Unique IC Buffer Enhances Op Amp Designs, Tames Fast Amplifiers

Application Note 16
August 1985
Unique IC Buffer Enhances Op Amp Designs,
Tames Fast Amplifiers
Robert J. Widlar
Abstract: A unity gain IC power buffer that uses NPN
output transistors while avoiding the usual problems of
quasi-complementary designs is described. Free of parasitic oscillations and stable with large capacitive loads, the
buffer has a 20MHz bandwidth, a 100V/μs slew and can
drive ±10V into a 75Ω load. Standby current is 5mA. A
number of applications using the buffer are detailed, and
it is shown that a buffer has many uses beyond driving
a heavy load.
Introduction
An output buffer can do much more than increase the
output swing of an op amp. It can also eliminate ringing
with large capacitive loads. Fast buffers can improve the
performance of high speed followers, integrators and
sample/hold circuits, while at the same time making them
much easier to work with.
Interest in buffers has been low because a reasonably
priced, high performance, general purpose part has not
been available. Ideally, a buffer should be fast, have no
crossover distortion and drive a lot of current with large
output swing. At the same time, the buffer should not eat
much power, drive all capacitive loads without stability
problems and cost about the same as the op amps it is
used with. Naturally, current limiting and thermal overload
protection would be nice.
These goals have been a dream for twenty years; but thanks
to some new IC design techniques, they have finally been
reached. A truly general purpose buffer has been made that
is faster than most op amps but not hard to use in slow
applications. It is manufactured using standard bipolar
processing, and die size is 50 × 82 mils.
The electrical characteristics of the buffer are summarized
in Table 1. Offset voltage and bias current win no medals;
but the buffer will usually be driven from an op amp output
and put within the feedback loop, virtually eliminating these
terms as errors. Loaded voltage gain is mostly determined
by the output resistance. Again, any error is much reduced
with the buffer inside a feedback loop.
Unloaded, the output swings within a volt of the positive
supply and almost to the negative rail. With ±150mA loading, this saturation voltage increases by 2.2V. Except for
output voltage swing, performance is little affected for a
total supply voltage between 4V and 40V. This means that
it can be powered by a single 5V logic supply or ±20V op
amp supplies.
Bandwidth and slew rate decrease somewhat with reduced
load resistance. The values given in Table 1 are for a 100Ω
in parallel with 100pF. The speed is quite impressive considering that quiescent current is but 5mA.
Table 1. Typical Performance of the Buffer at 25°C. Supply
Voltage Range is 4V to 40V
PARAMETER
VALUE
Output Offset Voltage
70mV
Input Bias Current
75μA
Voltage Gain
0.999
Output Resistance
7Ω
Positive Saturation Voltage
0.9V
Negative Saturation Voltage
0.1V
Output Saturation Resistance
Peak Output Current
15Ω
±300mA
Bandwidth
22MHz
Slew Rate
100V/μs
Supply Current
5mA
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
an16f
AN16-1
Application Note 16
Design Concept
Basic Design
The functional schematic in Figure 1 describes the basic
elements of the buffer design. The op amp drives the
output sink transistor, Q30, such that the collector current of the output follower, Q29, never drops below the
quiescent value (determined by I1 and the area ratio of
Q12 and Q28). As a result, the high frequency response
is essentially that of a simple follower even when Q30 is
supplying the load current. The internal feedback loop is
isolated from the effects of capacitive loading by a small
resistor in the output lead.
Figure 2 shows the essential details of the buffer design
using the concept in Figure 1 (for clarity, parts common
to simplified and developed schematics use the same
number). The op amp uses a common base PNP pair, Q10
and Q11, degenerated with R6 and R7 for an input stage.
The differential output is converted to single-ended by a
current mirror, Q13 and Q14; and this drives the output
sink transistor, Q30, through a follower, Q19.
The scheme is not perfect in that the rate of rise of sink
current is noticeably less than for source current. This
can be mitigated by connecting a resistor between the
bias terminal and V+, raising quiescent current. A feature
of the final design is that the output resistance is largely
independent of the follower current, giving low output
resistance at low quiescent current. The output will swing
to the negative rail, which is particularly useful with singlesupply operation.
