NSC LMH6321MRX

LMH6321
300 mA High Speed Buffer with Adjustable Current Limit
General Description
Features
The LMH6321 is a high speed unity gain buffer that slews at
1800 V/µs and has a small signal bandwidth of 110 MHz
while driving a 50Ω load. It can drive ± 300 mA continuously
and will not oscillate while driving large capacitive loads.
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The LMH6321 features an adjustable current limit. The current limit is continuously adjustable from 10 mA to 300 ma
with a ± 5 mA ± 5% accuracy. The current limit is set by
adjusting an external reference current with a resistor. The
current can be easily and instantly adjusted, as needed by
connecting the resistor to a DAC to form the reference
current. The sourcing and sinking currents share the same
current limit.
The LMH6321 is available in a space saving 8-pin PSOP or
a 7-pin TO-263 power package. The PSOP package features an exposed pad on the bottom of the package to
increase its heat sinking capability. The LMH6321 can be
used within the feedback loop of an operational amplifier to
boost the current output or as a stand alone buffer.
High slew rate
Wide bandwidth
Continuous output current
Output current limit tolerance
Wide supply voltage range
Wide temperature range
Adjustable current limit
High capacitive load drive
Thermal shutdown error flag
1800 V/µs
110 MHz
± 300 mA
± 5 mA ± 5%
5V to ± 15V
−40˚C to +125˚C
Applications
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Line driver
Pin driver
Sonar driver
Motor control
Connection Diagrams
8-Pin PSOP
7-Pin TO-263
20138626
20138625
Note: V− pin is connected to tab on back of each package
© 2006 National Semiconductor Corporation
DS201386
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LMH6321 300 mA High Speed Buffer with Adjustable Current Limit
October 2006
LMH6321
Absolute Maximum Ratings (Note 1)
(Soldering, 10 seconds)
Power Dissipation
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Operating Temperature Range
250V
Input to Output Voltage (Note 3)
Input Voltage
Output Short-Circuit to GND (Note 4)
Storage Temperature Range
± 5V
± VSUPPLY
Thermal Resistance (θJA),
Continuous
Thermal Resistance (θJC)
5V to ± 16V
PSOP Package (Note 6)
180˚C/W
TO-263 Package
−65˚C to +150˚C
Junction Temperature (TJMAX)
−40˚C to +125˚C
Operating Supply Range
36V ( ± 18V)
Supply Voltage
± 1.2V
Operating Ratings
2.5 kV
Machine Model
(Note 8)
CL Pin to GND Voltage
ESD Tolerance (Note 2)
Human Body Model
260˚C
4˚C/W
Thermal Resistance (θJA)
+150˚C
TO-263 Package
Lead Temperature
80˚C/W
± 15V Electrical Characteristics
The following specifications apply for Supply Voltage = ± 15V, VCM = 0, RL ≥ 100 kΩ and RS = 50Ω, CL open, unless otherwise
noted. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25˚C.
Symbol
AV
Parameter
Voltage Gain
Conditions
Min
Typ
RL = 1 kΩ, VIN = ± 10V
0.99
0.98
0.995
RL = 50Ω, VIN = ± 10V
0.86
0.84
0.92
Max
Units
V/V
V/V
VOS
Input Offset Voltage
RL = 1 kΩ, RS = 0V
±4
IB
Input Bias Current
VIN = 0V, RL = 1 kΩ, RS = 0V
±2
R.IN
Input Resistance
R.L = 50Ω
250
kΩ
CIN
Input Capacitance
3.5
pF
RO
Output Resistance
IO = ± 10 mA
5
Ω
IS
Power Supply Current
RL = ∞, VIN = 0
11
14.5
16.5
14.9
18.5
20.5
750 µA into
CL Pin
V O1
V O2
V O3
VEF
TSH
Positive Output Swing
IO = 300 mA, RS = 0V, VIN = ± VS
Negative Output Swing
IO = 300 mA, RS = 0V, VIN = ± VS
Positive Output Swing
RL = 1 kΩ, RS = 0V, VIN = ± VS
Negative Output Swing
RL = 1 kΩ, RS = 0V, VIN = ± VS
Positive Output Swing
RL = 50Ω, RS = 0V, VIN = ± VS
Negative Output Swing
RL = 50Ω, RS = 0V, VIN = ± VS
−11.9
Error Flag Output Voltage
RL = ∞, VIN = 0,
EF pulled up with 5 kΩ
to +5V
Normal
5.00
During
Thermal
Shutdown
0.25
Thermal Shutdown
Temperature
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11.2
10.8
mA
−10.3
−9.8
V
−12.9
−12.6
V
12.2
Measure Quantity is Die (Junction)
Temperature
168
Hysteresis
10
2
µA
13.4
−13.4
11.6
11.2
mV
11.9
−11.3
13.1
12.9
± 35
± 52
± 15
± 17
−10.9
−10.6
V
V
˚C
(Continued)
The following specifications apply for Supply Voltage = ± 15V, VCM = 0, RL ≥ 100 kΩ and RS = 50Ω, CL open, unless otherwise
noted. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25˚C.
