NSC LMH6553SDX

LMH6553
900 MHz Fully Differential Amplifier With Output Limiting
Clamp
General Description
Features
The LMH6553 is a 900 MHz differential amplifier with an integrated adjustable output limiting clamp. The clamp increases system performance and provides transient over-voltage
protection to following stages. The internal clamp feature of
the LMH6553 reduces or eliminates the need for external discrete overload protection networks. When used to drive
ADCs, the amplifier's output clamp allows low voltage ADC
inputs to be protected from being overdriven and damaged by
large input signals appearing at the system input. Fast overdrive recovery of 600 ps ensures the amplifier output rapidly
recovers from a clamping event and quickly resumes to follow
the input signal. The LMH6553 delivers exceptional bandwidth, distortion, and noise performance ideal for driving
ADCs up to 14-bits. The LMH6553 could also be used for automotive, communication, medical, test and measurement,
video, and LIDAR applications.
With external gain set resistors and integrated common mode
feedback, the LMH6553 can be configured as either a differential input to differential output or single ended input to
differential output gain block. The LMH6553 can be AC or DC
coupled at the input which makes it suitable for a wide range
of applications including communication systems and high
speed oscilloscope front ends. The LMH6553 is available in
8-pin PSOP and 8-pin LLP packages, and is part of our
LMH® high speed amplifier family.
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900 MHz −3 dB small signal bandwidth @ AV = 1
670 MHz −3 dB large signal bandwidth @ AV = 1
−79 dB THD @ 20 MHz
−92 dB IMD3 @ fc = 20 MHz
10 ns settling time to 0.1%
600 ps clamp overdrive recovery time
40 mV clamp accuracy with 100% Overdrive
−0.1 mV/°C clamp temperature drift
4.5 to 12 supply voltage operation
Applications
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Differential ADC driver
Video over twisted pair
Differential line driver
Single end to differential converter
High speed differential signaling
IF/RF amplifier
SAW filter buffer/driver
CCD Output Limiting Amplifier
Automotive Safety Applications
Typical Application
Single-Ended Input Differential Output ADC Driver
30043769
LMH® is a registered trademark of National Semiconductor Corporation.
© 2008 National Semiconductor Corporation
300437
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LMH6553 900 MHz Fully Differential Amplifier With Output Limiting Clamp
November 17, 2008
LMH6553
Soldering Information
Infrared or Convection (20 sec)
Wave Soldering (10 sec)
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
ESD Tolerance (Note 5)
Human Body Model
Machine Model
Supply Voltage
Common Mode Input Voltage
Maximum Input Current (pins 1, 2, 7, 8)
Maximum Output Current (pins 4, 5)
Maximum Junction Temperature
Operating Ratings
(Note 1)
Operating Temperature Range
(Note 3)
Storage Temperature Range
Total Supply Voltage
4000V
350V
13.2V
±VS
30 mA
(Note 4)
150°C
VS = ±5V Electrical Characteristics
235°C
260°C
−40°C to +125°C
−65°C to +150°C
4.5V to 12V
Package Thermal Resistance (θJA)
8-Pin PSOP
8-Pin LLP
59°C/W
58°C/W
(Note 2)
Unless otherwise specified, all limits are guaranteed for TA = 25°C, VS = ±5V, AV = 1, VCM = 0V, VCLAMP = 3V, RF = RG = 275Ω,
RL = 200Ω, for single-ended in, differential out. Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
Units
AC Performance (Differential)
SSBW
LSBW
Small Signal −3 dB Bandwidth
(Note 8)
Large Signal −3 dB Bandwidth
VOUT = 0.2 VPP, AV = 1, RL = 1 kΩ
900
VOUT = 0.2 VPP, AV = 1
720
VOUT = 0.2 VPP, AV = 2
680
VOUT = 0.2 VPP, AV = 4
630
VOUT = 0.2 VPP, AV = 8, (RF = 400Ω, RG = 50Ω)
350
VOUT = 2 VPP, AV = 1, RL = 1 kΩ
670
VOUT = 2 VPP, AV = 1
540
VOUT = 2 VPP, AV = 2
530
VOUT = 2 VPP, AV = 4
490
VOUT = 2 VPP, AV = 8, (RF = 400Ω, RG = 50Ω)
350
MHz
MHz
0.1 dB Bandwidth
