03h
1
R
00h
2
R/W
R/W
R/W
R/W
R
Gain Control
20h (minimum gain)
3
4
Reserved
8Ch
27h
45h
00h
Thermal feedback gain control
Thermal feedback frequency control
Reserved
5
6-127
9.6.1 Revision ID (address = 0h, Read-Only) [default = 03h]
Figure 53. Revision ID
7
6
5
4
3
2
1
0
Revision ID
R-0b
R-0b
R-0b
R-0b
R-0b
R-0b
R-1b
R-1b
LEGEND: R = Read only; -n = value after reset
Table 4. Revision ID Field Descriptions
Bit
Field
Type
Default
Description
7-0
Revision ID
R
00000011 Revision identification bits.
9.6.2 Product ID (address = 1h, Read-Only) [default = 00h]
Figure 54. Product ID
7
6
5
4
3
2
1
0
Product ID
R-0b
R-0b
R-0b
R-0b
R-0b
R-0b
R-0b
R-0b
LEGEND: R = Read only; -n = value after reset
Table 5. Product ID Field Descriptions
Bit
Field
Type
Default
Description
7-0
Product ID
R
00000000 Product identification bits.
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9.6.3 Gain Control (address = 2h) [default = 20h]
Figure 55. Gain Control
7
6
5
4
3
2
1
0
Reserved
R/W-0b
Power Down
R/W-0b
Gain Control
R/W-1b
R/W-0b
R/W-0b
R/W-0b
R/W-0b
R/W-0b
LEGEND: R/W = Read/Write; -n = value after reset
Table 6. Gain Control Field Description
Bit
Field
Type
Default
Description
7
Reserved
R/W
0
Reserved, always program to 0
0 = Active
1 = Power down
6
Power Down
Gain Control
R/W
R/W
0
5-0
100000
Gain control (see Table 10 for gain settings)
9.6.4 Reserved (address = 3h) [default = 8Ch]
Figure 56. Reserved
7
6
5
4
3
2
1
0
Reserved
R/W-1b
R/W-0b
R/W-0b
R/W-0b
R/W-1b
R/W-1b
R/W-0b
R/W-0b
LEGEND: R/W = Read/Write; -n = value after reset
Table 7. Reserved Field Descriptions
Bit
Field
Type
Default
Description
7-0
Reserved
R/W
10001100 Reserved
9.6.5 Thermal Feedback Gain Control (address = 4h) [default = 27h]
Figure 57. Thermal Feedback Gain Control
7
6
5
4
3
2
1
0
Reserved
R/W-0b
Reserved
R/W-0b
Thermal SD
R/W-1b
Thermal Feedback Gain Control
R/W-0b R/W-1b R/W-1b
R/W-0b
R/W-1b
LEGEND: R/W = Read/Write; -n = value after reset
Table 8. Thermal Feedback Gain Control Field Descriptions
Bit
Field
Type
Default
Description
7-6
Reserved
R/W
00
Reserved, always program to 00
0 = Thermal feedback control enabled
1 = Thermal feedback control disabled
5
Thermal SD
R/W
R/W
1
00000 = Minimum thermal feedback gain (see Figure 61)
11111 = Maximum thermal feedback gain (see Figure 61)
4-0
Thermal Feedback Gain Control
00111
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9.6.6 Thermal Feedback Frequency Control (address = 5h) [default = 45h]
Figure 58. Thermal Feedback Frequency Control
7
6
5
4
3
2
1
0
Reserved
R/W-0b
Reserved
R/W-1b
Reserved
R/W-0b
Thermal Feedback Frequency Control
R/W-0b R/W-1b R/W-0b
R/W-0b
R/W-1b
LEGEND: R/W = Read/Write; -n = value after reset
Table 9. Thermal Feedback Frequency Control Field Descriptions
Bit
Field
Type
Default
Description
7-5
Reserved
R/W
010
Reserved, always program to 010
Thermal Feedback Frequency
Control
00000 = Minimum thermal feedback frequency (see Figure 62)
11111 = Maximum thermal feedback frequency (see Figure 62)
4-0
R/W
00101
Table 10. Gain Control Register Controls
ATTENUATION (dB)
GAIN (dB)
REGISTER SETTING (Address = 02h)
0
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
00h
01h
02h
03h
04h
05h
06h
07h
08h
09h
0Ah
0Bh
0Ch
0Dh
0Eh
0Fh
10h
11h
12h
13h
14h
15h
16h
17h
18h
19h
1Ah
1Bh
1Ch
1Dh
1Eh
1Fh
20h-3Fh
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
8
7
6
5
4
3
2
1
0
–1
–2
–3
–4
–5
–6
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10 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
10.1 Application Information
10.1.1 Analog Input Characteristics
The LMH6401 is a single-channel device with analog input signal pins (INP and INM) that denote the positive
and negative input pins, respectively. The device inputs can be either ac- or dc-coupled. In order to dc-couple the
inputs, care must be taken to ensure the common-mode voltage is set within the input common-mode range of
the device, as described in the Electrical Characteristics table. For optimal linearity and noise performance, TI
recommends setting the input common-mode voltage as close to mid-supply as possible. The LMH6401 device
can be ac-coupled at the inputs using input capacitors that allow the inputs to self-bias close to mid-supply and
isolates the common-mode voltage of the driving circuitry. The LMH6401 inputs must be driven differentially. For
single-ended input source applications, care must be taken to select an appropriate balun or fully-differential
amplifier (such as the LMH3401 or LMH5401) that can convert single-ended signals into differential signals with
minimal distortion.
