NSC LMH6550MAX

LMH6550
Differential, High Speed Op Amp
General Description
Features
The LMH™6550 is a high performance voltage feedback
differential amplifier. The LMH6550 has the high speed and
low distortion necessary for driving high performance ADCs
as well as the current handling capability to drive signals
over balanced transmission lines like CAT 5 data cables. The
LMH6550 can handle a wide range of video and data formats.
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With external gain set resistors, the LMH6550 can be used
at any desired gain. Gain flexibility coupled with high speed
makes the LMH6550 suitable for use as an IF amplifier in
high performance communications equipment.
Applications
The LMH6550 is available in the space saving SOIC and
MSOP packages.
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400 MHz −3 dB bandwidth (VOUT = 0.5 VPP)
90 MHz 0.1 dB bandwidth
3000 V/µs slew Rate
8 ns settling time to 0.1%
−92/−103 dB HD2/HD3 @ 5 MHz
10 ns shutdown/enable
Differential AD driver
Video over twisted pair
Differential line driver
Single end to differential converter
High speed differential signaling
IF/RF amplifier
SAW filter buffer/driver
Typical Application
20130110
Single Ended Input Differential Output.
Gain = AV=0.5 * RF/RG
LMH™ is a trademark of National Semiconductor Corporation.
© 2006 National Semiconductor Corporation
DS201301
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LMH6550 Differential, High Speed Op Amp
May 2006
LMH6550
Connection Diagram
8-Pin SOIC & MSOP
20130108
Top View
Ordering Information
Package
8-Pin SOIC
8-Pin MSOP
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Part Number
LMH6550MA
LMH6550MAX
LMH6550MM
LMH6550MMX
Package Marking
LMH6550MA
Transport Media
95/Rails
2.5k Units Tape and Reel
1k Units Tape and Reel
AL1A
3.5k Units Tape and Reel
2
NSC Drawing
M08A
MUA08A
Infrared or Convection (20 sec)
235˚C
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Wave Soldering (10 sec)
260˚C
Operating Ratings (Note 1)
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)
Operating Temperature Range
2000V
200V
Storage Temperature Range
13.2V
Total Supply Voltage
−40˚C to +85˚C
−65˚C to +150˚C
4.5V to 12V
Package Thermal Resistance (θJA) (Note 4)
± VS
30 mA
(Note 3)
8-Pin SOIC
150˚C/W
8-Pin MSOP
235˚C/W
Soldering Information
± 5V Electrical Characteristics (Note 2)
Single ended in differential out, TA = 25˚C, AV= +1, VS = ± 5V, VCM = 0V, RF = RG = 365Ω, RL = 500Ω; Unless specified.
Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
AC Performance (Differential)
SSBW
Small Signal −3 dB Bandwidth
VOUT = 0.5 VPP
400
MHz
LSBW
Large Signal −3 dB Bandwidth
VOUT = 2 VPP
380
MHz
Large Signal −3 dB Bandwidth
VOUT = 4 VPP
320
MHz
0.1 dB Bandwidth
VOUT = 0.5 VPP
90
MHz
Slew Rate
4V Step (Note 6)
3000
V/µs
Rise/Fall Time
2V Step
2000
1
ns
Settling Time
2V Step, 0.1%
8
ns
VCM Pin AC Performance (Common Mode Feedback Amplifier)
Common Mode Small Signal
Bandwidth
VCM Bypass Capacitor Removed
210
MHz
Slew Rate
VCM Bypass Capacitor Removed
200
V/µs
VO = 2 VPP, f = 5 MHz, RL = 800Ω
−92
VO = 2 VPP, f = 20 MHz, RL = 800Ω
−78
VO = 2 VPP, f = 70 MHz, RL = 800Ω
−59
VO = 2 VPP, f = 5 MHz, RL = 800Ω
−103
VO = 2 VPP, f = 20 MHz, RL = 800Ω
−88
VO = 2 VPP, f = 70 MHz, RL = 800Ω
−50
Distortion and Noise Response
HD2
HD3
2nd Harmonic Distortion
3rd Harmonic Distortion
dBc
dBc
en
Input Referred Voltage Noise
f ≥ 1 MHz
6.0
nV/
in
Input Referred Noise Current
f ≥ 1 MHz
1.5
pA/
Input Characteristics (Differential)
VOSD
IBI
1
±4
±6
mV
Input Offset Voltage
Differential Mode, VID = 0, VCM = 0
Input Offset Voltage Average
Temperature Drift
(Note 10)
Input Bias Current
(Note 9)
Input Bias Current Average
Temperature Drift
(Note 10)
9.6
nA/˚C
Input Bias Difference
Difference in Bias Currents Between
the Two Inputs
0.3
µA
1.6
0
-8
µV/˚C
−16
µA
CMRR
Common Mode Rejection Ratio
DC, VCM = 0V, VID = 0V
82
dBc
RIN
Input Resistance
Differential
5
MΩ
CIN
Input Capacitance
Differential
1
pF
3
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LMH6550
Absolute Maximum Ratings (Note 1)
LMH6550
± 5V Electrical Characteristics (Note 2)
(Continued)
Single ended in differential out, TA = 25˚C, AV= +1, VS = ± 5V, VCM = 0V, RF = RG = 365Ω, RL = 500Ω; Unless specified.