VOUT = 0.2 VPP, AV = 1
50
MHz
0.5 dB Bandwidth
VOUT = 0.2 VPP, AV = 1
525
MHz
Slew Rate
4V Step, AV = 1
2300
V/μs
Rise/Fall Time, 10%-90%
2V Step
690
ps
0.1% Settling Time
2V Step
10
ns
1.0% Settling Time
2V Step
6
ns
Distortion and Noise Response
HD2
HD3
IMD3
2nd Harmonic Distortion
3rd Harmonic Distortion
3rd-Order Two-Tone
Intermodulation
VOUT = 2 VPP, f = 20 MHz, RL = 800Ω
−79
VOUT = 2 VPP, f = 70 MHz, RL = 800Ω
−78
VOUT = 2 VPP, f = 20 MHz, RL = 800Ω
−90
VOUT = 2 VPP, f = 70 MHz, RL = 800Ω
−71
fc = 20 MHz, , VOUT = 2 VPP Composite,
−92
RL = 200Ω
fc = 150 MHz, , VOUT = 2 VPP Composite,
−76
dBc
dBc
dBc
RL = 200Ω
Input Noise Voltage
f = 100 kHz
1.2
nV/
Input Noise Current
f = 100 kHz
13.6
pA/
Noise Figure (See Figure 5)
50Ω System, AV = 9, 10 MHz
10.3
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2
dB
Parameter
Conditions
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
Units
Input Characteristics
IBI
Input Bias Current (Note 11)
IBoffset
Input Bias Current Differential
(Note 7)
VCM = 0V, VID = 0V, IBoffset = (IB− - IB+)/2
−95
50
95
µA
−18
2.5
18
µA
CMRR
Common Mode Rejection Ratio
(Note 7)
DC, VCM = 0V, VID = 0V
RIN
Input Resistance
Differential
15
Ω
CIN
Input Capacitance
Differential
0.5
pF
CMVR
Input Common Mode Voltage
Range
CMRR > 38 dB
±3.3
±3.6
V
Output Voltage Level (Note 7)
Single-Ended Output
−3.7
±3.78
IOUT
Linear Output Current (Note 7)
VOUT = 0V
±100
±120
mA
ISC
Short Circuit Current
One Output Shorted to Ground VIN = 2V
Single-Ended (Note 6)
±150
mA
82
dBc
Output Performance
+3.7
V
Clamp Performance
VCLAMP
VCLAMP Voltage Range
Continuous Operation (Note 11)
VCM
VCLAMP Peak Voltage
(Note 14)
Default VCLAMP Voltage
VCLAMP Floating
0.92
1.0
1.08
Upper Clamp Level Accuracy
VCLAMP = 2V, VCM = 1.5V, VO = 2V, 100%
Overdrive
−53
−40
+53
Lower Clamp Level Accuracy
VCLAMP = 2V, VCM = 1.5V, VO = 1V, 100%
Overdrive
−30
−8
+30
VIN = 0V, VCLAMP(MIN) = −3.1 V
−200
−175
−0.1
VIN = 0V, VCLAMP(MAX) = +4.5V
150
Clamp Pin Bias Drift
Diff Amp Input Bias Shift
V
VCM +
3.0
Clamp Accuracy Temperature Drift
Clamp Pin Bias Current
VCM +
2.0
Linear to Clamped Operation
Clamp Pin Input Impedance
V
mV
mV/°C
175
µA
0.3
µA/°C
60
µA
30
1
KΩ/pF
Clamp Pin Feedthrough
f = 10 MHz
−60
dB
Clamp Bandwidth
0.5VDC + 40 mVPP, SE VIN = 2V
140
MHz
Clamp Slew Rate
100% Overdrive
64
V/µs
Clamp Overshoot
VIN = 2V Step, AV = 2 V/V, VCLAMP = 0.5V,
VCM = 0V, 100% Overdrive
125
mV
Clamp Overshoot
VIN = 2V Step, AV = 2 V/V, VCLAMP = 2V,
VCM = 1.5V, 100% Overdrive
250
mV
Clamp Overshoot Width
(Note 13)
650
ps
Clamp Overdrive Recovery Time
VIN = 2V Step, AV = 2 V/V, VCLAMP = 0.5V,
VCM = 0V, 50% Output Crossing
600
ps
Linearity Guardband (Note 12)
f = 75 MHz, VOD = 2 VPP, RL = 800, SFDR
Down 3 dB
22
mV
Common Mode Small Signal
Bandwidth
VIN+ = VIN− = 0
220
MHz
Slew Rate
VIN+ = VIN− = 0
Output Common Mode Error
Common Mode, VIN = Float, VCM = 0
Output Common Mode Control Circuit
VOSCM
340
3
−25
1
V/μs
25
mV
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LMH6553
Symbol
LMH6553
Symbol
Parameter
Input Bias Current
Conditions
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
VCM(TYPICAL) = 0, (Note 9)
−8
−3.5
VCM(MIN) = −3.2 V, (Note 9)
−9
−4.5
±3.14
±3.18
V
80
dB
VCM(MAX) = +3.2V, (Note 9)
Voltage Range
CMRR
−2.5
Measure VOD, VID = 0V
Input Resistance
1
µA
2
200
ΔVO,CM/ΔVCM
Gain
Units
0.995
1.00
kΩ
1.008
V/V
Miscellaneous Performance
ZT
Open Loop Transimpedance
Differential
112
dBΩ
PSRR
Power Supply Rejection Ratio
DC, ΔVS = ±1V
87
dB
IS
Supply Current
RL = ∞
VS = ±2.5V Electrical Characteristics
25
29.1
33
37
mA
(Note 2)
Unless otherwise specified, all limits are guaranteed for TA = 25°C, VS = ±2.5V, AV = 1, VCM = 0V, VCLAMP = 2V, RF = RG = 275Ω,
RL = 200Ω, for single-ended in, differential out. Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
Units
AC Performance (Differential)
SSBW
LSBW
Small Signal −3 dB Bandwidth
(Note 8)
Large Signal −3 dB Bandwidth