At maximum gain, the digital attenuator is set to 0-dB attenuation, the input signal is much smaller than the
output, and the maximum output voltage swing is limited by the output stage of the device. At minimum gain,
however, the maximum output voltage swing is limited by the input stage because the output is 6 dB lower than
the inputs. In the minimum gain configuration, the input signal begins to clip against the electrostatic discharge
(ESD) protection diodes before the output reaches maximum swing limits. This clipping is a result of the input
signal being unable to swing below the negative supply voltage and being unable to exceed the positive supply
voltage because of the protection diodes. For linear operation, care must be taken to ensure that the input is kept
within the maximum input voltage ratings, as described in the Absolute Maximum Ratings table. The supply
voltage imposes the limit for the input voltage swing because the input stage self-biases to approximately mid-
rail.
The device input impedance is set by the internal input termination resistors to a nominal value of 100 Ω.
Process variations result in a range of values, as described in the Electrical Characteristics table. The input
impedance is also affected by device parasitic reactance at higher frequencies, thus shifting the impedance away
from a nominal 100 Ω. The LMH6401 exhibits a well-matched, 100-Ω differential input impedance in the usable
bandwidth, achieving a –15-dB input return loss at 2 GHz across the gain settings; see Figure 3. Figure 59
illustrates a Smith chart plot of the LMH6401 differential input impedance referenced to a 100-Ω characteristic
impedance.
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Application Information (continued)
Figure 59. Smith Chart Showing Differential Input Impedance (zO = 100 Ω)
10.1.2 Analog Output Characteristics
The LMH6401, as with most RF amplifiers, has two 10-Ω, on-chip resistors on each output leg to provide
isolation from board parasitics at the output pins; see the Functional Block Diagram section. When designing a
filter between the LMH6401 and the interfacing circuitry (ADC), the filter source impedance must be calculated by
taking into account the two 10-Ω, on-chip resistors. Table 11 shows the calculated external source impedance
values (RO+ and RO–) required for various matched filter loads (RL). An important note is that the filter design
between the LMH6401 and the ADC is not limited to a matched filter, and source impedance values (RO+ and
RO–) can be reduced to achieve higher swing at the filter outputs. Achieving lower loss in the filter source
impedance resistors or higher swing at the filter outputs is often desirable because the amplifier must output
reduced swing to maintain the same full-scale input at the ADC and, thus, better linearity performance. An
example 370-MHz, un-matched, low-pass filter between the LMH6401 and ADS54J60 is illustrated in Figure 64,
with (RO+ and RO–) set to 20 Ω and RL set to 100 Ω.
Table 11. Load Component Values(1)
RO+ AND RO– FOR A MATCHED TOTAL LOAD RESISTANCE AT
LOAD (RL)
50 Ω
TERMINATION
AMPLIFIER OUTPUT
TERMINATION LOSS
15 Ω
100 Ω
200 Ω
400 Ω
800 Ω
2000 Ω
6 dB
6 dB
6 dB
6 dB
6 dB
100 Ω
200 Ω
400 Ω
1 kΩ
40 Ω
90 Ω
190 Ω
490 Ω
(1) The total load includes termination resistors.
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The LMH6401 can be either dc- or ac-coupled at the outputs. For dc-coupled applications, the device provides
an option to control the output common-mode voltage using the VOCM pin. Device performance is optimal when
the output common-mode voltage is within ±0.5 V of mid-supply (see Figure 21) and performance degrades
outside the range when the output swing approaches clipping levels. The LMH6401 can achieve a maximum
output swing of 6 VPPD with the output common-mode voltage centered at mid-supply.
Note that by default, the output common-mode voltage is set to mid-supply before the two 10-Ω, on-chip
resistors; see the Functional Block Diagram section. On a single-supply operation when dc-coupling the device
outputs to an ADC using common-mode, level-shifting resistors, the output common-mode voltage and resistor
values being calculated must include the two internal 10-Ω resistors in the equation. When operating the
LMH6401 on split supplies and dc-coupling the outputs, TI recommends matching the output common-mode
voltage of the LMH6401 with the input common-mode voltage of the ADC. A simple design procedure is to select
the supply voltages (VS+ and VS–) such that the default output common-mode voltage being set is equal to the
input common-mode voltage of the ADC. As illustrated in Figure 66, the supplies of the LMH6401 are selected
such that the default output common-mode voltage is set to mid-supply or 1.23 V, which is within the input
common-mode voltage range of the ADC (1.185 V to 1.265 V).
10.1.2.1 Driving Capacitive Loads
With high-speed signal paths, capacitive loading at the output is highly detrimental to the signal path, as shown
in Figure 60. The device on-chip resistors are included in order to isolate the parasitic capacitance associated
with the package and the printed circuit board (PCB) pads that the device is soldered to. However, designers
must make every effort to reduce parasitic loading on the amplifier output pins. The LMH6401 is stable with most
capacitive loads up to 10 pF; however, bandwidth suffers with capacitive loading on the output.