Symbol
Parameter
Conditions
Min
ISH
Supply Current at Thermal
Shutdown
EF pulled up with 5 kΩ to +5V
PSSR
Power Supply Rejection Ratio
RL = 1 kΩ, VIN = 0V,
VS = ± 5V to ± 15V
SR
Slew Rate
Positive
58
54
66
Negative
58
54
64
−3 dB Bandwidth
VIN
Large Signal Bandwidth
VIN = 2 VPP, RL = 50Ω
HD2
2nd Harmonic Distortion
VO = 2 VPP, f = 100 kHz
RL = 50Ω
−59
RL = 100Ω
−70
VO = 2 VPP, f = 1 MHz
RL = 50Ω
−57
RL = 100Ω
−68
3rd Harmonic Distortion
VO = 2 VPP, f = 100 kHz
VO = 2 VPP, f = 1 MHz
MHz
48
MHz
RL = 50Ω
−59
RL = 100Ω
−70
RL = 50Ω
−62
RL = 100Ω
−73
Input Voltage Noise
f ≥ 1 MHz
2.8
in
Input Current Noise
f ≥ 1 MHz
2.4
ISC1
Output Short Circuit Current
Source (Note 7)
VO = 0V,
Program Current
into CL = 25 µA
ISC2
V/µs
110
en
VO = 0V
Program Current
into CL = 750 µA
dB
1800
BW
Units
mA
2900
= ± 11V, RL = 50Ω
= ± 20 mVPP, RL = 50Ω
LSBW
HD3
Max
3
VIN = ± 11V, RL = 1 kΩ
VIN
Typ
dBc
dBc
nV/
pA/
Sourcing
VIN = +3V
4.5
4.5
10
15.5
15.5
Sinking
VIN = −3V
4.5
4.5
10
15.5
15.5
Sourcing
VIN = +3V
280
273
295
308
325
Sinking
VIN = −3V
280
275
295
310
325
Output Short Circuit Current
Source
RS = 0V, VIN = +3V
(Notes 5, 7)
320
300
570
750
920
Output Short Circuit Current
Sink
RS = 0V, VIN = −3V
(Notes 5, 7)
300
305
515
750
910
± 0.5
± 4.0
± 8.0
mA
mA
mA
V/I Section
CLVOS
Current Limit Input Offset
Voltage
RL = 1 kΩ, GND = 0V
CLIB
Current Limit Input Bias
Current
RL = 1 kΩ
CL
CMRR
Current Limit Common Mode
Rejection Ratio
RL = 1 kΩ, GND = −13 to +14V
3
−0.5
−0.8
−0.2
60
56
69
mV
µA
dB
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LMH6321
± 15V Electrical Characteristics
LMH6321
± 5V Electrical Characteristics
The following specifications apply for Supply Voltage = ± 5V, VCM = 0, RL ≥ 100 kΩ and RS = 50Ω, CL Open, unless otherwise
noted. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25˚C.
