NSC LMH6624MAX

LMH6624/LMH6626
Single/Dual Ultra Low Noise Wideband Operational
Amplifier
General Description
Features
The LMH6624/LMH6626 offer wide bandwidth (1.5GHz for
single, 1.3GHz for dual) with very low input noise (0.92nV/
, 2.3pA/
) and ultra low dc errors (100µV VOS,
± 0.1µV/˚C drift) providing very precise operational amplifiers
with wide dynamic range. This enables the user to achieve
closed-loop gains of greater than 10, in both inverting and
non-inverting configurations.
The LMH6624 (single) and LMH6626’s (dual) traditional voltage feedback topology provide the following benefits: balanced inputs, low offset voltage and offset current, very low
offset drift, 81dB open loop gain, 95dB common mode rejection ratio, and 88dB power supply rejection ratio.
The LMH6624/LMH6626 operate from ± 2.5V to ± 6V in
dual supply mode and from +5V to +12V in single supply
configuration.
LMH6624 is offered in SOT23-5 and SOIC-8 packages.
The LMH6626 is offered in SOIC-8 and MSOP-8 packages.
VS = ± 6V, TA = 25˚C, AV = 20, (Typical values unless
specified)
n Gain bandwidth (LMH6624)
1.5GHz
n Input voltage noise
0.92nV/
n Input offset voltage (limit over temp)
700uV
n Slew rate
350V/µs
n Slew rate (AV = 10)
400V/µs
n HD2 @ f = 10MHz, RL = 100Ω
−63dBc
n HD3 @ f = 10MHz, RL = 100Ω
−80dBc
± 2.5V to ± 6V
n Supply voltage range (dual supply)
n Supply voltage range (single supply)
+5V to +12V
n Improved replacement for the CLC425
(LMH6624)
n Stable for closed loop |AV| ≥ 10
Applications
n
n
n
n
n
n
n
Instrumentation sense amplifiers
Ultrasound pre-amps
Magnetic tape & disk pre-amps
Wide band active filters
Professional Audio Systems
Opto-electronics
Medical diagnostic systems
Connection Diagrams
5-Pin SOT23
8−Pin SOIC
20058952
20058951
Top View
Top View
© 2003 National Semiconductor Corporation
8−Pin SOIC/MSOP
DS200589
20058961
Top View
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LMH6624/LMH6626 Single/Dual Ultra Low Noise Wideband Operational Amplifier
May 2003
LMH6624/LMH6626
Absolute Maximum Ratings
Wave Soldering (10 sec.)
(Note 1)
Storage Temperature Range
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Machine Model
Operating Temperature Range
(Note 3), (Note 4)
200V (Note 9)
± 1.2V
Supply Voltage (V+ - V−)
13.2V
Voltage at Input pins
−40˚C to +125˚C
Package Thermal Resistance (θJA)(Note 4)
V+ +0.5V, V− −0.5V
Soldering Information
Infrared or Convection (20 sec.)
+150˚C
Operating Ratings (Note 1)
2000V (Note 2)
VIN Differential
−65˚C to +150˚C
Junction Temperature (Note 3), (Note 4)
ESD Tolerance
Human Body Model
260˚C
235˚C
SOIC-8
166˚C/W
SOT23–5
265˚C/W
MSOP-8
235˚C/W
± 2.5V Electrical Characteristics
Unless otherwise specified, all limits guaranteed at TA = 25˚C, V+ = 2.5V, V− = −2.5V, VCM = 0V, AV = +20, RF = 500Ω, RL =
100Ω. Boldface limits apply at the temperature extremes. See (Note 12).