10
0
-10
-20
No Cap
1 pF
2.4pF
-30
4.7pF
10pF
-40
10
100
1000
10000
Frequency (MHz)
D024
Figure 60. Frequency Response vs Capacitive Load
10.1.3 Thermal Feedback Control
The LMH6401 can be used to optimize long-term settling responses using thermal feedback gain and frequency
control registers. These registers are disabled on power-up and can be enabled by clearing the thermal SD bit;
see the Thermal Feedback Gain Control register. The thermal feedback gain control bits increase the low-
frequency gain and the thermal feedback frequency control bits shift the boost frequency. The thermal feedback
gain and frequency registers both have a range of 32 steps. When the function is enabled, there is a small initial
gain offset to optimize the control range. The thermal feedback off condition is illustrated in the gain control plot
(Figure 61), along with a sweep of gain settings of 0, 4, 8…28, and 31 with a 0 register value representing the
minimum gain setting. The frequency control is illustrated in Figure 62 with the optimal gain setting from the gain
sweep over the values of 0, 4, 8…28, and 31 with a 0 register value representing the minimum frequency boost
setting.
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10.1.3.1 Step Response Optimization using Thermal Feedback Control
The LMH6401 has an adjustable frequency compensation scheme that is designed to dramatically improve the
step response for long-term settling. The structure of the LMH6401 gives the best distortion performance for
signals ranging from dc to 2 GHz over a wide range of gain settings. Thermal heating causes a small change in
gain at low frequencies close to 500 kHz. This change in gain is shown in Figure 61 in the ac response for the
trace labeled Thermal Feedback OFF. The amount of gain change is approximately 0.18 dB at maximum gain.
This gain change resulting from thermal heating leads to approximately 1.7% overshoot that settles over a
relatively long time period. A patent pending technique is added that allows for the reduction of this overshoot to
approximately 0.35%, thus eliminating the long-term settling and still retaining the wide dynamic performance
range. The circuit also corrects for small systematic changes that occur at different gain settings and tracks
temperature changes as well. This low-frequency gain correction is accomplished by the addition of a circuit that
alters the gain at low frequencies to nearly eliminate the variation from low to high frequencies.
The step response optimization circuit is disabled on power-up and can be enabled by clearing bit 5 in the
Thermal Feedback Gain Control register (register 4h). The power-on default setting for thermal gain and
frequency are adjusted for the evaluation board for typical silicon performance. These registers are made
available for customization in the final system because board layout characteristics or other components in the
system can change the required correction needed.
Figure 63 demonstrates the initial step response and the corrected response that corresponds to the default
register values for a typical device on the evaluation board displaying long-term settling correction.
26.2
26.16
26.12
26.08
26.04
26
26.16
26.12
26.08
26.04
26
Max Frequency
Max Gain
25.96
25.92
25.88
25.84
25.8
25.96
25.92
25.88
Min Gain
10
Thermal Feedback OFF
Min Frequency
1
100
1000
10000
100000
1
10
100
1000
10000
100000
Frequency (kHz)
Frequency (kHz)
D047
D048
Figure 61. Thermal Gain Control Sweep (Frequency = 9)
Figure 62. Thermal Frequency Control Sweep (Gain = 10)
1.02
Uncorrected
Corrected
1.015
1.01
1.005
1
0.995
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
Time (usec)
1
D049
Figure 63. Long-Term Settling Response using Thermal Feedback
(Gain = 10, Frequency = 9)
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10.1.4 Thermal Considerations
The LMH6401 is packaged in a space-saving UQFN package that has a thermal coefficient (RθJA) of 78°C/W.
Limit the total power dissipation in order to keep the device junction temperature below 150°C for instantaneous
power and below 125°C for continuous power.
10.2 Typical Application
The LMH6401 is designed and optimized for the highest performance when driving differential input ADCs.
Figure 64 shows a block diagram of the LMH6401 driving an ADC with a fourth-order, low-pass filter. The
primary interface circuit between the amplifier and the ADC is usually an antialiasing filter to suppress high-
frequency harmonics aliasing into the ADC FFT spectrum. The interface circuit also provides a means to bias the
signal to the input common-mode voltage required by the ADC. Filters range from single-order real RC poles to
higher-order RLC filters, depending on the application requirements. Output resistors (RO) in series with the
amplifier outputs isolate the amplifier from any capacitive load presented by the filter.
5 V
Driving Circuit
7.5 nH
18 nH
Ro+ = 20 ꢀ
10 ꢀ
LMH6401
10 ꢀ
5 ꢀ
5 ꢀ
Tx Line, ZO = 50
50 ꢀ
50 ꢀ
2.8 pF ||1.2 Nꢀ
54 ꢀ
54 ꢀ
6.3 pF
ADS41B49
ADS54J60
+
9 pF
2.5 V
VOCM
Ro- = 20 ꢀ
7.5 nH
18 nH
ZIN ~ 100
VOCM
0.01 PF
0.01 PF
Figure 64. The LMH6401 Driving an ADS54J60 with a 370 MHz Fourth-Order Chebyshev Low-Pass Filter
Low distortion and low noise figure, along-with low power dissipation make the LMH6401 an ideal device for use
in front-end radio applications. Figure 65 shows a block diagram of a one-transmit and one-receive (1T/1R) radio
architecture with a digital pre-distortion path, where the LMH6401 can be used as a variable-gain IF amplifier on
both the transmit and receive signal chain.