Symbol
AV
Parameter
Voltage Gain
Conditions
Min
Typ
RL = 1 kΩ, VIN = ± 3V
0.99
0.98
0.994
RL = 50Ω, VIN = ± 3V
0.86
0.84
0.92
± 2.5
Max
Units
V/V
± 35
± 50
± 15
± 17
VOS
Offset Voltage
RL = 1 kΩ, RS = 0V
IB
Input Bias Current
VIN = 0V, RL = 1 kΩ, RS = 0V
±2
RIN
Input Resistance
RL = 50Ω
250
kΩ
CIN
Input Capacitance
3.5
pF
RO
Output Resistance
IS
Power Supply Current
IOUT = ± 10 mA
RL = ∞, VIN = 0V
VO1
V O2
V O3
PSSR
ISC1
Positive Output Swing
IO = 300 mA, RS = 0V, VIN = ± VS
Negative Output Swing
IO = 300 mA, RS = 0V, VIN = ± VS
Positive Output Swing
RL = 1 kΩ, RS = 0V, VIN = ± VS
Negative Output Swing
RL = 1 kΩ, RS = 0V, VIN = ± VS
Positive Output Swing
RL = 50Ω, RS = 0V, VIN = ± VS
Negative Output Swing
RL = 50Ω, RS = 0V, VIN = ± VS
Power Supply Rejection Ratio
RL = 1 kΩ, VIN = 0,
VS = ± 5V to ± 15V
Output Short Circuit Current
VO = 0V, Program
Current into CL = 25 µA
VO = 0V, Program
Current into CL = 750
µA
ISC2
SR
1.3
0.9
10
13.5
14.7
14
17.5
19.5
1.9
−1.3
3.2
2.9
−0.5
−0.1
3.5
−3.5
2.8
2.5
µA
Ω
5
750 µA into CL Pin
mV
V
−3.1
−2.9
3.1
−3.0
−2.6
−2.4
58
54
66
Negative
58
54
64
Sourcing
VIN = +3V
4.5
4.5
9
14.0
15.5
Sinking
VIN = −3V
4.5
4.5
9
14.0
15.5
Sourcing
VIN = +3V
275
270
290
305
320
Sinking
VIN = −3V
275
270
290
310
320
RS = 0V, VIN = +3V
(Notes 5, 7)
300
470
Output Short Circuit Current
Sink
RS = 0V, VIN = −3V
(Notes 5, 7)
300
400
Slew Rate
VIN = ± 2 VPP, RL = 1 kΩ
450
VIN = ± 2 VPP, RL = 50Ω
210
V
V
Positive
Output Short Circuit Current
Source
V
V
dB
mA
mA
V/µs
BW
−3 dB Bandwidth
VIN = ± 20 mVPP, RL = 50Ω
90
MHz
LSBW
Large Signal Bandwidth
VIN = 2 VPP, RL = 50Ω
39
MHz
TSD
Thermal Shutdown
Temperature
170
Hysteresis
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4
˚C
(Continued)
The following specifications apply for Supply Voltage = ± 5V, VCM = 0, RL ≥ 100 kΩ and RS = 50Ω, CL Open, unless otherwise
noted. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = 25˚C.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
V/I Section
CLVOS
Current Limit Input Offset
Voltage
RL = 1 kΩ, GND = 0V
CLIB
Current Limit Input Bias
Current
RL = 1 kΩ, CL = 0V
CL
CMRR
Current Limit Common Mode
Rejection Ratio
RL = 1 kΩ, GND = −3V to +4V
2.7
+5
± 5.0
−0.5
−0.6
−0.2
60
56
65
mV
µA
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 and the test conditions, see the Electrical Characteristics Table.
Note 2: Human Body Model is 1.5 kΩ in series with 100 pF. Machine Model is 0Ω in series with 200 pF.
Note 3: If the input-output voltage differential exceeds ± 5V, internal clamping diodes will turn on. The current through these diodes should be limited to 5 mA max.
Thus for an input voltage of ± 15V and the output shorted to ground, a minimum of 2 kΩ should be placed in series with the input.
Note 4: The maximum continuous current must be limited to 300 mA. See the Application section for more details.
Note 5: For the condition where the CL pin is left open the output current should not be continuous, but instead, should be limited to low duty cycle pulse mode such
that the RMS output current is less than or equal to 300 mA.
Note 6: Soldered to PC board with copper foot print equal to DAP size. Natural convection (no air flow). Board material is FR-4.
Note 7: VIN = + or −4V at TJ = −40˚C.
Note 8: 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. See Thermal Management section of the Application Hints.
Ordering Information
Package
8-Pin PSOP
Part Number
Package Marking
LMH6321MR
LMH6321MR
LMH6321MRX
7-Pin TO-263
LMH6321TS
LMH6321TSX
Transport Media
NSC Drawing
95 Units/Rail
MRA08A
2.5k Units Tape and Reel
LMH6321TS
5
45 Units/Rail
500 Units Tape and Reel
TS7B
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LMH6321
± 5V Electrical Characteristics
LMH6321
Typical Performance Characteristics
Overshoot vs. Capacitive Load
Slew Rate
20138634
20138665
Slew Rate
Small Signal Step Response
20138644
20138635
Small Signal Step Response
Input Offset Voltage of Amplifier vs. Supply Voltage
20138643
20138660
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6
LMH6321
Typical Performance Characteristics
(Continued)
Small Signal Step Response
Small Signal Step Response
20138645
20138646
Large Signal Step Response — Leading Edge
Large Signal Step Response — Leading Edge
20138639
20138641
Large Signal Step Response — Trailing Edge
Large Signal Step Response — Trailing Edge
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20138642
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LMH6321
Typical Performance Characteristics
(Continued)
Large Signal Step Response
Large Signal Step Response
20138648
20138647
Large Signal Step Response
Large Signal Step Response
20138649
20138650
Harmonic Distortion with 50Ω Load
Harmonic Distortion with 100Ω Load
20138637
20138638
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LMH6321
Typical Performance Characteristics
(Continued)
Harmonic Distortion with 50Ω Load
Noise vs. Frequency
20138651
20138615
Gain vs. Frequency
Gain vs. Frequency
20138618
20138616
Gain vs. Frequency
Gain vs. Frequency
20138617
20138619
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LMH6321
Typical Performance Characteristics
(Continued)
Supply Current vs. Supply Voltage
Output Impedance vs. Sourcing Current
20138653
20138654
Output Impedance vs. Sinking Current
Output Impedance vs. Sourcing Current
20138620
20138622
Output Short Circuit Current — Sourcing vs.