Boldface limits apply at the temperature extremes.
Symbol
CMVR
Parameter
Input Common Mode Voltage
Range
Conditions
CMRR > 53 dB
Min
(Note 8)
Typ
(Note 7)
+3.1
−4.6
+3.2
−4.7
Max
(Note 8)
Units
V
VCM Pin Input Characteristics (Common Mode Feedback Amplifier)
VOSC
±5
±8
mV
Input Offset Voltage
Common Mode, VID = 0
1
Input Offset Voltage Average
Temperature Drift
(Note 10)
25
µV/˚C
Input Bias Current
(Note 9)
VCM CMRR
VID = 0V, 1V Step on VCM Pin,
Measure VOD
−2
µA
70
75
dB
∆VO,CM/∆VCM
0.995
0.997
Output Voltage Swing
Peak to Peak, Differential
7.38
7.18
7.8
V
Output Common Mode Voltage
Range
VID = 0 V,
± 3.69
± 3.8
V
IOUT
Linear Output Current
VOUT = 0V
± 63
ISC
Short Circuit Current
Output Shorted to Ground
VIN = 3V Single Ended (Note 3)
± 75
± 200
mA
Output Balance Error
∆VOUT Common Mode /∆VOUT
Differential , VOUT = 1 VPP
Differential, f = 10 MHz
−68
dB
Input Resistance
Common Mode Gain
25
kΩ
1.005
V/V
Output Performance
mA
Miscellaneous Performance
Enable Voltage Threshold
Pin 7
Disable Voltage Threshold
Pin 7
2.0
V
1.5
Enable/Disable Time
V
10
ns
70
dB
AVOL
Open Loop Gain
Differential
PSRR
Power Supply Rejection Ratio
DC, ∆VS = ± 1V
74
90
Supply Current
RL = ∞
18
20
24
27
mA
1
1.2
mA
Disabled Supply Current
dB
5V Electrical Characteristics
(Note 2)
Single ended in differential out, TA = 25˚C, AV = +1, VS = 5V, VCM = 2.5V, RF = RG = 365Ω, RL = 500Ω; Unless specified.
Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
SSBW
Small Signal −3 dB Bandwidth
RL = 500Ω, VOUT = 0.5 VPP
350
MHz
LSBW
Large Signal −3 dB Bandwidth
RL = 500Ω, VOUT = 2 VPP
330
MHz
60
MHz
1500
V/µs
0.1 dB Bandwidth
Slew Rate
2V Step (Note 6)
Rise/Fall Time, 10% to 90%
1V Step
1
ns
Settling Time
1V Step, 0.05%
12
ns
Common Mode Small Signal
Bandwidth
185
MHz
Slew Rate
180
V/µs
VCM Pin AC Performance (Common Mode Feedback Amplifier)
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LMH6550
5V Electrical Characteristics
(Note 2) (Continued)
Single ended in differential out, TA = 25˚C, AV = +1, VS = 5V, VCM = 2.5V, RF = RG = 365Ω, RL = 500Ω; Unless specified.
Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
Distortion and Noise Response
HD2
HD3
2nd Harmonic Distortion
3rd Harmonic Distortion
VO = 2 VPP, f = 5 MHz, RL = 800Ω
−89
VO = 2 VPP, f = 20 MHz, RL = 800Ω
−88
VO = 2 VPP, f = 5 MHz, RL = 800Ω
−85
VO = 2 VPP, f = 20 MHz, RL = 800Ω
−70
dBc
dBc
en
Input Referred Noise Voltage
f ≥ 1 MHz
6.0
nV/
in
Input Referred Noise Current
f ≥ 1 MHz
1.5
pA/
Input Characteristics (Differential)
VOSD
IBIAS
CMRR
VICM
1
±4
±6
mV
Input Offset Voltage
Differential Mode, VID = 0, VCM = 0
Input Offset Voltage Average
Temperature Drift
(Note 10)
Input Bias Current
(Note 9)
Input Bias Current Average
Temperature Drift
(Note 10)
9.5
nA/˚C
Input Bias Current Difference
Difference in Bias Currents Between
the Two Inputs
0.3
µA
Common-Mode Rejection Ratio
DC, VID = 0V
80
dBc
1.6
0
70
−8
µV/˚C
−16
µA
Input Resistance
Differential
5
MΩ
Input Capacitance
Differential
1
pF
Input Common Mode Range
CMRR > 53 dB
+3.1
+0.4
+3.2
+0.3
VCM Pin Input Characteristics (Common Mode Feedback Amplifier)
Input Offset Voltage
Common Mode, VID = 0
1
Input Offset Voltage Average
Temperature Drift
Input Bias Current
VCM CMRR
VID = 0,
1V Step on VCM Pin, Measure VOD
Input Resistance
VCM Pin to Ground
Common Mode Gain
∆VO,CM/∆VCM
70
±5
±8
mV
18.6
µV/˚C
3
µA
75
dB
25
kΩ
0.991
V/V
Output Performance
VOUT
Output Voltage Swing
Peak to Peak, Differential,
VS = ± 2.5V, VCM = 0V
2.4
2.8
V
IOUT
Linear Output Current
VOUT = 0V Differential
± 54
± 70
mA
ISC
Output Short Circuit Current
Output Shorted to Ground
VIN = 3V Single Ended (Note 3)
250
mA
CMVR
Common Mode Voltage Range
VID = 0, VCM Pin = 1.2V and 3.8V
3.8
1.2
V
Output Balance Error
∆VOUT Common Mode /∆VOUT
DIfferential , VOUT = 1 VPP
Differential, f = 10 MHz
−65
dB
3.72
1.23
Miscellaneous Performance
Enable Voltage Threshold
Pin 7
Disable Voltage Threshold
Pin 7
2.0
1.5
Enable/Disable Time
Open Loop Gain
V
DC, Differential
5
V
10
ns
70
dB
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LMH6550
5V Electrical Characteristics
(Note 2) (Continued)
Single ended in differential out, TA = 25˚C, AV = +1, VS = 5V, VCM = 2.5V, RF = RG = 365Ω, RL = 500Ω; Unless specified.
Boldface limits apply at the temperature extremes.
Symbol
Parameter
Conditions
PSRR
Power Supply Rejection Ratio
DC, ∆VS = ± 0.5V
IS
Supply Current
RL = ∞
ISD
Disabled Supply Current
Min
(Note 8)
Typ
(Note 7)
Max
(Note 8)
Units
72
77
16.5
19
23.5
26.5
mA
1
1.2
mA
dB
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.
Note 3: The maximum output current (IOUT) is determined by device power dissipation limitations.
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
P D= (TJ(MAX) — TA)/ θJA. All numbers apply for package soldered directly into a 2 layer PC board with zero air flow.
Note 5: Human body model: 1.5 kΩ in series with 100 pF. Machine model: 0Ω in series with 200pF.
Note 6: Slew Rate is the average of the rising and falling edges.
Note 7: Typical numbers are the most likely parametric norm.
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 input current implies current flowing out of the device.
Note 10: Drift determined by dividing the change in parameter at temperature extremes by the total temperature change.
Note 11: Parameter is guaranteed by design.
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(TA = 25˚C, VS = ± 5V, RL = 500Ω, RF = 365Ω, AV = +1; Un-
Frequency Response vs. Supply Voltage
Frequency Response
20130114
20130115
Frequency Response vs. VOUT
Frequency Response vs. Gain
20130134
20130116
Frequency Response vs. Capacitive Load
Suggested ROUT vs. Cap Load
20130121
20130122
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LMH6550
Typical Performance Characteristics
less Specified).