Receive Path
Demodulator
LMH6401
ADC
LNA
LO1
CLK1
Modulator
LMH6401
DAC
PA
LO2
CLK2
LO3
CLK3
ADC
LMH6401
Demodulator
Transmit Path
Figure 65. 1T/1R with Digital Pre-Distortion Front-End Radio Application
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Typical Application (continued)
10.2.1 Design Requirements
Table 12 shows example design requirements for an amplifier in an oscilloscope front-end application; the
LMH6401 meets these requirements.
Table 12. Example Design Requirements for an Oscilloscope Front-End application
SPECIFICATION
DESIGN REQUIREMENTS
4.0 V to 5.25 V with typically less than a 100-mA current and
split-supply operation supported
Supply voltage and current
Usable input frequency range
Voltage gain and gain range
DC to 2 GHz
26-dB to 10-dB voltage gain with x2 attenuation supported
(ideal 32-dB gain range)
OIP3 (PO= –2 dBm per tone, RL= 200 Ω) and noise figure (RS = 100 Ω) at 1 GHz
Rise and fall time (VO= 2-V step) from 10% to 90%
Settling time to 1% of VO = 2-V step
> 30 dBm and less than 10 dB, respectively.
Less than 100 ps
Less than 1 ns with long-term settling correction required
10.2.2 Detailed Design Procedure
10.2.2.1 Driving ADCs
When the amplifier is driving an ADC, the key points to consider for implementation are the signal-to-noise ratio
(SNR), spurious-free dynamic range (SFDR), and ADC input considerations, as described in this section.
A typical application of the LMH6401 involves driving an ultra-wideband, 12-bit ADC (such as the ADC12J4000),
as shown in Figure 66. The LMH6401 can drive the full Nyquist bandwidth of ADCs with sampling rates up to
4 GSPS. If the front-end bandwidth of the ADC is more than 2 GHz, use a simple noise filter to improve SNR.
Otherwise, the ADC can be connected directly to the amplifier output pins with appropriate matching resistors to
limit the full-scale input of the ADC. Note that the LMH6401 inputs must be driven differentially using a balun or
fully-differential amplifiers (FDAs). For dc-coupled applications, an FDA (such as the LMH3401 or LMH5401) that
can convert a single-ended input to a differential output with low distortion is preferred.
VS+ = 3.73 V
VS+ = 3.73 V
1.23 V
LMH5401
RF
25 ꢀ
RT
RO+ = 40 ꢀ
10 ꢀ
IN
1.5 pF (2)
95 ꢀ
RG
10 ꢀ
10 ꢀ
0 ꢀ
0 ꢀ
-
+
-
ADC12J4000
ADS41B49
LMH6401
+
RG
VOCM
RM
10 ꢀ
RO- = 40 ꢀ
~ 100 ꢀ
RF
25 ꢀ
VOCM
0.01 PF
VS- = -1.27 V
VS- = -1.27 V
Figure 66. DC-Coupled Oscilloscope Front-End Application
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10.2.2.1.1 SNR Considerations
The signal-to-noise ratio (SNR) of the amplifier and filter can be calculated from the amplitude of the signal and
the bandwidth of the filter. The noise from the amplifier is band-limited by the filter with the equivalent brick-wall
filter bandwidth. The amplifier and filter noise can be calculated using Equation 3:
V2
VO
O
SNRAMP+FILTER = 10 × log
= 20 × log
e2
eFILTEROUT
FILTEROUT
where:
•
•
•
•
eFILTEROUT = eNAMPOUT • √ENB,
eNAMPOUT = the output noise density of the LMH6401 (30.4 nV/√Hz) at AV = 26 dB,
ENB = the brick-wall equivalent noise bandwidth of the filter, and
VO = the amplifier output signal.
(3)
For example, with a first-order (N = 1) band-pass or low-pass filter with a 1000-MHz cutoff, ENB is 1.57 • f–3dB
=
1.57 • 1000 MHz = 1570 MHz. For second-order (N = 2) filters, ENB is 1.22 • f–3dB. When the filter order
increases, ENB approaches f–3dB (N = 3 → ENB = 1.15 • f–3dB; N = 4 → ENB = 1.13 • f–3dB). Both VO and
eFILTEROUT are in RMS voltages. For example, with a 2-VPP (0.707 VRMS) output signal and a 1000-MHz first-
order, low-pass filter, the SNR of the amplifier and filter is 55.4 dB with eFILTEROUT = 30.4 nV/√Hz • √1570 MHz =
1204.5 μVRMS
.
The SNR of the amplifier, filter, and ADC sum in RMS fashion, as shown in Equation 4 (SNR values in dB):
-SNRAMP+FILTER
-SNRADC
10
10
SNRSYSTEM = -20 × log
10
+ 10
(4)
This formula shows that if the SNR of the amplifier and filter equals the SNR of the ADC, the combined SNR is
3 dB lower (worse). Thus, for minimal degradation (< 1 dB) on the ADC SNR, the SNR of the amplifier and filter
must be ≥ 10 dB greater than the ADC SNR. The combined SNR calculated in this manner is usually accurate to
within ±1 dB of the actual implementation.
10.2.2.1.2 SFDR Considerations
The SFDR of the amplifier is usually set by the second- or third-harmonic distortion for single-tone inputs, and by
the second-order or third-order intermodulation distortion for two-tone inputs. Harmonics and second-order
intermodulation distortion can be filtered to some degree, but third-order intermodulation spurs cannot be filtered.