VOUT = 0.2 VPP, AV = 1, RL = 1 kΩ
875
VOUT = 0.2 VPP, AV = 1
630
VOUT = 0.2 VPP, AV = 2
580
VOUT = 0.2 VPP, AV = 4
540
VOUT = 0.2 VPP, AV = 8 , (RF = 400Ω, RG = 50Ω)
315
VOUT = 2 VPP, AV = 1, RL = 1 kΩ
640
VOUT = 2 VPP, AV = 1
485
VOUT = 2 VPP, AV = 2
435
VOUT = 2 VPP, AV = 4
420
VOUT = 2 VPP, AV = 8, (RF = 400Ω, RG = 50Ω)
405
MHz
MHz
0.1 dB Bandwidth
VOUT = 0.2 VPP, AV = 1
60
MHz
0.5 dB Bandwidth
VOUT = 0.2 VPP, AV = 1
236
MHz
Slew Rate
2V Step, AV = 1
1350
V/μs
Rise/Fall Time, 10%-90%
2V Step
860
ps
0.1% Settling Time
2V Step
10
ns
1.0% Settling Time
2V Step
6
ns
Distortion and Noise Response
HD2
HD3
IMD3
2nd Harmonic Distortion
3rd Harmonic Distortion
3rd-Order Two-Tone
Intermodulation
VOUT = 2 VPP, f = 20 MHz, RL = 800Ω
−80
VOUT = 2 VPP, f = 70 MHz, RL = 800Ω
−72
VOUT = 2 VPP, f = 20 MHz, RL = 800Ω
−78
VOUT = 2 VPP, f = 70 MHz, RL = 800Ω
−66
fc = 20 MHz, VOUT = 2 VPP Composite,
−87
RL = 200Ω
fc = 150 MHz, VOUT = 2 VPP Composite,
−68
dBc
dBc
dBc
RL = 200Ω
Input Noise Voltage
f = 100 kHz
1.1
nV/
Input Noise Current
f = 100 kHz
13.6
pA/
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4
Parameter
Noise Figure (See Figure 5)
Conditions
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
Units
10.3
dB
50Ω System, AV = 9, 10 MHz
Input Characteristics
IBI
Input Bias Current (Note 11)
IBoffset
Input Bias Current Differential
(Note 7)
VCM = 0V, VID = 0V, IBoffset = (IB− - IB+)/2
−90
45
90
µA
−24
2
24
µA
CMRR
Common Mode Rejection Ratio
(Note 7)
DC, VCM = 0V, VID = 0V
80
RIN
Input Resistance
Differential
15
Ω
CIN
Input Capacitance
Differential
0.5
pF
CMVR
Input Common Mode Voltage
Range
CMRR > 38 dB
±1.0
±1.2
V
dBc
Output Performance
Output Voltage Swing (Note 7)
Differential Output
5.32
5.47
VPP
IOUT
Linear Output Current (Note 7)
VOUT = 0V
±75
±95
mA
ISC
Short Circuit Current
One Output Shorted to Ground VIN = 2V
Single-Ended (Note 6)
±140
mA
Clamp Performance
VCLAMP
VCLAMP Voltage Range
Continuous Operation (Note 11)
VCM
VCLAMP Peak Voltage
(Note 14)
Default VCLAMP Voltage
VCLAMP Floating
0.42
0.48
0.54
Upper Clamp Level Accuracy
VIN = 0V, VCLAMP = +0.5V, VCM = 0, VO = +0.5V,
100% Overdrive
−39
−30
+39
Lower Clamp Level Accuracy
VIN = 0V, VCLAMP = +0.5V, VCM = 0, VO = −0.5V,
100% Overdrive
−18
6
+18
−0.1
VIN = 0V, VCLAMP = 1V, VCM = 0
Clamp Pin Bias Drift
Diff Amp Input Bias Shift
V
VCM +
3.0
Clamp Accuracy Temperature Drift
Clamp Pin Bias Current
VCM +
2.0
Linear to Clamped Operation
Clamp Pin Input Impedance
V
mV
mV/°C
23.5
µA
0.3
µA/°C
50
µA
30
1
kΩ/pF
Clamp Pin Feedthrough
f = 10 MHz
−60
dB
Clamp Bandwidth
0.5VDC + 40 mVPP, SE VIN = 2V
125
MHz
Clamp Slew Rate
100% Overdrive
52
V/µs
Clamp Overshoot
VIN = 1V Step, AV = 2 V/V, VCLAMP = 0.5V,
VCM= 0V, 100% Overdrive
105
mV
Clamp Overshoot
VIN = 1V Step, AV= 2 V/V, VCLAMP = 1V,
VCM = 0.5V, 100% Overdrive
105
mV
Clamp Overshoot Width
(Note 13)
650
ps
Clamp Overdrive Recovery Time
VIN = 2V Step, AV = 2 V/V, VCLAMP = 0.5V,
VCM = 0V, 50% Output Crossing
600
ps
Linearity Guardband (Note 12)
f = 75 MHz, VOD = 2 VPP, RL = 800, SFDR
Down 3 dB
40
mV
Common Mode Small Signal
Bandwidth
VIN+ = VIN− = 0
130
MHz
Slew Rate
VIN+ = VIN− = 0
186
V/μs
Output Common Mode Error
Common Mode, VIN = float, VCM = 0
Output Common Mode Control Circuit
VOSCM
5
−20
2
20
mV
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LMH6553
Symbol
LMH6553
Symbol
Parameter
Input Bias Current
Conditions
Units
−3.5
µA
VCM = 0, (Note 9)
Voltage Range
CMRR
Min
Typ
Max
(Note 8) (Note 7) (Note 8)
±0.75
Measure VOD, VID = 0V
Input Resistance
Gain
±0.81
V
84
dB
200
ΔVO,CM/ΔVCM
0.995
1.00
kΩ
1.008
V/V
Miscellaneous Performance
ZT
Open Loop Transimpedance
Differential
105
dBΩ
PSRR
Power Supply Rejection Ratio
DC, ΔVS = ±1V
85
dB
IS
Supply Current
RL = ∞
23
26.5
30
34
mA
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but specific performance is not guaranteed. For guaranteed specifications, see the Electrical Characteristics tables.