LMH6550
Typical Performance Characteristics (TA = 25˚C, VS = ±5V, RL = 500Ω, RF = 365Ω, AV = +1;
Unless Specified). (Continued)
Suggested ROUT vs. Cap Load
1 VPP Pulse Response Single Ended Input
20130126
20130123
2 VPP Pulse Response Single Ended Input
Large Signal Pulse Response
20130127
20130125
Output Common Mode Pulse Response
Distortion vs. Frequency Single Ended Input
20130128
20130124
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Distortion vs. Frequency Single Ended Input
Maximum VOUT vs. IOUT
20130129
20130130
Minimum VOUT vs. IOUT
Closed Loop Output Impedance
20130117
20130131
Closed Loop Output Impedance
PSRR
20130119
20130118
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LMH6550
Typical Performance Characteristics (TA = 25˚C, VS = ±5V, RL = 500Ω, RF = 365Ω, AV = +1;
Unless Specified). (Continued)
LMH6550
Typical Performance Characteristics (TA = 25˚C, VS = ±5V, RL = 500Ω, RF = 365Ω, AV = +1;
Unless Specified). (Continued)
PSRR
CMRR
20130120
20130133
Balance Error
3rd Order Intermodulation Products vs. VOUT
20130113
20130135
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The resistors RO help keep the amplifier stable when presented with a load CL as is typical in an analog to digital
converter (ADC). When fed with a differential signal, the
LMH6550 provides excellent distortion, balance and common mode rejection provided the resistors RF, RG and RO
are well matched and strict symmetry is observed in board
layout. With a DC CMRR of over 80 dB, the DC and low
frequency CMRR of most circuits will be dominated by the
external resistors and board trace resistance. At higher frequencies board layout symmetry becomes a factor as well.
Precision resistors of at least 0.1% accuracy are recommended and careful board layout will also be required.
The LMH6550 is a fully differential amplifier designed to
provide low distortion amplification to wide bandwidth differential signals. The LMH6550, though fully integrated for
ultimate balance and distortion performance, functionally
provides three channels. Two of these channels are the V+
and V− signal path channels, which function similarly to
inverting mode operational amplifiers and are the primary
signal paths. The third channel is the common mode feedback circuit. This is the circuit that sets the output common
mode as well as driving the V+ and V− outputs to be equal
magnitude and opposite phase, even when only one of the
two input channels is driven. The common mode feedback
circuit allows single ended to differential operation.
The LMH6550 is a voltage feedback amplifier with gain set
by external resistors. Output common mode voltage is set by
the VCM pin. This pin should be driven by a low impedance
reference and should be bypassed to ground with a 0.1 µF
ceramic capacitor. Any signal coupling into the VCM will be
passed along to the output and will reduce the dynamic
range of the amplifier.
The LMH6550 is equipped with a ENABLE pin to reduce
power consumption when not in use. The ENABLE pin floats
to logic high. If this pin is not used it can be left floating. The
amplifier output stage goes into a high impedance state
when the amplifier is disabled. The feedback and gain set
resistors will then set the impedance of the circuit. For this
reason input to output isolation will be poor in the disabled
state.
FULLY DIFFERENTIAL OPERATION
The LMH6550 will perform best when used with split supplies and in a fully differential configuration. See Figure 1
and Figure 3 for recommend circuits.
20130102
FIGURE 2. Fully Differential Cable Driver
With up to 15 VPP differential output voltage swing and 80
mA of linear drive current the LMH6550 makes an excellent
cable driver as shown in Figure 2. The LMH6550 is also
suitable for driving differential cables from a single ended
source.
20130104
FIGURE 1. Typical Application
The circuit shown in Figure 1 is a typical fully differential
application as might be used to drive an ADC. In this circuit
closed loop gain, (AV) = VOUT/ VIN = RF/RG. For all the
applications in this data sheet VINis presumed to be the
voltage presented to the circuit by the signal source. For
differential signals this will be the difference of the signals on
each input (which will be double the magnitude of each
individual signal), while in single ended inputs it will just be
the driven input signal.