The ADC generates the same distortion products as the amplifier, but also generates additional spurs (not
harmonically related to the input signal) as a result of sampling and clock feed through.
When the spurs from the amplifier and filter are known, each individual spur can be directly added to the same
spur from the ADC, as shown in Equation 5, to estimate the combined spur (spur amplitudes in dBc):
-HDxAMP+FILTER
-HDxADC
20
20
HDxSYSTEM = -20 × log
10
+ 10
(5)
This calculation assumes the spurs are in phase, but usually provides a good estimate of the final combined
distortion.
For example, if the spur of the amplifier and filter equals the spur of the ADC, then the combined spur is 6 dB
higher. To minimize the amplifier contribution (< 1 dB) to the overall system distortion, the spur from the amplifier
and filter must be approximately 15 dB lower in amplitude than that of the converter. The combined spur
calculated in this manner is usually accurate to within ±6 dB of the actual implementation; however, higher
variations can be detected as a result of phase shift in the filter, especially in second-order harmonic
performance.
This worst-case spur calculation assumes that the amplifier and filter spur of interest is in phase with the
corresponding spur in the ADC, such that the two spur amplitudes can be added linearly. There are two phase-
shift mechanisms that cause the measured distortion performance of the amplifier-ADC chain to deviate from the
expected performance calculated using Equation 5; one is the common-mode phase shift and other is the
differential phase shift.
32
Copyright © 2015, Texas Instruments Incorporated
LMH6401
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ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
Common-mode phase shift is the phase shift detected equally in both branches of the differential signal path
including the filter. Common-mode phase shift nullifies the basic assumption that the amplifier, filter, and ADC
spur sources are in phase. This phase shift can lead to better performance than predicted when the spurs
become phase shifted, and there is the potential for cancellation when the phase shift reaches 180°. However,
there is a significant challenge in designing an amplifier-ADC interface circuit to take advantage of a common-
mode phase shift for cancellation: the phase characteristics of the ADC spur sources are unknown, thus the
necessary phase shift in the filter and signal path for cancellation is also unknown.
Differential phase shift is the difference in the phase response between the two branches of the differential filter
signal path. Differential phase shift in the filter is a result of mismatched components caused by nominal
tolerances and can severely degrade the even harmonic distortion of the amplifier-ADC chain. This effect has the
same result as mismatched path lengths for the two differential traces, and causes more phase shift in one path
than the other. Ideally, the phase responses over frequency through the two sides of a differential signal path are
identical, such that even harmonics remain optimally out of phase and cancel when the signal is taken
differentially. However, if one side has more phase shift than the other, then the even harmonic cancellation is
not as effective.
Single-order RC filters cause very little differential phase shift with nominal tolerances of 5% or less, but higher-
order LC filters are very sensitive to component mismatch. For instance, a third-order Butterworth band-pass
filter with a 100-MHz center frequency and a 20-MHz bandwidth shows as much as 20° of differential phase
imbalance in a SPICE Monte Carlo analysis with 2% component tolerances. Therefore, although a prototype may
work, production variance is unacceptable. For ac-coupled or dc-coupled applications where a transformer or
balun cannot be used, using first- or second-order filters is recommended to minimize the effect of differential
phase shift.
10.2.2.1.3 ADC Input Common-Mode Voltage Considerations—AC-Coupled Input
When interfacing to an ADC, the input common-mode voltage range of the ADC must be taken into account for
proper operation. In an ac-coupled application between the amplifier and the ADC, the input common-mode
voltage bias of the ADC can be accomplished in different ways. Some ADCs use internal bias networks such that
the analog inputs are automatically biased to the required input common-mode voltage if the inputs are ac-
coupled with capacitors (or if the filter between the amplifier and ADC is a band-pass filter). Other ADCs supply
their required input common-mode voltage from a reference voltage output pin (often termed CM or VCM). With
these ADCs, the ac-coupled input signal can be re-biased to the input common-mode voltage by connecting
resistors from each input to the CM output of the ADC, as shown in Figure 67. AC coupling provides dc common-
mode isolation between the amplifier and the ADC; thus, the output common-mode voltage of the amplifier is a
don’t care for the ADC.
RO
RCM
AIN+
Amp
ADC
CM
AIN-
RCM
RO
Figure 67. Biasing AC-Coupled ADC Inputs Using the ADC CM Output
10.2.2.1.4 ADC Input Common-Mode Voltage Considerations—DC-Coupled Input
DC-coupled applications vary in complexity and requirements, depending on the ADC (a split supply for the CMV
is applicable). One typical requirement is resolving the mismatch between the common-mode voltage of the
driving amplifier and the ADC. Devices such as the ADC12J4000 require a nominal 1.23-V input common-mode,
whereas other devices such as the ADS54J60 require a nominal 2.1-V input common-mode. The simplest
approach when dc-coupling the LMH6401 with the input common-mode voltage of the ADC is to select the
supply voltages (VS+) and (VS–) such that the default output common-mode voltage being set is equal to the
input common-mode voltage of the ADC; see Figure 66. The default common-mode voltage being set can be
controlled externally using the VOCM pin. The device performance is optimal when the output common-mode
voltage is within ±0.5 V of mid-supply and degrades outside the range when the output swing approaches
clipping levels.