Note 2: Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating
of the device such that TJ = TA. No guarantee of parametric performance is indicated in the electrical tables under conditions of internal self-heating where
TJ > TA. See Applications Section for information on temperature de-rating of this device." Min/Max ratings are based on product characterization and simulation.
Individual parameters are tested as noted.
Note 3: The maximum power dissipation is a function of TJ(MAX), θJA. The maximum allowable power dissipation at any ambient temperature is
PD = (TJ(MAX)– TA) / θJA. All numbers apply for packages soldered directly onto a PC Board.
Note 4: The maximum output current (IOUT) is determined by device power dissipation limitations. See the Power Dissipation section of the Application Section
for more details.
Note 5: Human Body Model, applicable std. MIL-STD-883, Method 30157. Machine Model, applicable std. JESD22-A115-A (ESD MM std. of JEDEC). FieldInduced Charge-Device Model, applicable std. JESD22-C101-C (ESD FICDM std. of JEDEC).
Note 6: Short circuit current should be limited in duration to no more than 10 seconds. See the Power Dissipation section of the Application Information for more
details.
Note 7: Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and will
also depend on the application and configuration. The typical values are not tested and are not guaranteed on shipped production material.
Note 8: Limits are 100% production tested at 25°C. Limits over the operating temperature range are guaranteed through correlation using Statistical Quality
Control (SQC) methods.
Note 9: Negative current implies current flowing out of the device.
Note 10: IBI is referred to a differential output offset voltage by the following relationship: VOD(offset) = IBI*2RF
Note 11: Exceeding limits could result in excessive device current.
Note 12: Linearity Guardband is defined for an output sinusoid (f = 75 MHz, VOD = 2 VPP). It is the difference between the VCLAMP level and the peak output voltage
where the SFDR is decreased by 3 dB.
Note 13: Clamp Overshoot Width is the duration of overshoot in a 100% overdrive condition.
Note 14: This parameter is guaranteed by design and/or characterization and is not tested in production. The condition of VCLAMP = 3V is not intended for continuous
operation; continuous operation with VCLAMP = 3V may incur permanent damage to the device.
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LMH6553
Connection Diagrams
8-Pin PSOP
30043708
Top View
8-Pin LLP
30043771
Top View
Ordering Information
Package
Part Number
Package Marking
LMH6553MR
8-Pin PSOP
LMH6553MRE
LMH6553MR
250 Units Tape and Reel
MRA08A
2.5k Units Tape and Reel
LMH6553SD
LMH6553SDE
NSC Drawing
95 Units/Rails
LMH6553MRX
8-Pin LLP
Transport Media
1k Units Tape and Reel
6553
250 Units Tape and Reel
LMH6553SDX
SDA08C
4.5k Units Tape and Reel
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LMH6553
Typical Performance Characteristics VS = ±5V
(TA = 25°C, RF = RG = 275Ω, RL = 200Ω, AV = 1,
for single ended in, differential out, unless specified).
Frequency Response vs. Gain
Frequency Response vs. Gain
30043747
30043734
Frequency Response vs. VOUT
Frequency Response vs. VOUT
30043748
30043716
Frequency Response vs. Supply Voltage (RL = 200Ω)
Frequency Response vs. Supply Voltage (RL = 1 kΩ)
30043763
30043762
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LMH6553
Frequency Response vs. Capacitive Load
Suggested RO vs. Capacitive Load
30043721
30043722
Frequency Response vs. Resistive Load
Frequency Response vs. Resistive Load
30043760
30043759
Frequency Response vs. RF
1 VPP Pulse Response Single-Ended Input
30043726
30043761
9
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LMH6553
2 VPP Pulse Response Single-Ended Input
4 VPP Pulse Response Single-Ended Input
30043725
30043727
Pulse Response with 0% and 100% Overdrive
Pulse Response with 0% and 100% Overdrive
30043775
30043774
Overdrive Recovery with VS = ±5V
Overdrive Recovery with VS = ±2.5V
30043757
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30043758
10
30043724
30043729
Distortion vs. Supply Voltage (fc=20Mhz, RL=800Ω)
Distortion vs. Supply Voltage (fc=75Mhz, RL=800Ω)
30043743
30043737
Distortion vs. VCM (fc=20Mhz, RL=800Ω)
Distortion vs. VCM (fc=75Mhz, RL=800Ω)
30043738
30043767
11
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LMH6553
Distortion vs. Frequency Single-Ended Input (RL=800Ω)
Output Common Mode Pulse Response
LMH6553
Distortion vs. Frequency Single-Ended Input (RL=200Ω)
Distortion vs. Supply Voltage (fc=20Mhz, RL=200Ω)
30043781
30043782
Distortion vs. Supply Voltage (fc=75Mhz, RL=200Ω)
Distortion vs. VCM (fc=20Mhz, RL=200Ω)
30043783
30043784
Distortion vs. VCM (fc=75Mhz, RL=200Ω)
Maximum VOUT vs. IOUT
30043730
30043785
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LMH6553
Minimum VOUT vs. IOUT
Closed Loop Output Impedance
30043717
30043731
Closed Loop Output Impedance
Open Loop Transimpedance
30043718
30043741
Open Loop Transimpedance
PSRR
30043742
30043719
13
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LMH6553
PSRR
CMRR
30043720
30043733
Balance Error
Noise Figure
30043713
30043745
Noise Figure
Differential S-Parameter Magnitude vs. Frequency
30043746
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30043755
14
3rd Order Intermodulation Products vs. VOUT
30043756
30043751
3rd Order Intermodulation Products vs. VOUT
3rd Order Intermodulation Products vs. Center Frequency
30043777
30043752
3rd Order Intermodulation Products vs. Center Frequency 3rd Order Intermodulation Products vs. Center Frequency
30043765
30043778
15
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LMH6553
Differential S-Parameter Phase vs. Frequency
LMH6553
3rd Order Intermodulation Products vs. Center Frequency
30043780
30043779
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3rd Order Intermodulation Products vs. VCLAMP
16
LMH6553
Application Information
The LMH6553, a fully differential current feedback amplifier
with integrated output common mode control and output limiting clamp, is designed to provide protection of following input
stages. The common mode feedback circuit sets the output
common mode voltage independent of the input common
mode, as well as forcing the outputs to be equal in magnitude
and opposite in phase, even when only one of the inputs is
driven as in single ended to differential conversion.