Symbol
Parameter
Conditions
Min
(Note 6)
Typ
(Note 5)
Max
(Note 6)
Units
Dynamic Performance
fCL
SR
−3dB BW
Slew Rate(Note 8)
VO = 400mVPP (LMH6624)
90
VO = 400mVPP (LMH6626)
80
VO = 2VPP, AV = +20 (LMH6624)
300
VO = 2VPP, AV = +20 (LMH6626)
290
VO = 2VPP, AV = +10 (LMH6624)
360
MHz
V/µs
VO = 2VPP, AV = +10 (LMH6626)
340
tr
Rise Time
VO = 400mV Step, 10% to 90%
4.1
ns
tf
Fall Time
VO = 400mV Step, 10% to 90%
4.1
ns
ts
Settling Time 0.1%
VO = 2VPP (Step)
20
ns
Distortion and Noise Response
en
in
HD2
HD3
Input Referred Voltage Noise
Input Referred Current Noise
2nd Harmonic Distortion
3
rd
Harmonic Distortion
f = 1MHz (LMH6624)
0.92
f = 1MHz (LMH6626)
1.0
f = 1MHz (LMH6624)
2.3
f = 1MHz (LMH6626)
1.8
fC = 10MHz, VO = 1VPP, RL 100Ω
−60
dBc
fC = 10MHz, VO = 1VPP, RL 100Ω
−76
dBc
nV/
pA/
Input Characteristics
VOS
Input Offset Voltage
Average Drift (Note 7)
VCM = 0V
IOS
Input Offset Current
VCM = 0V
Average Drift (Note 7)
VCM = 0V
2
Input Bias Current
VCM = 0V
13
Average Drift (Note 7)
VCM = 0V
12
nA/˚C
Input Resistance (Note 10)
Common Mode
6.6
MΩ
Differential Mode
4.6
kΩ
Common Mode
0.9
pF
Differential Mode
2.0
IB
RIN
CIN
CMRR
Input Capacitance (Note 10)
Common Mode Rejection
Ratio
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VCM = 0V
−0.75
−0.95
−0.25
+0.75
+0.95
± 0.25
−1.5
−2.0
−0.05
mV
µV/˚C
+1.5
+2.0
µA
nA/˚C
+20
+25
µA
Input Referred,
VCM = −0.5 to +1.9V
VCM = −0.5 to +1.75V
2
87
85
90
dB
(Continued)
Unless otherwise specified, all limits guaranteed at TA = 25˚C, V+ = 2.5V, V− = −2.5V, VCM = 0V, AV = +20, RF = 500Ω, RL =
100Ω. Boldface limits apply at the temperature extremes. See (Note 12).
Symbol
Parameter
Conditions
Min
(Note 6)
Typ
(Note 5)
(LMH6624)
RL = 100Ω, VO = −1V to +1V
75
70
79
(LMH6626)
RL = 100Ω, VO = −1V to +1V
72
67
79
Max
(Note 6)
Units
Transfer Characteristics
AVOL
Xt
Large Signal Voltage Gain
Crosstalk Rejection
f = 1MHz (LMH6626)
dB
−75
dB
Output Characteristics
VO
Output Swing
± 1.1
± 1.0
± 1.4
± 1.25
RL = 100Ω
No Load
± 1.5
RO
Output Impedance
f ≤ 100KHz
ISC
Output Short Circuit Current
(LMH6624)
Sourcing to Ground
∆VIN = 200mV (Note 3), (Note 11)
90
75
145
(LMH6624)
Sinking to Ground
∆VIN = −200mV (Note 3), (Note 11)
90
75
145
(LMH6626)
Sourcing to Ground
∆VIN = 200mV (Note 3),(Note 11)
60
50
120
(LMH6626)
Sinking to Ground
∆VIN = −200mV (Note 3),(Note 11)
60
50
120
IOUT
Output Current
V
± 1.7
10
(LMH6624)
Sourcing, VO = +0.8V
Sinking, VO = −0.8V
100
(LMH6626)
Sourcing, VO = +0.8V
Sinking, VO = −0.8V
75
mΩ
mA
mA
Power Supply
PSRR
Power Supply Rejection Ratio
VS = ± 2.0V to ± 3.0V
IS
Supply Current (per channel)
No Load
82
80
90
11.4
dB
16
18
mA
± 6V Electrical Characteristics
Unless otherwise specified, all limits guaranteed at TA = 25˚C, V+ = 6V, V− = −6V, VCM = 0V, AV = +20, RF = 500Ω, RL =
100Ω. Boldface limits apply at the temperature extremes. See (Note 12).