Program Current
Output Impedance vs. Sinking Current
20138657
20138621
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10
(Continued)
Output Short Circuit Current — Sinking vs.
Program Current
Output Short Circuit Current — Sourcing vs.
Program Current
20138661
20138655
Output Short Circuit Current — Sinking vs.
Program Current
Positive Output Swing vs. Sourcing Current
20138659
20138623
Negative Output Swing vs. Sinking Current
Positive Output Swing vs. Sourcing Current
20138656
20138624
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LMH6321
Typical Performance Characteristics
LMH6321
Typical Performance Characteristics
(Continued)
Output Short Circuit Current — Sourcing vs.
Supply Voltage
Negative Output Swing vs. Sinking Current
20138658
20138664
Output Short Circuit Current — Sinking vs.
Supply Voltage
Positive Output Swing vs. Supply Voltage
20138663
20138667
Positive Output Swing vs. Supply Voltage
Negative Output Swing vs. Supply Voltage
20138666
20138669
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LMH6321
Typical Performance Characteristics
(Continued)
Input Offset Voltage of Amplifier vs.
Common Mode Voltage
Negative Output Swing vs. Supply Voltage
20138668
20138672
Input Offset Voltage of Amplifier vs.
Common Mode Voltage
Input Bias Current of Amplifier vs. Supply Voltage
20138662
20138670
Input Offset Voltage of V/I Section vs.
Common Mode Voltage
Input Offset Voltage of V/I Section vs.
Common Mode Voltage
20138671
20138673
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LMH6321
a low impedance load, since a high Z source can’t supply the
needed current to the load. For example, in the case where
the signal source to an analog to digital converter is a
sensor, it is recommended that the sensor be isolated from
the A/D converter. The use of a buffer ensures a low output
impedance and delivery of a stable output to the converter.
In A/D converter applications buffers need to drive varying
and complex reactive loads.
Application Hints
BUFFERS
Buffers are often called voltage followers because they have
largely unity voltage gain, thus the name has generally come
to mean a device that supplies current gain but no voltage
gain. Buffers serve in applications requiring isolation of
source and load, i.e., high input impedance, low output
impedance (high output current drive). In addition, they offer
gain flatness and wide bandwidth.
Most operational amplifiers, that meet the other given requirements in a particular application, can be configured as
buffers, though they are generally more complex and are, by
and large, not optimized for unity gain operation. The commercial buffer is a cost effective substitute for an op amp.
Buffers serve several useful functions, either in tandem with
op amps or in standalone applications. As mentioned, their
primary function is to isolate a high impedance source from
Buffers come in two flavors: Open Loop and Closed Loop.
While sacrificing the precision of some DC characteristics,
and generally displaying poorer gain linearity, open loop
buffers offer lower cost and increased bandwidth, along with
less phase shift and propagation delay than do closed loop
buffers. The LMH6321 is of the open loop variety.
Figure 1 shows a simplified diagram of the LMH6321 topology, revealing the open loop complementary follower design
approach. Figure 2 shows the LMH6321 in a typical application, in this case, a 50Ω coaxial cable driver.
20138627
FIGURE 1. Simplified Schematic
SUPPLY BYPASSING
The method of supply bypassing is not critical for frequency
stability of the buffer, and, for light loads, capacitor values in
the neighborhood of 1 nF to 10 nF are adequate. However,
under fast slewing and large loads, large transient currents
are demanded of the power supplies, and when combined
with any significant wiring inductance, these currents can
produce voltage transients. For example, the LMH6321 can
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slew typically at 1000 V/µs. Therefore, under a 50Ω load
condition the load can demand current at a rate, di/dt, of
20 A/µs. This current flowing in an inductance of 50 nH
(approximately 1.5” of 22 gage wire) will produce a 1V
transient. Thus, it is recommended that solid tantalum capacitors of 5 µF to 10 µF, in parallel with a ceramic 0.1 µF
capacitor be added as close as possible to the device supply
pins.