The proprietary current feedback architecture of the
LMH6553 offers gain and bandwidth independence even at
high values of gain, simply with the appropriate choice of
RF1 and RF2. Generally RF1 is set equal to RF2, and RG1 equal
to RG2, so that the gain is set by the ratio RF/RG. Matching of
these resistors greatly affects CMRR, DC offset error, and
output balance. Resistors with 0.1% tolerances are recommended for optimal performance, and the amplifier is internally compensated to operate with optimum gain flatness with
values of RF between 250Ω and 350Ω depending on package
selection, PCB layout, and load resistance.
The output common mode voltage is set by the VCM pin with
a fixed gain of 1 V/V. This pin should be driven by a low
impedance source and should be bypassed to ground with a
0.1 µF ceramic capacitor. Any unwanted signal coupling into
the VCM pin will be passed along to the outputs, reducing the
performance of the amplifier. This pin must not be left floating.
The LMH6553 can be operated with either a single 5V supply
or split +5V and −5V supplies. Operation on a single 5V supply, depending on gain, is limited by the input common mode
range; therefore, AC coupling may be required. For example,
in a DC coupled input application on a single 5V supply, with
a VCM of 1.5V, the input common voltage at a gain of 1 will be
0.75V which is outside the minimum 1.5V to 3.5V input common mode range of the amplifier. The minimum VCM for this
application should be greater than 1.5V depending on output
signal swing. Alternatively, AC coupling of the inputs in this
example results in equal input and output common mode voltages, so a 1.5V input common mode would result. Split
supplies allow much less restricted AC and DC coupled operation with optimum distortion performance.
The LMH6553 has a VCLAMP input which allows control of the
maximum amplifier output swing to prevent overdriving of following stages such as sensitive ADC inputs and also provides
fast recovery from transients that would otherwise saturate
the signal path.
30043770
FIGURE 1. Typical Application
When driven from a differential source, the LMH6553 provides low distortion, excellent balance, and common mode
rejection. This is true provided the resistors RF, RG and RO
are well matched and strict symmetry is observed in board
layout.
30043753
FIGURE 2. Differential S-Parameter Test Circuit
The circuit configuration shown in Figure 2 was used to measure differential S parameters in a 50Ω environment at a gain
of 1 V/V. Refer to the Differential S-Parameter vs. Frequency
plots in the Typical Performance Characteristics section for
measurement results.
SINGLE-ENDED INPUT TO DIFFERENTIAL OUTPUT
OPERATION
In many applications, it is required to drive a differential input
ADC from a single-ended source. Traditionally, transformers
have been used to provide single to differential conversion,
but these are inherently bandpass by nature and cannot be
used for DC coupled applications. The LMH6553 provides
excellent performance as a single-to-differential converter
down to DC. Figure 3 shows a typical application circuit where
an LMH6553 is used to produce a differential signal from a
single ended source.
RECOMMENDED FEEDBACK RESISTOR
The LMH6553 is available in both an 8-pin LLP and PSOP
package. The recommended feedback resistor, RF, for the
LLP package is 275Ω and 325Ω for the PSOP to give a flat
frequency response with minimal peaking.
FULLY DIFFERENTIAL OPERATION
The LMH6553 is ideal for a fully differential configuration. The
circuit shown in Figure 1 is a typical fully differential application circuit as might be used to drive an analog to digital
converter (ADC). In this circuit the closed loop gain
AV = VOUT/ VIN = RF/RG, where the feedback is symmetric.
The series output resistors, RO, are optional and help keep
the amplifier stable when presented with a capacitive load.
Refer to the Driving Capacitive Loads section for details.
17
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LMH6553
30043754
FIGURE 4. Single Ended Input S-Parameter Test Circuit
(50Ω System)
30043710
The circuit shown in Figure 4 was used to measure S-parameters for a single-to-differential configuration. The S-parameter plots in the Typical Performance Curves are taken using
the recommended component values for 0 dB gain.
FIGURE 3. Single-Ended Input with Differential Output
When using the LMH6553 in single-to-differential mode, the
complementary output is forced to a phase inverted replica of
the driven output by the common mode feedback circuit as
opposed to being driven by its own complementary input.