20130110
FIGURE 3. Single Ended in Differential Out
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LMH6550
Application Section
LMH6550
Application Section
SINGLE ENDED INPUT TO DIFFERENTIAL OUTPUT
(Continued)
The LMH6550 provides excellent performance as an active
balun transformer. Figure 3 shows a typical application
where an LMH6550 is used to produce a differential signal
from a single ended source. It should be noted that compared to differential input, using a single ended input will
reduce gain by 1/2. So that the closed loop gain will be; Gain
= AV = 0.5 * RF/RG.
In single ended input operation the output common mode
voltage is set by the VCMpin as in fully differential mode.
Also, In this mode the common mode feedback circuit must
recreate the signal that is not present on the unused differential input pin. The performance chart titled “Balance Error”
is the measurement of the effectiveness of this process. The
common mode feedback circuit is responsible for ensuring
balanced output with a single ended input. Balance error is
defined as the amount of input signal that couples into the
output common mode. It is measured as a the undesired
output common mode swing divided by the signal on the
input. Balance error can be caused by either a channel to
channel gain error, or phase error. Either condition will produce a common mode shift. The chart titled “Balance Error”
measures the balance error with a single ended input as that
is the most demanding mode of operation for the amplifier.
Supply and VCM pin bypassing are also critical in this mode
of operation. See the above section on FULLY DIFFERENTIAL OPERATION for bypassing recommendations also see
Figure 4 and Figure 5 for recommended supply bypassing
configurations.
20130101
FIGURE 4. Split Supply Bypassing Capacitors
SINGLE SUPPLY OPERATION
The input stage of the LMH6550 has a built in offset of 0.7V
towards the lower supply to accommodate single supply
operation with single ended inputs. As shown in Figure 6, the
input common mode voltage is less than the output common
voltage. It is set by current flowing through the feedback
network from the device output. The input common mode
range of 0.4V to 3.2V places constraints on gain settings.
Possible solutions to this limitation include AC coupling the
input signal, using split power supplies and limiting stage
gain. AC coupling with single supply is shown in Figure 7.
In Figure 6 below closed loop gain = AV= RF/RG. Please note
that in single ended to differential operation VIN is measured
single ended while VOUT is measured differentially. This
means that gain is really 1/2 or 6 dB less when measured on
either of the output pins separately.
VICM= Input common mode voltage = (V+IN+V−IN)/2.
20130112
FIGURE 5. Single Supply Bypassing Capacitors
The LMH6550 requires supply bypassing capacitors as
shown in Figure 4 and Figure 5. 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. The
SMT capacitors should be connected directly to a ground
plane. Thin traces or small vias will reduce the effectiveness
of bypass capacitors. Also shown in both figures is a capacitor from the VCM pin to ground. The VCM pin is a high
impedance input to a buffer which sets the output common
mode voltage. Any noise on this input is transferred directly
to the output. Output common mode noise will result in loss
of dynamic range, degraded CMRR, degraded Balance and
higher distortion. The VCM pin should be bypassed even if
the pin in not used. There is an internal resistive divider on
chip to set the output common mode voltage to the mid point
of the supply pins. The impedance looking into this pin is
approximately 25 kΩ. If a different output common mode
voltage is desired drive this pin with a clean, accurate voltage reference.
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20130111
FIGURE 6. Relating AV to Input/Output Common Mode
Voltages
12
LMH6550
Application Section
(Continued)
20130105
20130109
FIGURE 8. Driving an ADC
FIGURE 7. AC Coupled for Single Supply Operation
The amplifier and ADC should be located as closely 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 the output traces and the ADC is
sensitive to high frequency noise that may couple in on its
input lines. 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 Nyquist range (DC to
Fs/2). See AN-236 for more details on the subsampling
process and the requirements this imposes on the filtering
necessary in your system.
DRIVING ANALOG TO DIGITAL CONVERTERS
Analog to digital converters (ADC) 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 8 shows a
typical circuit for driving an ADC. The two 56Ω resistors
serve to isolate the capacitive loading of the ADC from the
amplifier and ensure stability. In addition, the resistors form
part of a low pass filter which helps to provide anti alias and
noise reduction functions. The two 39 pF capacitors help to
smooth the current spikes associated with the internal
switching circuits of the ADC and also are a key component
in the low pass filtering of the ADC input. In the circuit of
Figure 8 the cutoff frequency of the filter is 1/ (2*π*56Ω *(39
pF + 14 pF)) = 53 MHz (which is slightly less than the
sampling frequency). Note that the ADC input capacitance
must be factored into the frequency response of the input
filter, and that being a differential input the effective input
capacitance is double. Also as shown in Figure 8 the input
capacitance to many ADCs is variable based on the clock
cycle. See the data sheet for your particular ADC for details.