Symbol
Parameter
Conditions
Min
(Note 6)
Typ
(Note 5)
Max
(Note 6)
Units
Dynamic Performance
fCL
SR
tr
−3dB BW
Slew Rate (Note 8)
Rise Time
VO = 400mVPP (LMH6624)
95
VO = 400mVPP (LMH6626)
85
VO = 2VPP, AV = +20 (LMH6624)
350
VO = 2VPP, AV = +20 (LMH6626)
320
VO = 2VPP, AV = +10 (LMH6624)
400
VO = 2VPP, AV = +10 (LMH6626)
360
VO = 400mV Step, 10% to 90%
3.7
3
MHz
V/µs
ns
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LMH6624/LMH6626
± 2.5V Electrical Characteristics
LMH6624/LMH6626
± 6V Electrical Characteristics
(Continued)
Unless otherwise specified, all limits guaranteed at TA = 25˚C, V+ = 6V, V− = −6V, VCM = 0V, AV = +20, RF = 500Ω, RL =
100Ω. Boldface limits apply at the temperature extremes. See (Note 12).
Symbol
Parameter
Conditions
Min
(Note 6)
Typ
(Note 5)
Max
(Note 6)
Units
tf
Fall Time
VO = 400mV Step, 10% to 90%
3.7
ns
ts
Settling Time 0.1%
VO = 2VPP (Step)
18
ns
Distortion and Noise Response
en
in
HD2
HD3
Input Referred Voltage Noise
Input Referred Current Noise
2nd Harmonic Distortion
3
rd
Harmonic Distortion
f = 1MHz (LMH6624)
0.92
f = 1MHz (LMH6626)
1.0
f = 1MHz (LMH6624)
2.3
f = 1MHz (LMH6626)
1.8
fC = 10MHz, VO = 1VPP, RL 100Ω
−63
dBc
fC = 10MHz, VO = 1VPP, RL 100Ω
−80
dBc
nV/
pA/
Input Characteristics
VOS
IOS
IB
−0.5
−0.7
± 0.10
Input Offset Voltage
VCM = 0V
+0.5
+0.7
Average Drift (Note 7)
VCM = 0V
Input Offset Current Average
Drift (Note 7)
(LMH6624)
VCM = 0V
−1.1
−2.5
0.05
1.1
2.5
(LMH6626)
VCM = 0V
−2.0
−2.5
0.1
2.0
2.5
± 0.2
VCM = 0V
0.7
Input Bias Current
VCM = 0V
13
mV
µV/˚C
µA
nA/˚C
+20
+25
µA
Average Drift (Note 7)
VCM = 0V
12
nA/˚C
RIN
Input Resistance (Note 10)
Common Mode
6.6
MΩ
Differential Mode
4.6
kΩ
CIN
Input Capacitance (Note 10)
Common Mode
0.9
Differential Mode
2.0
CMRR
Common Mode Rejection
Ratio
pF
Input Referred,
VCM = −4.5 to +5.25V
VCM = −4.5 to +5.0V
90
87
95
(LMH6624)
RL = 100Ω, VO = −3V to +3V
77
72
81
(LMH6626)
RL = 100Ω, VO = −3V to +3V
74
70
80
dB
Transfer Characteristics
AVOL
Xt
Large Signal Voltage Gain
Crosstalk Rejection
f = 1MHz (LMH6626)
−75
dB
dB
Output Characteristics
VO
Output Swing
± 4.4
± 4.3
± 4.8
± 4.65
± 4.3
± 4.2
± 4.8
± 4.65
(LMH6624)
RL = 100Ω
(LMH6624)
No Load
(LMH6626)
RL = 100Ω
(LMH6626)
No Load
RO
Output Impedance
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f ≤ 100KHz
± 4.9
± 5.2
± 4.8
± 5.2
10
4
V
mΩ
(Continued)
Unless otherwise specified, all limits guaranteed at TA = 25˚C, V+ = 6V, V− = −6V, VCM = 0V, AV = +20, RF = 500Ω, RL =
100Ω. Boldface limits apply at the temperature extremes. See (Note 12).