14
LMH6321
Application Hints
(Continued)
20138628
FIGURE 2. 50Ω Coaxial Cable Driver with Dual Supplies
The reason for this larger resistor is explained in the following: One way that the input/output voltage differential can
exceed the Abs Max value is under a short circuit condition
to ground while driving the input with up to ± 15V. However,
in the LMH6321 the maximum output current is set by the
programmable Current Limit pin (CL). The value set by this
pin is guaranteed to be accurate to 5 mA ± 5%. If the input/
output differential exceeds 5V while the output is trying to
supply the maximum set current to a shorted condition or to
a very low resistance load, a portion of that current will flow
through the clamp diodes, thus creating an error in the total
load current. If the input resistor is too low, the error current
can exceed the 5 mA ± 5% budget.
For values of capacitors in the 10 µF to 100 µF range,
ceramics are usually larger and more costly than tantalums
but give superior AC performance for bypassing high frequency noise because of their very low ESR (typically less
than 10 MΩ) and low ESL.
LOAD IMPEDANCE
The LMH6321 is stable under any capacitive load when
driven by a 50Ω source. As shown by the Overshoot vs.
Capacitive Load graph in the Typical Performance Characteristics, worst case overshoot is for a purely capacitive load
of about 1 nF. Shunting the load capacitance with a resistor
will reduce the overshoot.
BANDWIDTH AND STABILITY
As can be seen in the schematic of Figure 2, a small capacitor is inserted in parallel with the series input resistors. The
reason for this is to compensate for the natural band-limiting
effect of the 1st order filter formed by this resistor and the
input capacitance of the buffer. With a typical CIN of 3.5 pF
(Figure 2), a pole is created at
(1)
fp2 = 1/(2πR1CIN) = 4.5 MHz
This will band-limit the buffer and produce further phase lag.
If used in an op amp-loop application with an amplifier that
has the same order of magnitude of unity gain crossing as
fp2, this additional phase lag will produce oscillation.
The solution is to add a small feed-forward capacitor (phase
lead) around the input resistor, as shown in Figure 2. The
value of this capacitor is not critical but should be such that
the time constant formed by it and the input resistor that it is
in parallel with (RIN) be at least five times the time constant
of RINCIN. Therefore,
C1 = (5RIN/R1)(CIN)
(2)
from the Electrical Characteristics, RIN is 250 kΩ.
In the case of the example in Figure 2, RINCIN produces a
time-constant of 870 ns, so C1 should be chosen to be a
minimum of 4.4 µs, or 438 pF. The value of C1 (1000 pF)
shown in Figure 2 gives 10 µs.
SOURCE INDUCTANCE
Like any high frequency buffer, the LMH6321 can oscillate
with high values of source inductance. The worst case condition occurs with no input resistor, and a purely capacitive
load of 50 pF, where up to 100 nH of source inductance can
be tolerated. With a 50Ω load, this goes up to 200 nH.
However, a 100Ω resistor placed in series with the buffer
input will ensure stability with a source inductances up to 400
nH with any load.
OVERVOLTAGE PROTECTION
(Refer to the simplified schematic in Figure 1).
If the input-to-output differential voltage were allowed to
exceed the Absolute Maximum Rating of 5V, an internal
diode clamp would turn on and divert the current around the
compound emitter followers of Q1/Q3 (D1 – D11 for positive
input), or around Q2/Q4 (D2 – D12 for negative inputs).
Without this clamp, the input transistors Q1 – Q4 would
zener, thereby damaging the buffer.
To limit the current through this clamp, a series resistor
should be added to the buffer input (see R1 in Figure 2).
Although the allowed current in the clamp can be as high as
5 mA, which would suggest a 2 kΩ resistor from a 15V
source, it is recommended that the current be limited to
about 1 mA, hence the 10 kΩ shown.
15
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LMH6321
Application Hints
to be at zero volts also. Therefore, a voltage applied to the
other end of REXT will force a current
(3)
IEXT = VPROG/REXT
into this pin. Via this pin, IOUT is programmable from 10 mA
to 300 mA by setting IEXT from 25 µA to 750 µA by means of
a fixed REXT of 10 kΩ and making VCL variable from 0.25V to
7.5V. Thus, an input voltage VCL is converted to a current
IEXT. This current is the output from the V/I converter. It is
gained up by a factor of two and sent to the Short Circuit
Protection block as IPROG. IPROG sets a voltage drop across
RSC which is applied to the non-inverting input of error amp
A2. The other input is across RSENSE. The current through
RSENSE, and hence the voltage drop across it, is proportional
to the load current, via the current sense transistor QSENSE.