Consequently, as the driven input changes, the common
mode feedback action results in a varying common mode
voltage at the amplifier's inputs, proportional to the driving
signal. Due to the non-ideal common mode rejection of the
amplifier's input stage, a small common mode signal appears
at the outputs which is superimposed on the differential output
signal. The ratio of the change in output common mode voltage to output differential voltage is commonly referred to as
output balance error. The output balance error response of
the LMH6553 over frequency is shown in the Typical Performance Characteristics section.
To match the input impedance of the circuit in Figure 3 to a
specified source resistance, RS, requires that RT || RIN = RS.
The equations governing RIN and AV for single-to-differential
operation are also provided in Figure 3. These equations,
along with the source matching condition, must be solved iteratively to achieve the desired gain with the proper input
termination. Component values for several common gain configurations in a 50Ω environment are given in Table 1.
SINGLE SUPPLY OPERATION
Single supply operation is possible on supplies from 5V to
10V; however, as discussed earlier, AC input coupling is recommended for low supplies due to input common mode limitations. An example of an AC coupled, single supply, singleto-differential circuit is shown in Figure 5. Note that when AC
coupling, both inputs need to be AC coupled irrespective of
single-to-differential or differential-to-differential configuration. For higher supply voltages, DC coupling of the inputs
may be possible provided that the output common mode DC
level is set high enough so that the amplifier's inputs and outputs are within their specified operating ranges.
TABLE 1. Gain Component Values for 50Ω System
LLP Package
Gain
RF
RG
RT
RM
0 dB
275Ω
255Ω
59Ω
26.7Ω
6 dB
275Ω
127Ω
68.1Ω
28.7Ω
12 dB
275Ω
54.9Ω
107Ω
34Ω
30043709
TABLE 2. Gain Component Values for 50Ω System
PSOP Package
Gain
RF
RG
RT
RM
0 dB
325Ω
316Ω
56.2Ω
26.7Ω
6 dB
325Ω
150Ω
66.5Ω
28.7Ω
12 dB
325Ω
68.1Ω
110Ω
34.8Ω
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FIGURE 5. AC Coupled for Single Supply Operation
18
CLAMP OPERATION
The output clamp allows control of the maximum amplifier
output swing to prevent overdriving of following stages such
as sensitive ADC inputs and provide fast recovery from signal
transients that would otherwise saturate the signal path. Figure 6 shows the relationship between VCLAMP and the +OUT
and −OUT outputs. The example circuit shown has a single
ended input and is set for a gain of 2 V/V. For proper operation
VCM < VCLAMP < VCM + 2.0V and the upper single ended output
voltage is limited to the voltage level set at the VCLAMP input.
The output common mode control loop forces the lower single
ended voltage to be limited to 2*VCM - VCLAMP. The maximum
clamped single ended output swing is therefore equal to 2*
(VCLAMP - V CM) and the maximum differential output swing is
therefore equal to 4*(VCLAMP - VCM). In the example of Figure
6 with VCLAMP set to 2V and VCM set to 1.5V, the maximum
single ended output is therefore 1 VPP centered at 1.5V and
the maximum differential output is 2 VPP. This is shown for the
case of a 2 VPP input sine wave which for a gain of 2 V/V in
unclamped operation would provide single ended outputs at
+OUT and -OUT of 2 VPP but is shown being clamp limited to
1 VPP.
30043773
FIGURE 7. Clamp Overdrive Recovery Time
MAXIMUM OUTPUT LEVEL
The maximum unclamped output swing in normal operation
is 4VPP single ended or 8 VPP differential due to the requirement that VCLAMP < VCM + 2.0V. For split supply operation of
+5V and −5V, the maximum output voltage is limited by the
output stage's ability to swing close to either supply
(VOUT < ±3.7V). As shown in Figure 8, if VCLAMP is set > 3.7V,
the amplifier output will saturate at the positive supply before
the clamp can operate and similarly if 2*VCM - VCLAMP < −3.7V,
the amplifier output will saturate at the negative supply.
30043772
FIGURE 6. Clamp Operation
30043776
FIGURE 8. Split Supply VOUT(MAX) and VOUT(MIN) Output
Levels
19
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LMH6553
CLAMP PERFORMANCE
Key clamp performance specifications are listed in the electrical characteristics section. Figure 7 illustrates the clamp
overdrive recovery time which is defined as the difference in
input to output propagation delay due to a step change at the
input for a clamped output versus a normal linear unclamped,
non-saturated output.
SPLIT SUPPLY OPERATION
For optimum performance, split supply operation is recommended using +5V and −5V supplies; however, operation is
possible on split supplies as low as +2.25V and −2.25V and
as high as +6V and −6V. Provided the total supply voltage
does not exceed the 4.5V to 12V operating specification,
asymmetric supply operation is also possible and in some
cases advantageous. For example, if 5V DC coupled operation is required for low power dissipation but the amplifier input
common mode range prevents this operation, it is still possible with split supplies of (V+) and (V−). Where
(V+) - (V−) = 5V and V+ and V− are selected to set the amplifier
input common mode voltage to suit the application.
LMH6553
OUTPUT NOISE PERFORMANCE AND MEASUREMENT
Unlike differential amplifiers based on voltage feedback architectures, noise sources internal to the LMH6553 refer to
the inputs largely as current sources, hence the low input referred voltage noise and relatively higher input referred current noise. The output noise is therefore more strongly
coupled to the value of the feedback resistor and not to the
closed loop gain, as would be the case with a voltage feedback differential amplifier. This allows operation of the
LMH6553 at much higher gain without incurring a substantial
noise performance penalty, simply by choosing a suitable
feedback resistor.