Symbol
Parameter
Output Short Circuit Current
ISC
IOUT
Output Current
Conditions
Min
(Note 6)
Typ
(Note 5)
(LMH6624)
Sourcing to Ground
∆VIN = 200mV (Note 3), (Note 11)
100
85
156
(LMH6624)
Sinking to Ground
∆VIN = −200mV (Note 3), (Note 11)
100
85
156
(LMH6626)
Sourcing to Ground
∆VIN = 200mV (Note 3), (Note 11)
65
55
120
(LMH6626)
Sinking to Ground
∆VIN = −200mV (Note 3), (Note 11)
65
55
120
(LMH6624)
Sourcing, VO = +4.3V
Sinking, VO = −4.3V
100
(LMH6626)
Sourcing, VO = +4.3V
Sinking, VO = −4.3V
80
Max
(Note 6)
Units
mA
mA
Power Supply
PSRR
Power Supply Rejection Ratio
VS = ± 5.4V to ± 6.6V
IS
Supply Current (per channel)
No Load
82
80
88
12
dB
16
18
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 and the test conditions, see the Electrical Characteristics.
Note 2: Human body model, 1.5kΩ in series with 100pF.
Note 3: Applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated ambient temperature can result in exceeding the
maximum allowed junction temperature of 150˚C.
Note 4: The maximum power dissipation is a function of TJ(MAX), θJA, and TA. 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 5: Typical Values represent the most likely parametric norm.
Note 6: All limits are guaranteed by testing or statistical analysis.
Note 7: Average drift is determined by dividing the change in parameter at temperature extremes into the total temperature change.
Note 8: Slew rate is the slowest of the rising and falling slew rates.
Note 9: Machine Model, 0Ω in series with 200pF.
Note 10: Simulation results.
Note 11: Short circuit test is a momentary test. Output short circuit duration is 1.5ms.
Note 12: 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.
Absolute maximum ratings indicate junction temperature limits beyond which the device may be permanently degraded, either mechanically or electrically.
Ordering Information
Package
SOT23-5
Part Number
Package Marking
Transport Media
NSC Drawing
LMH6624MF
A94A
1k Units Tape and Reel
MF05A
LMH6624MFX
SOIC-8
LMH6624MA
3k Units Tape and Reel
LMH6624MA
95 Units/Rail
LMH6624MAX
SOIC-8
LMH6626MA
2.5k Units Tape and Reel
LMH6626MA
95 Units/Rail
LMH6626MAX
MSOP-8
LMH6626MM
M08A
M08A
2.5k Units Tape and Reel
A98A
1k Units Tape and Reel
LMH6626MMX
MUA08A
3.5k Units Tape and Reel
5
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LMH6624/LMH6626
± 6V Electrical Characteristics
LMH6624/LMH6626
Typical Performance Characteristics
Voltage Noise vs. Frequency
Current Noise vs. Frequency
20058962
20058963
Inverting Frequency Response
Inverting Frequency Response
20058989
20058988
Non-Inverting Frequency Response
Non-Inverting Frequency Response
20058904
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20058903
6
(Continued)
Open Loop Frequency Response Over Temperature
Open Loop Frequency Response Over Temperature
20058964
20058966
Frequency Response with Cap. Loading
Frequency Response with Cap. Loading
20058984
20058986
Frequency Response with Cap. Loading
Frequency Response with Cap. Loading
20058987
20058985
7
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LMH6624/LMH6626
Typical Performance Characteristics
LMH6624/LMH6626
Typical Performance Characteristics
(Continued)
Non-Inverting Frequency Response Varying VIN
Non-Inverting Frequency Response Varying VIN
20058906
20058905
Non-Inverting Frequency Response Varying VIN
(LMH6626)
Non-Inverting Frequency Response Varying VIN
(LMH6624)
20058908
20058981
Non-Inverting Frequency Response Varying VIN
(LMH6626)
Non-Inverting Frequency Response Varying VIN
(LMH6624)
20058907
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20058980
8
(Continued)
Sourcing Current vs. VOUT (LMH6624)
Sourcing Current vs. VOUT (LMH6626)
20058957
20058972
Sourcing Current vs. VOUT (LMH6624)
Sourcing Current vs. VOUT (LMH6626)
20058954
20058969
VOS vs. VSUPPLY (LMH6624)
VOS vs. VSUPPLY (LMH6626)
20058967
20058968