Copyright © 2015, Texas Instruments Incorporated
33
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
A second approach is shown in Figure 68 when dc-coupling on a single supply, where a resistor network can be
used to perform the common-mode level shift. This resistor network consists of the amplifier series output
resistors and pullup or pulldown resistors to a reference voltage. This resistor network introduces signal
attenuation that may prevent the use of the full-scale input range of the ADC. ADCs with an input common-mode
closer to the typical 2.5-V output common-mode of the LMH6401 are easier to dc-couple, and require little or no
level shifting.
VREF = GND
LMH6401
+5 V
RP
RO
VADC+
VAMP+
10 ꢀ
10 ꢀ
RIN
C
ADC
ADS41B49
IN
VAMP-
VADC-
RO
RP
GND
VREF = GND
Figure 68. Resistor Network to DC Level-Shift Common-Mode Voltage using VREF as GND
For common-mode analysis of the circuit in Figure 68, assume that VAMP± = VCM and VADC± = VCM (the
specification for the ADC input common-mode voltage). Note that the VAMP± common-mode voltage is set before
the two internal 10-Ω resistors, making these resistors necessary to include in the common-mode level-shift
resistor calculation. VREF is chosen to be a voltage within the system higher than VCM (such as the ADC or
amplifier analog supply) or ground, depending on whether the voltage must be pulled up or down, respectively;
RO is chosen to be a reasonable value, such as 24.9 Ω. With these known values, RP can be found by using
Equation 6:
RP= (10 + RO) × (VADC – VREF) / (VAMP – VADC
)
(6)
Shifting the common-mode voltage with the resistor network comes at the expense of signal attenuation.
Modeling the ADC input as the parallel combination of a resistance (RIN) and capacitance (CIN) using values
taken from the ADC data sheet, the approximate differential input impedance (ZIN) for the ADC can be calculated
at the signal frequency. The effect of CIN on the overall calculation of gain is typically minimal and can be ignored
for simplicity (that is, ZIN = RIN). The ADC input impedance creates a divider with the resistor network; the gain
(attenuation) for this divider can be calculated by Equation 7:
Gain = (2RP || ZIN) / (20 + 2RO + 2RP || ZIN)
(7)
With ADCs that have internal resistors that bias the ADC input to the ADC input common-mode voltage, the
effective RIN is equal to twice the value of the bias resistor. For example, the ADS54J60 has a 0.6-kΩ resistor
tying each input to the ADC VCM; therefore, the effective differential RIN is 1.2 kΩ.
The introduction of the RP resistors also modifies the effective load that must be driven by the amplifier.
Equation 8 shows the effective load created when using the RP resistors.
RL = 20 + 2RO + 2RP || ZIN
(8)
The RP resistors function in parallel to the ADC input such that the effective load (output current) at the amplifier
output is increased. Higher current loads limit the LMH6401 differential output swing.
Using the gain and knowing the full-scale input of the ADC (VADC FS), the required amplitude to drive the ADC
with the network can be calculated using Equation 9:
VADC FS
VAMP PP
=
GAIN
(9)
As with any design, testing is recommended to validate whether the specific design goals are met.
34
Copyright © 2015, Texas Instruments Incorporated
LMH6401
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ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
10.2.3 Application Curves
60
55
50
45
40
35
30
25
20
15
0.3
0.2
0.1
0
3
200 MHz
500 MHz
1000 MHz
2000 MHz
Vin
2VppOut
4VppOut
2
1
0
-0.1
-0.2
-0.3
-1
-2
-3
-2 -1
0
1
2
3
4
5
6
7
8
9
10
Time (1 nsec/div)
Total Output Power per tone (dBm)
D022
D037
Figure 69. Output IP3 vs Total Output Power per Tone
Figure 70. Output Pulse Response
10.3 Do's and Don'ts
10.3.1 Do:
•
•
•
•
•
•
Include a thermal analysis at the beginning of the project.
Use well-terminated transmission lines for all signals.
Maintain symmetrical input and output trace layouts
Use solid metal layers for the power supplies.
Keep signal lines as straight as possible.
Use split supplies where required.
10.3.2 Don't:
•
•
•
•
Use a lower supply voltage than necessary.
Use thin metal traces to supply power.
Forget about the common-mode response of filters and transmission lines.
Rout digital line traces close to the analog signals and supply line traces
Copyright © 2015, Texas Instruments Incorporated
35
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
11 Power-Supply Recommendations
The LMH6401 supports both single- or split-supply operation with a total recommended supply operating range
[(VS+) – (VS–)] from 4.0 V to 5.25 V. Note that supply voltages do not need to be symmetrical when using split
supplies, provided the total supply voltage is within the recommended operating range. Any combination of
positive (VS+) and negative (VS–) supply voltages is acceptable, as long as the minimum positive (VS+) supply
voltage to ground is 2 V, or greater.
Using a single 5-V power supply gives the best balance of performance and power dissipation. If power
dissipation is a critical design parameter, a power supply as low as 4.0 V (±2.0 V) can be used. The input
common-mode and output swing limitations of the device scale with supply voltage. TI recommends studying the
common-mode voltage and output swing limitations (see the Electrical Characteristics table) before deciding to
use a lower supply voltage.
11.1 Single-Supply Operation
The device supports single-ended supply voltages with VS+ connected to a positive voltage from 4.0 V to 5.25 V
and VS– connected to ground reference. When using a single supply, check to make sure the input and output
common-mode voltages are within the operating range of the device. Best performance is achieved when the
input and output common-mode voltages are centered close to mid-supply.