The output of A2 controls the drive (IDRIVE) to the base of the
NPN output transistor, Q3 which is, proportional to the
amount and polarity of the voltage differential (VDIFF ) between AMP2 inputs, that is, how much the voltage across
RSENSE is greater than or less than the voltage across RSC.
This loop gains IEXT up by another 200, thus
(4)
ISC = 2 x 200 (IEXT) = 400 IEXT
(Continued)
OUTPUT CURRENT AND SHORT CIRCUIT
PROTECTION
The LMH6321 is designed to deliver a maximum continuous
output current of 300 mA. However, the maximum available
current, set by internal circuitry, is about 700 mA at room
temperature. The output current is programmable up to 300
mA by a single external resistor and voltage source.
The LMH6321 is not designed to safely output 700 mA
continuously and should not be used this way. However, the
available maximum continuous current will likely be limited
by the particular application and by the package type chosen, which together set the thermal conditions for the buffer
(see Thermal Management section) and could require less
than 300 mA.
The programming of both the sourcing and sinking currents
into the load is accomplished with a single resistor. Figure 3
shows a simplified diagram of the V to I converter and ISC
protection circuitry that, together, perform this task.
Referring to Figure 3, the two simplified functional blocks,
labeled V/I Converter and Short Circuit Protection, comprise
the circuitry of the Current Limit Control.
The V/I converter consists of error amplifier A1 driving two
PNP transistors in a Darlington configuration. The two input
connections to this amplifier are VCL (inverting input) and
GND (non-inverting input). If GND is connected to zero volts,
then the high open loop gain of A1, as well as the feedback
through the Darlington, will force CL, and thus one end REXT
Therefore, combining Equations (3) and (4), and solving for
REXT , we get
(5)
REXT = 400 VPROG/ISC
If the VCL pin is left open, the output short circuit current will
default to about 700 mA. At elevated temperatures this current will decrease.
20138629
Only the NPN output ISC protection is shown. Depending on the polarity of VDIFF, AMP2 will turn IDRIVE either on or off.
FIGURE 3. Simplified Diagram of Current Limit Control
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16
The maximum value of thermal resistance, junction to ambient θJA, is defined as:
(Continued)
THERMAL MANAGEMENT
(6)
θJA = (TJ(MAX) - TA(MAX) )/ PD(MAX)
where:
TJ(MAX) = the maximum recommended junction temperature
TA(MAX) = the maximum ambient temperature in the user’s
environment
PD(MAX) = the maximum recommended power dissipation
Heatsinking
For some applications, a heat sink may be required with the
LMH6321. This depends on the maximum power dissipation
and maximum ambient temperature of the application. To
accomplish heat sinking, the tabs on TO-263 and PSOP
package may be soldered to the copper plane of a PCB for
heatsinking (note that these tabs are electrically connected
to the most negative point in the circuit, i. e.,V−).
Note: The allowable thermal resistance is determined by the maximum
allowable heat rise , TRISE = TJ(MAX) - TA(MAX) = (θJA) (PD(MAX)). Thus,
if ambient temperature extremes force TRISE to exceed the design
maximum, the part must be de-rated by either decreasing PD to a safe
level, reducing θJA, further, or, if available, using a larger copper area.
Heat escapes from the device in all directions, mainly
through the mechanisms of convection to the air above it and
conduction to the circuit board below it and then from the
board to the air. Natural convection depends on the amount
of surface area that is in contact with the air. If a conductive
plate serving as a heatsink is thick enough to ensure perfect
thermal conduction (heat spreading) into the far recesses of
the plate, the temperature rise would be simply inversely
proportional to the total exposed area. PCB copper planes
are, in that sense, an aid to convection, the difference being
that they are not thick enough to ensure perfect conduction.
Therefore, eventually we will reach a point of diminishing
returns (as seen in Figure 5). Very large increases in the
copper area will produce smaller and smaller improvement
in thermal resistance. This occurs, roughly, for a 1 inch
square of 1 oz copper board. Some improvement continues
until about 3 square inches, especially for 2 oz boards and
better, but beyond that, external heatsinks are required.
Ultimately, a reasonable practical value attainable for the
junction to ambient thermal resistance is about 30 ˚C/W
under zero air flow.
A copper plane of appropriate size may be placed directly
beneath the tab or on the other side of the board. If the
conductive plane is placed on the back side of the PCB, it is
recommended that thermal vias be used per JEDEC Standard JESD51-5.