9
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LMH6624/LMH6626
Typical Performance Characteristics
LMH6624/LMH6626
Typical Performance Characteristics
(Continued)
Sinking Current vs. VOUT (LMH6624)
Sinking Current vs. VOUT (LMH6626)
20058958
20058971
Sinking Current vs. VOUT (LMH6624)
Sinking Current vs. VOUT (LMH6626)
20058956
20058970
IOS vs. VSUPPLY
Crosstalk Rejection vs. Frequency (LMH6626)
20058979
20058953
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10
LMH6624/LMH6626
Typical Performance Characteristics
(Continued)
Distortion vs. Frequency
Distortion vs. Frequency
20058944
20058946
Distortion vs. Frequency
Distortion vs. Gain
20058945
20058978
Distortion vs. VOUT Peak to Peak
Distortion vs. VOUT Peak to Peak
20058943
20058977
11
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LMH6624/LMH6626
Typical Performance Characteristics
(Continued)
Non-Inverting Large Signal Pulse Response
Non-Inverting Large Signal Pulse Response
20058973
20058974
Non-Inverting Small Signal Pulse Response
Non-Inverting Small Signal Pulse Response
20058975
20058976
PSRR vs. Frequency
PSRR vs. Frequency
20058948
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20058949
12
(Continued)
Input Referred CMRR vs. Frequency
Input Referred CMRR vs. Frequency
20058901
20058902
Amplifier Peaking with Varying RF
Amplifier Peaking with Varying RF
20058982
20058983
13
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LMH6624/LMH6626
Typical Performance Characteristics
LMH6624/LMH6626
Application Section
20058919
20058918
FIGURE 2. Inverting Amplifier Configuration
FIGURE 1. Non-Inverting Amplifier Configuration
TOTAL INPUT NOISE vs. SOURCE RESISTANCE
INTRODUCTION
The LMH6624/LMH6626 are very wide gain bandwidth, ultra
low noise voltage feedback operational amplifiers. Their excellent performances enable applications such as medical
diagnostic ultrasound, magnetic tape & disk storage and
fiber-optics to achieve maximum high frequency signal-tonoise ratios. The set of characteristic plots in the "Typical
Performance" section illustrates many of the performance
trade offs. The following discussion will enable the proper
selection of external components to achieve optimum system performance.
To determine maximum signal-to-noise ratios from the
LMH6624/LMH6626, an understanding of the interaction between the amplifier’s intrinsic noise sources and the noise
arising from its external resistors is necessary.
Figure 3 describes the noise model for the non-inverting
amplifier configuration showing all noise sources. In addition
to the intrinsic input voltage noise (en) and current noise
(in = in+ = in−) source, there is also thermal voltage noise
(et = √(4KTR)) associated with each of the external resistors.
Equation 1 provides the general form for total equivalent
input voltage noise density (eni). Equation 2 is a simplification of Equation 1 that assumes
BIAS CURRENT CANCELLATION
To cancel the bias current errors of the non-inverting configuration, the parallel combination of the gain setting (Rg)
and feedback (Rf) resistors should equal the equivalent
source resistance (Rseq) as defined in Figure 1. Combining
this constraint with the non-inverting gain equation also seen
in Figure 1, allows both Rf and Rg to be determined explicitly
from the following equations:
Rf = AVRseq and Rg = Rf/(AV-1)
When driven from a 0Ω source, such as the output of an op
amp, the non-inverting input of the LMH6624/LMH6626
should be isolated with at least a 25Ω series resistor.
As seen in Figure 2, bias current cancellation is accomplished for the inverting configuration by placing a resistor
(Rb) on the non-inverting input equal in value to the resistance seen by the inverting input (Rf||(Rg+Rs)). Rb should to
be no less than 25Ω for optimum LMH6624/LMH6626 performance. A shunt capacitor can minimize the additional
noise of Rb.