11.2 Split-Supply Operation
Using split supplies provides the most flexibility in system design. To operate on split supplies, apply the positive
supply voltage to VS+, the negative supply voltage to VS–, and the ground reference to GND. Note that supply
voltages do not need to be symmetrical, as long as the minimum positive (VS+) supply voltage to ground is 2 V,
or greater. The split-supply operation is often beneficial when the output common-mode of the device must be
set to a particular voltage. For best performance (see Figure 21 and Figure 22), TI recommends that the power-
supply voltages be symmetrical around the desired output common-mode voltage. The input common-mode
voltage range is much more flexible than the output. For example, if the LMH6401 is used to drive an ADC with a
1.0-V input common mode, then the ideal supply voltages are 3.5 V and –1.5 V with the output common-mode
voltage of the LMH6401 centered at 1.0 V for best linearity and noise performance. The GND pin can then be
connected to the system ground and the PD pin and SPI pins are ground referenced.
TI recommends powering up the device with low-noise, LDO-type regulators. If a switching-type regulator is used
to improve system power efficiency, following the switching-type regulator with a low-noise LDO is recommended
to provide the best possible filtering of the switching noise. An example low-noise switcher and LDO for
generating negative supply voltages are the LMR70503 and TPS72301, respectively. In a system with multiple
devices being powered on from the same voltage regulator, a high possibility of noise being coupled between the
multiple devices exists. Additionally, when operated on a board with high-speed digital signals, isolation must be
provided between the digital signal noise and the LMH6401 supply pins. Therefore, adding additional series
ferrite beads or isolation devices and decoupling capacitors is recommended to filter out any power-supply noise
and improve isolation.
Power-supply decoupling is critical to filter out high-frequency switching noise coupling into the supply pins.
Decoupling the supply pins with low ESL, 0306-size ceramic capacitors of X7R-type 0.01-µF and 2200-pF values
are recommended. In addition to the decoupling capacitors, the supply bypassing can be provided by the PCB,
as illustrated in Layout Guidelines section.
36
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LMH6401
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ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
12 Layout
12.1 Layout Guidelines
When dealing with a device with relatively high gain and bandwidth in excess of 1 GHz, certain board layout
precautions must be taken to ensure stability and optimum performance. TI recommends that the LMH6401
board be multi-layered to improve thermal performance, grounding, and power-supply decoupling. The differential
input and output traces must be symmetrical in order to achieve the best linearity performance.
By sandwiching the power-supply layer between ground layers on either side (with thin dielectric thicknesses),
parasitic capacitance between power and ground functions as a distributed, high-resonance frequency capacitor
to help with power-supply decoupling. The LMH6401 evaluation board includes a total of six layers and the
positive (VS+) and negative (VS–) power planes are sandwiched in the middle with a board stack-up (dielectric
thickness), as shown in Figure 71, to help with supply decoupling. Both VS+ and VS– must be connected to the
internal power planes through multiple vias in the immediate vicinity of the supply pins. In addition, low ESL,
ceramic, 0.01-μF decoupling capacitors to the supplies are placed on the same layer as the device to provide
supply decoupling.
Routing high-frequency signal traces on a PCB requires careful attention to maintain signal integrity. A board
layout software package can simplify the trace thickness design to maintain impedances for controlled
impedance signals. In order to isolate the affect of board parasitic on frequency response, TI recommends
placing the external output matching resistors close to the amplifier output pins. A 0.01-µF bypass capacitor is
also recommended close to the VOCM pins to suppress high-frequency common-mode noise. Refer to the user
guide LMH6401EVM Evaluation Module (SLOU406) for more details on board layout and design.
In order to improve board mechanical reliability, the LMH6401 has square anchor pins on four corners of the
package that must be soldered to the board for mechanical strength.
L1 - Top
L2 - GND
0.0166"
0.005"
L3 ± VS+
0.0482"
L4 ± VS-
0.005"
L5 ± GND
0.0166"
L6 - Bottom
1-oz. copper on all layers,
100-ꢀGLIIHUHQWLDOꢀWUDFHꢀLPSHGDQFHꢀRQꢀWKHꢀWRSꢀOD\HU,
and Rogers 4350 dielectric on the top layer.
Figure 71. Recommended PCB Layer Stack-Up for a Six-Layer Board
Copyright © 2015, Texas Instruments Incorporated
37
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
12.2 Layout Examples
Power connections
with multiple vias to
power planes.
ROUT pads closer to
device output pins.
Symmetrical Output
traces
Symmetrical Input
traces
Supply bypass
capacitor pads.
Stitched GND vias
across signal traces
provide GND shielding.