Procedure
1.
First determine the maximum power dissipated by the
buffer, PD(MAX). For the simple case of the buffer driving
a resistive load, and assuming equal supplies, PD(MAX)
is given by
(7)
PD(MAX) = IS (2V+) + V+2/4RL
where: IS = quiescent supply current
2.
Determine the maximum allowable die temperature rise,
(8)
TR(MAX) = TJ(MAX)-TA(MAX) = PD(MAX)θJA
3. Using the calculated value of TR(MAX) and PD(MAX) the
required value for junction to ambient thermal resistance
can be found:
(9)
θJA = TR(MAX)/PD(MAX)
4. Finally, using this value for θJA choose the minimum
value of copper area from Figure 4.
Example
Assume the following conditions:
V+ = V− = 15V, RL = 50Ω, IS = 15 mA TJ(MAX) = 125˚C,
TA(MAX) = 85˚C.
1. From (7)
PD(MAX) = IS (2V+) + V+2/4RL = (15 mA)(30V) +
225V2/200Ω = 1.58W
Determining Copper Area
One can determine the required copper area by following a
few basic guidelines:
2.
From (8)
TR(MAX) = 125˚C - 85˚C = 40˚C
1.
3.
From (9)
θJA = 40˚C/1.58W = 25.3˚C/W
2.
3.
4.
5.
Determine the value of the circuit’s power dissipation,
PD
Specify a maximum operating ambient temperature,
TA(MAX). Note that when specifying this parameter, it
must be kept in mind that, because of internal temperature rise due to power dissipation, the die temperature,
TJ, will be higher than TA by an amount that is dependent on the thermal resistance from junction to ambient,
θJA. Therefore, TA must be specified such that TJ does
not exceed the absolute maximum die temperature of
150˚C.
Specify a maximum allowable junction temperature, TJ(MAX), which is the temperature of the chip at maximum
operating current. Although no strict rules exist, typically
one should design for a maximum continuous junction
temperature of 100˚C to 130˚C, but no higher than
150˚C which is the absolute maximum rating for the part.
Calculate the value of junction to ambient thermal resistance, θJA
Choose a copper area that will guarantee the specified
TJ(MAX) for the calculated θJA. θJA as a function of copper area in square inches is shown in Figure 4.
Examining the plot of Copper Area vs. θJA, we see that we
cannot attain this low of a thermal resistance for one layer of
1 oz copper. It will be necessary to derate the part by
decreasing either the ambient temperature or the power
dissipation. Other solutions are to use two layers of 1 oz foil,
or use 2 oz copper (see Table 1), or to provide forced air flow.
One should allow about an extra 15% heat sinking capability
for safety margin.
17
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LMH6321
Application Hints
LMH6321
Application Hints
As seen in the previous example, buffer dissipation in DC
circuit applications is easily computed. However, in AC circuits, signal wave shapes and the nature of the load (reactive, non-reactive) determine dissipation. Peak dissipation
can be several times the average with reactive loads. It is
particularly important to determine dissipation when driving
large load capacitance.
A selection of thermal data for the PSOP package is shown
in Table 2. The table summarized θJA for both 0.5 watts and
0.75 watts. Note that the thermal resistance, for both the
TO-263 and the PSOP package is lower for the higher power
dissipation levels. This phenomenon is a result of the principle of Newtons Law of Cooling. Restated in term of heatsink cooling, this principle says that the rate of cooling and
hence the thermal conduction, is proportional to the temperature difference between the junction and the outside
environment (ambient). This difference increases with increasing power levels, thereby producing higher die temperatures with more rapid cooling.
(Continued)
20138630
TABLE 2. θJA vs. Copper Area and PD for PSOP. 1.0 oz
cu Board. No Airflow. Ambient Temperature = 22˚C
FIGURE 4. Thermal Resistance (typ) for 7-L TO-263
Package Mounted on 1 oz. (0.036 mm) PC Board Foil
20138631
FIGURE 5. Derating Curve for TO-263 package.