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20058920
FIGURE 3. Non-Inverting Amplifier Noise Model
14
Rf||Rg should be as low as possible to minimize noise.
Results similar to Equation 1 are obtained for the inverting
configuration of Figure 2 if Rseq is replaced by Rb and Rg is
replaced by Rg + Rs. With these substitutions, Equation 1 will
yield an eni referred to the non-inverting input. Referring eni
to the inverting input is easily accomplished by multiplying
eni by the ratio of non-inverting to inverting gains.
(Continued)
(1)
Rf||Rg = Rseq for bias current cancellation. Figure 4 illustrates the equivalent noise model using this assumption.
Figure 5 is a plot of eni against equivalent source resistance
(Rseq) with all of the contributing voltage noise source of
Equation 2. This plot gives the expected eni for a given (Rseq)
which assumes Rf||Rg = Rseq for bias current cancellation.
The total equivalent output voltage noise (eno) is eni*AV.
NOISE FIGURE
Noise Figure (NF) is a measure of the noise degradation
caused by an amplifier.
(3)
The Noise Figure formula is shown in Equation 3. The addition of a terminating resistor RT, reduces the external thermal noise but increases the resulting NF. The NF is increased because RT reduces the input signal amplitude thus
reducing the input SNR.
20058921
FIGURE 4. Noise Model with Rf||Rg = Rseq
(4)
The noise figure is related to the equivalent source resistance (Rseq) and the parallel combination of Rf and Rg. To
minimize noise figure.
• Minimize Rf||Rg
• Choose the Optimum RS (ROPT)
ROPT is the point at which the NF curve reaches a minimum
and is approximated by:
ROPT ≈ en/in
(2)
As seen in Figure 5, eni is dominated by the intrinsic voltage
noise (en) of the amplifier for equivalent source resistances
below 33.5Ω. Between 33.5Ω and 6.43kΩ, eni is dominated
by the thermal noise (et = √(4kT(2Rseq)) of the external
resistor. Above 6.43kΩ, eni is dominated by the amplifier’s
current noise (in = √(2) inRseq). When Rseq = 464Ω (ie.,
en/√(2) in) the contribution from voltage noise and current
noise of LMH6624/LMH6626 is equal.. For example, configured with a gain of +20V/V giving a −3dB of 90MHz and
driven from Rseq = 25Ω, the LMH6624 produces a total
1.57*90MHz) of
equivalent input noise voltage (eni x
16.5µVrms.
NON-INVERTING GAINS LESS THAN 10V/V
Using the LMH6624/LMH6626 at lower non-inverting gains
requires external compensation such as the shunt compensation as shown in Figure 6. The compensation capacitors
are chosen to reduce frequency response peaking to less
than 1dB.
20058924
FIGURE 6. External Shunt Compensation
INVERTING GAINS LESS THAN 10V/V
The lag compensation of Figure 7 will achieve stability for
lower gains. It is best used for the inverting configuration
because of its affect on the non-inverting input impedance.
20058922
FIGURE 5. Voltage Noise Density vs. Source
Resistance
If bias current cancellation is not a requirement, then Rf||Rg
need not equal Rseq. In this case, according to Equation 1,
15
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LMH6624/LMH6626
Application Section
LMH6624/LMH6626
Application Section
(Continued)
20058927
20058925
FIGURE 9. Transimpedance Amplifier Configuration
FIGURE 7. External Lag Compensation
SINGLE SUPPLY OPERATION
The LMH6624/LMH6626 can be operated with single power
supply as shown in Figure 8. Both the input and output are
capacitively coupled to set the DC operating point.
20058928
FIGURE 10. Current Noise Density vs. Feedback
Resistance
20058926
FIGURE 8. Single Supply Operation
LOW NOISE TRANSIMPEDANCE AMPLIFIER
Figure 9 implements a low-noise transimpedance amplifier
commonly used with photo-diodes. The transimpedance
gain is set by Rf. Equation 4 provides the total input current
noise density (ini) equation for the basic transimpedance
configuration and is plotted against feedback resistance (Rf)
showing all contributing noise sources in Figure 10. This plot
indicates the expected total equivalent input current noise
density (ini) for a given feedback resistance (Rf). The total
equivalent output voltage noise density (eno) is ini*Rf.