Figure 9 shows a circuit configuration used to measure noise
figure for the LMH6553 in a 50Ω system. An RF value of
275Ω is chosen for the PSOP package to minimize output
noise while simultaneously allowing both high gain (9 V/V)
and proper 50Ω input termination. Refer to the section titled
Single-Ended Input Operation for calculation of resistor and
gain values. Noise figure values at various frequencies are
shown in the plot titled Noise Figure in the Typical Performance Characteristics section.
30043766
FIGURE 10. Driving a 14-bit ADC
Figure 11 shows the SFDR and SNR performance vs. frequency for the LMH6553 and ADC14C105 combination circuit with the ADC input signal level at −1 dBFS. The
ADC14C105 is a single channel 14-bit ADC with maximum
sampling rate of 105 MSPS. The amplifier is configured to
provide a gain of 2 V/V in single to differential mode. An external bandpass filter is inserted in series between the input
signal source and the amplifier to reduce harmonics and noise
from the signal generator. In order to properly match the input
impedance seen at the LMH6553 amplifier inputs, RM is chosen to match ZS || RT for proper input balance.
30043750
FIGURE 9. Noise Figure Circuit Configuration
DRIVING ANALOG TO DIGITAL CONVERTERS
Analog-to-digital converters present challenging load conditions. They typically have high impedance inputs with large
and often variable capacitive components. As well, there are
usually current spikes associated with switched capacitor or
sample and hold circuits. Figure 10 shows the LMH6553 driving the ADC14C105. The amplifier is configured to provide a
gain of 2 V/V in a single-to-differential mode. The LMH6553
common mode voltage is set by the ADC14C105. The 0.1 µF
capacitor, in series with the 49.9Ω resistor, is inserted to
ground across the 68.1Ω resistor to balance the amplifier inputs. The circuit in Figure 10 has a 2nd order lowpass LC filter
formed by the 620 nH inductors along with the 22 pF capacitor
across the differential inputs of the ADC14C105. The filter has
a pole frequency of about 50 MHz. The two 100Ω resistors
serve to isolate the capacitive loading of the ADC from the
amplifier and ensure stability. For switched capacitor input
ADCs, the input capacitance will vary based on the clock cycle, as the ADC switches between the sample and hold mode.
See your particular ADC's datasheet for details.
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30043768
FIGURE 11. LMH6553/ADC14C105 SFDR and SNR
Performance vs. Frequency
The amplifier and ADC should be located as close together
as possible. Both devices require that the filter components
be in close proximity to them. The amplifier needs to have
minimal parasitic loading on it's outputs and the ADC is sensitive to high frequency noise that may couple in on its inputs.
Some high performance ADCs have an input stage that has
a bandwidth of several times its sample rate. The sampling
process results in all input signals presented to the input stage
mixing down into the first Nyquist zone (DC to Fs/2).
The LMH6553 is capable of driving a variety of National Semiconductor Analog-to-Digital Converters. This is shown in Table 3, which offers a list of possible signal path ADC and
amplifier combinations. The use of the LMH6553 to drive an
ADC is determined by the application and the desired sampling process (Nyquist operation, sub-sampling or over-sampling). See application note AN-236 for more details on the
sampling processes and application note AN-1393 'Using
20
DRIVING CAPACITIVE LOADS
As noted previously, capacitive loads should be isolated from
the amplifier outputs with small valued resistors. This is particularly the case when the load has a resistive component
that is 500Ω or higher. A typical ADC has capacitive components of around 10 pF and the resistive component could be
1000Ω or higher. If driving a transmission line, such as 50Ω
coaxial or 100Ω twisted pair, using matching resistors will be
sufficient to isolate any subsequent capacitance. For other
applications see the Suggested ROUT vs. Capacitive Load
charts in the Typical Performance Characteristics section.
TABLE 3. DIFFERENTIAL INPUT ADCs COMPATIBLE
WITH LMH6553 DRIVER
Product Number
Max
Sampling
Rate
(MSPS)
Resolution
Channels
ADC1173
15
8
SINGLE
ADC1175
20
8
SINGLE
ADC08351
42
8
SINGLE
ADC1175-50
50
8
SINGLE
ADC08060
60
8
SINGLE
ADC08L060
60
8
SINGLE
ADC08100
100
8
SINGLE
ADC08200
200
8
SINGLE
ADC08500
500
8
SINGLE
ADC081000
1000
8
SINGLE
ADC08D1000
1000
8
DUAL
ADC10321
20
10
SINGLE
ADC10D020
20
10
DUAL
ADC10030
27
10
SINGLE
ADC10040
40
10
DUAL
ADC10065
65
10
SINGLE
ADC10DL065
65
10
DUAL
ADC10080
80
10
SINGLE
ADC11DL066
66
11
DUAL
ADC11L066
66
11
SINGLE
ADC11C125
125
11
SINGLE
ADC11C170
170
11
SINGLE
ADC12010
10
12
SINGLE
ADC12020
20
12
SINGLE
ADC12040
40
12
SINGLE
ADC12D040
40
12
DUAL
ADC12DL040
40
12
DUAL
ADC12DL065
65
12
DUAL
ADC12DL066
66
12
DUAL
ADC12L063
63
12
SINGLE
ADC12C080
80
12
SINGLE
ADC12DS080
80
12
DUAL
ADC12L080
80
12
SINGLE
ADC12C105
105
12
SINGLE
ADC12DS105
105
12
DUAL
ADC12C170
170
12
SINGLE
ADC14L020
20
14
SINGLE
ADC14L040
40
14
SINGLE
ADC14C080
80
14
SINGLE
ADC14DS080
80
14
DUAL
ADC14C105
105
14
SINGLE
ADC14DS105
105
14
DUAL
ADC14155
155
14
SINGLE
BALANCED CABLE DRIVER
With up to 8 VPP differential output voltage swing and 100 mA
of linear drive current the LMH6553 makes an excellent cable
driver as shown in Figure 12. The LMH6553 is also suitable
for driving differential cables from a single ended source.