No Air Flow
TABLE 1. θJA vs. Copper Area and PD for TO-263. 1.0
oz cu Board. No Air Flow. Ambient Temperature = 24˚C
Copper Area
θJA @ 1.0W
(˚C/W)
θJA @ 2.0W
(˚C/W)
1 Layer = 1”x2” cu
Bottom
62.4
54.7
2 Layer = 1”x2” cu
Top & Bottom
36.4
32.1
2 Layer = 2”x2” cu
Top & Bottom
23.5
22.0
2 Layer = 2”x4” cu
Top & Bottom
19.8
17.2
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Copper Area/Vias
θJA @ 0.5W
(˚C/W)
θJA @ 0.75W
(˚C/W)
1 Layer = 0.05 sq. in.
(Bottom) + 3 Via
Pads
141.4
138.2
1 Layer = 0.1 sq. in.
(Bottom) + 3 Via
Pads
134.4
131.2
1 Layer = 0.25 sq. in.
(Bottom) + 3 Via
Pads
115.4
113.9
1 Layer = 0.5 sq. in.
(Bottom) + 3 Via
Pads
105.4
104.7
1 Layer = 1.0 sq. in.
(Bottom) + 3 Via
Pads
100.5
100.2
2 Layer = 0.5 sq. in.
(Top)/ 0.5 sq. in.
(Bottom) + 33 Via
Pads
93.7
92.5
2 Layer = 1.0 sq. in.
(Top)/ 1.0 sq. in.
(Bottom) + 53 Via
Pads
82.7
82.2
ERROR FLAG OPERATION
The LMH6321 provides an open collector output at the EF
pin that produces a low voltage when the Thermal Shutdown
Protection is engaged, due to a fault condition. Under normal
operation, the Error Flag pin is pulled up to V+ by an external
resistor. When a fault occurs, the EF pin drops to a low
voltage and then returns to V+ when the fault disappears.
This voltage change can be used as a diagnostic signal to
alert a microprocessor of a system fault condition. If the
function is not used, the EF pin can be either tied to ground
or left open. If this function is used, a 10 kΩ, or larger, pull-up
resistor (R2 in Figure 2) is recommended. The larger the
18
LMH6321
Application Hints
(Continued)
resistor the lower the voltage will be at this pin under thermal
shutdown. Table 3 shows some typical values of VEF for 10
kΩ and 100 kΩ.
TABLE 3. VEF vs. R2 Figure 2
R2
@ V+ = 5V
@ V+ = 15V
10 kΩ
0.24V
0.55V
100 KΩ
0.036V
0.072V
SINGLE SUPPLY OPERATION
If dual supplies are used, then the GND pin can be connected to a hard ground (0V) (as shown in Figure 2). However, if only a single supply is used, this pin must be set to a
voltage of one VBE (∼0.7V) or greater, or more commonly,
mid rail, by a stiff, low impedance source. This precludes
applying a resistive voltage divider to the GND pin for this
purpose. Figure 6 shows one way that this can be done.
20138635
FIGURE 7. Slew Rate vs. Peak-to-Peak Input Voltage
However, when driving capacitive loads, the slew rate may
be limited by the available peak output current according to
the following expression.
(10)
dv/dt = IPK/CL
and rapidly changing output voltages will require large output
load currents. For example if the part is required to slew at
1000 V/µs with a load capacitance of 1 nF the current
demand from the LMH6321 would be 1A. Therefore, fast
slew rate is incompatible with large CL. Also, since CL is in
parallel with the load, the peak current available to the load
decreases as CL increases.
Figure 8 illustrates the effect of the load capacitance on slew
rate. Slew rate tests are specified for resistive loads and/or
very small capacitive loads, otherwise the slew rate test
would be a measure of the available output current. For the
highest slew rate, it is obvious that stray load capacitance
should be minimized. Peak output current should be kept
below 500 mA. This translates to a maximum stray capacitance of 500 pF for a slew rate of 1000 V/µs.
20138632
FIGURE 6. Using an Op Amp to Bias the GND Pin to 1⁄2
V+ for Single Supply Operation
In Figure 6, the op amp circuit pre-biases the GND pin of the
buffer for single supply operation.
The GND pin can be driven by an op amp configured as a
constant voltage source, with the output voltage set by the
resistor voltage divider, R1 and R2. It is recommended that
These resistors be chosen so as to set the GND pin to V+/2,
for maximum common mode range.
SLEW RATE
Slew rate is the rate of change of output voltage for largesignal step input changes. For resistive load, slew rate is
limited by internal circuit capacitance and operating current
(in general, the higher the operating current for a given
internal capacitance, the faster is the slew rate). Figure 7
shows the slew capabilities of the LMH6321 under large
signal input conditions, using a resistive load.
20138636
FIGURE 8. Slew Rate vs. Load Capacitance
19
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LMH6321
Physical Dimensions
inches (millimeters) unless otherwise noted
8-Pin PSOP
NS Package Number MRA08B
7-Pin TO-263
NS Package Number TS7B
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20
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LMH6321 300 mA High Speed Buffer with Adjustable Current Limit
Notes