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(5)
LOW NOISE INTEGRATOR
The LMH6624/LMH6626 implement a deBoo integrator
shown in Figure 11. Positive feedback maintains integration
linearity. The LMH6624/LMH6626’s low input offset voltage
and matched inputs allow bias current cancellation and provide for very precise integration. Keeping RG and RS low
helps maintain dynamic stability.
16
LMH6624/LMH6626
Application Section
(Continued)
20058931
FIGURE 13. Noise Magnetic Media Equalizer
20058929
FIGURE 11. Low Noise Integrator
HIGH-GAIN SALLEN-KEY ACTIVE FILTERS
The LMH6624/LMH6626 are well suited for high gain SallenKey type of active filters. Figure 12 shows the 2nd order
Sallen-Key low pass filter topology. Using component predistortion methods discussed in OA-21 enables the proper
selection of components for these high-frequency filters.
20058932
FIGURE 14. Equalizer Frequency Response
LAYOUT CONSIDERATION
National Semiconductor suggests the copper patterns on the
evaluation boards listed below as a guide for high frequency
layout. These boards are also useful as an aid in device
testing and characterization. As is the case with all highspeed amplifiers, accepted-practice RF design technique on
the PCB layout is mandatory. Generally, a good high frequency layout exhibits a separation of power supply and
ground traces from the inverting input and output pins. Parasitic capacitances between these nodes and ground may
cause frequency response peaking and possible circuit oscillations (see Application Note OA-15 for more information).
Use high quality chip capacitors with values in the range of
1000pF to 0.1F for power supply bypassing. One terminal of
each chip capacitor is connected to the ground plane and the
other terminal is connected to a point that is as close as
possible to each supply pin as allowed by the manufacturer’s
design rules. In addition, connect a tantalum capacitor with a
value between 4.7µF and 10µF in parallel with the chip
capacitor. Signal lines connecting the feedback and gain
resistors should be as short as possible to minimize inductance and microstrip line effect. Place input and output termination resistors as close as possible to the input/output
pins. Traces greater than 1 inch in length should be impedance matched to the corresponding load termination.
20058930
FIGURE 12. Sallen-Key Active Filter Topology
LOW NOISE MAGNETIC MEDIA EQUALIZER
The LMH6624/LMH6626 implement a high-performance low
noise equalizer for such application as magnetic tape channels as shown in Figure 13. The circuit combines an integrator with a bandpass filter to produce the low noise equalization. The circuit’s simulated frequency response is illustrated
in Figure 14.
17
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LMH6624/LMH6626
Application Section
by-product of the board layout and component placement.
Moreover, a large resistor will also add more thermal noise to
the signal path. Either way, keeping the resistor values low
will diminish this interaction. On the other hand, choosing
very low value resistors could load down nodes and will
contribute to higher overall power dissipation and high distortion.
(Continued)
Symmetry between the positive and negative paths in the
layout of differential circuitry should be maintained to minimize the imbalance of amplitude and phase of the differential
signal.
These free evaluation boards are shipped when a device
sample request is placed with National Semiconductor.
Component value selection is another important parameter
in working with high speed/high performance amplifiers.
Choosing external resistors that are large in value compared
to the value of other critical components will affect the closed
loop behavior of the stage because of the interaction of
these resistors with parasitic capacitances. These parasitic
capacitors could either be inherent to the device or be a
www.national.com
18
Device
Package
Evaluation Board Part
Number
LMH6624MF
SOT23–5
CLC730216
LMH6624MA
SOIC-8
CLC730227
LMH6626MA
SOIC-8
CLC730036
LMH6626MM
MSOP-8
CLC730123
LMH6624/LMH6626
Physical Dimensions
inches (millimeters) unless otherwise noted
5-Pin SOT23
NS Package Number MF05A
8-Pin SOIC
NS Package Number M08A
19
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LMH6624/LMH6626 Single/Dual Ultra Low Noise Wideband Operational Amplifier
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
8-Pin MSOP
NS Package Number MUA08A
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