USING TRANSFORMERS
Transformers are useful for impedance transformation as
well as for single to differential, and differential to single
ended conversion. A transformer can be used to step up the
output voltage of the amplifier to drive very high impedance
loads as shown in Figure 9. Figure 11 shows the opposite
case where the output voltage is stepped down to drive a low
impedance load.
Transformers have limitations that must be considered before choosing to use one. Compared to a differential amplifier, the most serious limitations of a transformer are the
inability to pass DC and balance error (which causes distortion and gain errors). For most applications the LMH6550 will
have adequate output swing and drive current and a transformer will not be desirable. Transformers are used primarily
to interface differential circuits to 50Ω single ended test
equipment to simplify diagnostic testing.
13
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LMH6550
Application Section
(Continued)
20130107
20130103
FIGURE 9. Transformer Out High Impedance Load
FIGURE 12. Driving 50Ω Test Equipment
CAPACITIVE DRIVE
As noted in the Driving ADC section, capacitive loads should
be isolated from the amplifier output 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. Cap Load” charts in the Typical Performance Characteristics section.
20130132
POWER DISSIPATION
The LMH6550 is optimized for maximum speed and performance in the small form factor of the standard SOIC package, and is essentially a dual channel amplifier. 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 is never exceeded due to
the overall power dissipation.
Follow these steps to determine the Maximum power dissipation for the LMH6550:
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 VOCM 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.
3. Calculate the total RMS power: PT = PAMP + PD.
The maximum power that the LMH6550 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 SOIC package
θJA is 150˚C/W, and for the MSOP package it is 235˚C/W.
FIGURE 10. Calculating Transformer Circuit Net Gain
20130106
FIGURE 11. Transformer Out Low Impedance Load
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EVALUATION BOARD
Generally, a good high frequency layout will keep power
supply and ground traces away from the inverting input and
output pins. Parasitic capacitances on these nodes to
ground will cause frequency response peaking and possible
circuit oscillations (see Application Note OA-15 for more
information). National Semiconductor suggests the following
evaluation boards as a guide for high frequency layout and
as an aid in device testing and characterization:
(Continued)
NOTE: If VCM is not 0V 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 LMH6550 is protected against electrostatic discharge
(ESD) on all pins. The LMH6550 will survive 2000V Human
Body model and 200V Machine model events. Under normal
operation the ESD diodes have no effect on circuit performance. There are occasions, however, when the ESD diodes will be evident. If the LMH6550 is driven by a large
signal while the device is powered down the ESD diodes will
conduct . The current that flows through the ESD diodes will
either exit the chip through the supply pins or will flow
through the device, hence it is possible to power up a chip
with a large signal applied to the input pins. Using the
shutdown mode is one way to conserve power and still
prevent unexpected operation.
Device
Package
Evaluation Board
Part Number
LMH6550MA
SOIC
LMH730154
These evaluation boards can be shipped when a device
sample request is placed with National Semiconductor.
BOARD LAYOUT
The LMH6550 is a very high performance amplifier. In order
to get maximum benefit from the differential circuit architecture board layout and component selection is very critical.
The circuit board should have low a inductance ground plane
and well bypassed broad 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 3-4 mm of the
amplifier as should the supply bypass capacitors. The
LMH730154 evaluation board is an example of good layout
techniques. Evaluation boards are available free of charge
through the product folder on National’s web site.
The LMH6550 is sensitive to parasitic capacitances on the
amplifier inputs and to a lesser extent on the outputs as well.
Ground and power plane metal should be removed from
beneath the amplifier and from beneath RF and RG.
With any differential signal path symmetry is very important.
Even small amounts of assymetery will contribute to distortion and balance errors.
15
www.national.com
LMH6550
Application Section
LMH6550
Physical Dimensions
inches (millimeters) unless otherwise noted
8-Pin SOIC
NS Package Number M08A
8–Pin MSOP
NS Package Number MUA08A
www.national.com
16
LMH6550 Differential, High Speed Op Amp
Notes
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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