30043702
FIGURE 12. Fully Differential Cable Driver
POWER SUPPLY BYPASSING
The LMH6553 requires supply bypassing capacitors as
shown in Figure 13 and Figure 14. The 0.01 µF and 0.1 µF
capacitors should be leadless SMT ceramic capacitors and
should be no more than 3 mm from the supply pins. These
capacitors should be star routed with a dedicated ground return plane or trace for best harmonic distortion performance.
A small capacitor, ~0.01 µF, placed across the supply rails,
and as close to the chip's supply pins as possible, can further
improve HD2 performance. Narrow traces or small vias will
reduce the effectiveness of bypass capacitors. Also shown in
both figures is a capacitor from the VCM and VCLAMP pins to
ground. These inputs are high impedance and can provide a
coupling path into the amplifier for external noise sources,
possibly resulting in loss of dynamic range, degraded CMRR,
degraded balance and higher distortion.
21
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LMH6553
High Speed Differential Amplifiers to Drive ADCs. For more
information regarding a particular ADC, refer to the particular
ADC datasheet for details.
LMH6553
3. Calculate the total RMS power: PT = PAMP + PD.
The maximum power that the LMH6553 package can dissipate at a given temperature can be derived with the following
equation:
PMAX = (150° – TAMB)/ θJA, where TAMB = Ambient temperature
(°C) and θJA = Thermal resistance, from junction to ambient,
for a given package (°C/W). For the PSOP package θJA is
59°C/W; LLP package θJA is 58°C/W.
NOTE: If VCM is not mid-rail, then there will be quiescent current flowing in the feedback network. This current should be
included in the thermal calculations and added into the quiescent power dissipation of the amplifier.
ESD PROTECTION
The LMH6553 is protected against electrostatic discharge
(ESD) on all pins. The LMH6553 will survive 4000V Human
Body model and 350V Machine model events. Under normal
operation the ESD diodes have no effect on circuit performance. The current that flows through the ESD diodes will
either exit the chip through the supply pins or through the device, hence it is possible to power up a chip with a large signal
applied to the input pins.
30043701
FIGURE 13. Split Supply Bypassing Capacitors
BOARD LAYOUT
The LMH6553 is a very high performance amplifier. In order
to get maximum benefit from the differential circuit architecture, board layout and component selection are very critical.
The circuit board should have a low inductance ground plane
and well bypassed wide supply lines. External components
should be leadless surface mount types. The feedback network and output matching resistors should be composed of
short traces and precision resistors (0.1%). The output matching resistors should be placed within 3 or 4 mm of the amplifier
as should the supply bypass capacitors. Refer to the section
titled Power Supply Bypassing for recommendations on bypass circuit layout. Evaluation boards are available free of
charge through the product folder on National’s web site.
By design, the LMH6553 is relatively insensitive to parasitic
capacitance at its inputs. Nonetheless, ground and power
plane metal should be removed from beneath the amplifier
and from beneath RF and RG for best performance at high
frequency.
With any differential signal path, symmetry is very important.
Even small amounts of asymmetry can contribute to distortion
and balance errors.
30043712
FIGURE 14. Single Supply Bypassing Capacitors
POWER DISSIPATION
The LMH6553 is optimized for maximum speed and performance in the small form factor of the standard LLP package.
To ensure maximum output drive and highest performance,
thermal shutdown is not provided. Therefore, it is of utmost
importance to make sure that the TJMAX of 150°C is never exceeded.
Follow these steps to determine the maximum power dissipation for the LMH6553:
1. Calculate the quiescent (no-load) power: PAMP = ICC*
VS, where VS = V+ - V−. (Be sure to include any current
through the feedback network if VCM is not mid-rail.)
2. Calculate the RMS power dissipated in each of the output
stages: PD (rms) = rms ((VS - V+OUT) * I+OUT) + rms ((VS
− V−OUT) * I−OUT) , where VOUT and IOUT are the voltage
and the current measured at the output pins of the
differential amplifier as if they were single ended
amplifiers and VS is the total supply voltage.
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EVALUATION BOARD
National Semiconductor suggests the following evaluation
boards to be used with the LMH6553:
Device
Package
LMH6553MR
LMH6553SD
PSOP
LLP
Evaluation Board
Ordering ID
55160019
LMH6553SDEVAL
These evaluation boards can be shipped when a device sample request is placed with National Semiconductor.
22
LMH6553
Physical Dimensions inches (millimeters) unless otherwise noted
8-Pin PSOP
NS Package Number MRA08A
8-Pin LLP
NS Package Number SDA08C
23
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LMH6553 900 MHz Fully Differential Amplifier With Output Limiting Clamp
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