Figure 72. EVM Top Layer
Figure 73. EVM Second Layer Showing a Solid GND Plane
38
版权 © 2015, Texas Instruments Incorporated
LMH6401
www.ti.com.cn
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
13 器件和文档支持
13.1 文档支持
13.1.1 相关文档ꢀ
相关文档如下:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
《ADS12D1800RF 数据表》,SNAS518
《ADC12J1600 和 ADC12J2700 数据表》,SLAS969
《ADC12J4000 数据表》,SLAS989
《ADS54J40 数据表》,SBAS714
《ADS54J60 数据表》,SBAS706
《LMH3401 数据表》,SBOS695
《LMH5401 数据表》,SBOS710
《LMH6517 数据表》,SNOSB19
《LMH6521 数据表》,SNOSB47
《LMH6554 数据表》,SNOSB30
《LMH6881 数据表》,SNOSC72
《LMR70503 数据表》,SNVS850
《TPS72301 数据表》,SLVS346
《AN-2188 在放大器和 ADC 之间:管理通信系统中的滤波器损耗》,SNOA567
《AN-2235 LMH6517/21/22 和其它高速 IF/RF 反馈放大器的电路板设计》,SNOA869
《LMH6401EVM 评估模块》,SLOU406
13.2 社区资源
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
13.3 商标
E2E is a trademark of Texas Instruments.
Marki is a trademark of Marki Microwave, Inc.
SPI is a trademark of Motorola Mobility LLC.
All other trademarks are the property of their respective owners.
13.4 静电放电警告
ESD 可能会损坏该集成电路。德州仪器 (TI) 建议通过适当的预防措施处理所有集成电路。如果不遵守正确的处理措施和安装程序 ,
可能会损坏集成电路。
ESD 的损坏小至导致微小的性能降级 , 大至整个器件故障。 精密的集成电路可能更容易受到损坏 , 这是因为非常细微的参数更改都可
能会导致器件与其发布的规格不相符。
13.5 术语表
SLYZ022 — TI 术语表。
这份术语表列出并解释术语、首字母缩略词和定义。
版权 © 2015, Texas Instruments Incorporated
39
LMH6401
ZHCSDQ5A –APRIL 2015–REVISED MAY 2015
www.ti.com.cn
14 机械、封装和可订购信息
以下页中包括机械、封装和可订购信息。 这些信息是针对指定器件可提供的最新数据。 这些数据会在无通知且不
对本文档进行修订的情况下发生改变。 欲获得该数据表的浏览器版本,请查阅左侧的导航栏。
40
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Copyright © 2015, 德州仪器半导体技术(上海)有限公司
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
LMH6401IRMZR
LMH6401IRMZT
ACTIVE
ACTIVE
UQFN-HR
UQFN-HR
RMZ
RMZ
16
16
3000 RoHS & Green
250 RoHS & Green
SN
Level-2-260C-1 YEAR
Level-2-260C-1 YEAR
-40 to 85
-40 to 85
MH6401
MH6401
SN
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
24-Jul-2020
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
LMH6401IRMZR
LMH6401IRMZT
UQFN-
HR
RMZ
RMZ
16
16
3000
250
180.0
16.5
3.3
3.3
0.75
8.0
12.0
Q2
UQFN-
HR
180.0
16.5
3.3
3.3
0.75
8.0
12.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
24-Jul-2020
*All dimensions are nominal
Device
Package Type Package Drawing Pins
SPQ
Length (mm) Width (mm) Height (mm)
LMH6401IRMZR
LMH6401IRMZT
UQFN-HR
UQFN-HR
RMZ
RMZ
16
16
3000
250
205.0
205.0
200.0
200.0
30.0
30.0
Pack Materials-Page 2
PACKAGE OUTLINE
RMZ0016A
UQFN - 0.65 mm max height
SCALE 4.000
PLASTIC QUAD FLATPACK - NO LEAD
3.1
2.9
B
A
PIN 1 INDEX AREA
3.1
2.9
C
0.65 MAX
SEATING PLANE
0.08 C
0.05
0.00
2X 1.5
SYMM
(0.15)
TYP
(0.125) TYP
4X ( 0.25)
5
8
4
9
SYMM
2X
1.5
1
12
12X 0.5
0.3
16X
0.2
16
13
0.5
0.3
0.1
C A
C
B
0.6±0.05
0.05
15X
(45 X0.13)
PIN 1 ID
4221506/B 01/2015
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
www.ti.com
EXAMPLE BOARD LAYOUT
RMZ0016A
UQFN - 0.65 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
SYMM
(R0.05) TYP
(0.8)
16
13
4X ( 0.25)
(0.1)
1
12
12X (0.5)
SYMM
(2.8)
(2.5)
16X (0.25)
15X (0.6)
4
9
5
8
(2.5)
(2.8)
LAND PATTERN EXAMPLE
SCALE:20X
0.07 MAX
ALL AROUND
0.07 MIN
ALL AROUND
SOLDER MASK
OPENING
METAL
SOLDER MASK
OPENING
METAL
UNDER
SOLDER MASK
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK DETAILS
NOT TO SCALE
4221506/B 01/2015
NOTES: (continued)
3. For more information, see Texas Instruments literature number SLUA271 (www.ti.com/lit/slua271).
www.ti.com
EXAMPLE STENCIL DESIGN
RMZ0016A
UQFN - 0.65 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
SYMM
(R0.05) TYP
(0.8)
13
16
4X ( 0.25)
(0.1)
1
12
12X (0.5)
SYMM
(2.8)
(2.5)
16X (0.25)
4
9
15X (0.6)
5
8
(2.5)
(2.8)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICKNESS
SCALE:20X
4221506/B 01/2015
NOTES: (continued)
4. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
www.ti.com
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邮寄地址:上海市浦东新区世纪大道 1568 号中建大厦 32 楼,邮政编码:200122
Copyright © 2020 德州仪器半导体技术(上海)有限公司
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