BIAS
INPUT
Start-up biasing is done with a collector FET, Q4. Once in
operation, the collector current of Q6 is added to the drain
current of Q4 to bias Q5. These currents plus the current
through Q9 and Q10 flow through Q12 to set the output
quiescent current (along with R10).
Q28
+
–
IC23
A1
Q29
I1
Q21
R23
OUTPUT
Q30
AN16 F01
The control loop is stabilized with a feedforward capacitor,
C1. Above 2MHz, feedback is predominantly through the
capacitor. The break frequency is determined by C1 and R7
plus the emitter resistance of Q11. The loop is made stable
for capacitive and resonant loading by R23, which limits
the phase lag that can be induced at the emitter of Q29.
A resistor, R10, has been added to improve the negative
slew response. With a large negative transient, Q29 will
cut off. When this happens, R10 pulls stored charge from
Q28 and provides enough voltage swing to get Q30 from
its clamp level into conduction.
V+
Q12
A clamp, Q15, is included to insure that the output sink
transistor does not turn off completely. Its biasing circuitry
Q6 through Q9, is arranged such that the emitter current
of Q15 is about equal to the base current of Q19 with no
output load.
V–
Figure 1. In the Buffer, Main Signal Path Is Through Followers
Q21 and Q29. Op Amp Keeps Q29 Turned on Even When Q30 Is
Supplying Load Current, So Response Is That of Followers
Follower Boost
The boost circuit in Figure 3 reduces the buffer standby
current by at least a factor of three while improving performance. It does this by increasing the effective current
gain of Q29 so that the current source current IC23, can be
drastically cut. Secondly, it can give under 0.5Ω follower
output resistance at less than 3mA bias, something that
normally takes over 40mA. Hard as it may be to believe,
the boost does not degrade the high frequency response
of the final design.
an16f
AN16-2
Application Note 16
V+
R10
300
Q12
R20
200
Q28
BIAS
Q23
R5
1k
Q5
R6
1k
Q9
Q10
100μ
R7
1k
Q11
Q29
R23
7
100μ
Q8
OUTPUT
Q15
100μ
Q6
Q7
Q13
Q19
Q14
R4
4k
Q4
700μ
C1
60
Q30
R14
Q21
4k
INPUT
AN16 F02
V–
Figure 2. Implementation of the Buffer in Figure 1. Simple Op Amp Uses Common Base PNP Input Transistors (Q10 and Q11).
Control Loop Is Stabilized with Feedforward Capacitor (C1); and Clamp (Q15) Keeps Q30 from Turning Off Entirely
V+
loop. If R21 is properly selected, voltage change across R19
with loading is less than 40mV, so a small value causes no
problems (increasing load does cause Q21 bias current to
increase). The quiescent drop across R19 is set by sizing
Q24, Q25 and Q29 geometries.
OUTPUT
Charge Storage PNP
Q25
IC23
0.7mA
R19
200
Q29
Q24
INPUT
R21
3k
Q21
AN16 F03
V–
IQ
Figure 3. This Boost Circuit Raises Effective Current Gain and
Transconductance of the Output Transistor, Giving Low Standby
Current Along with Low Output Resistance
If R19 is removed (opened), circuit operation becomes
clearer. Output resistance is determined by Q24, with Q25
and Q29 providing current gain. If the current through R21
is larger than the base current of Q29, output resistance is
proportionately reduced. Without R21, output resistance
depends on Q29 bias, like a simple follower.
The purpose of R19 is to provide a direct AC path at high
frequencies and kill unneeded gain in the boost feedback
At high frequencies, a lateral PNP looks like a low impedance between the base and emitter because charge stored
between the emitter and subcollector (the PNP base) has a
capacitive effect. The input PNP, Q21, has been designed to
have more than 30 times the stored charge of a standard
lateral for a given emitter current. This stored charge
couples in the input to slew internal stray capacitances
and drive the output follower while the boost circuitry is
coming into action.
Stored charge can be maximized in a lateral PNP by using
large emitter area and wide base spacing. Dimensions of
several mils are practical; diffusion lengths are in the order
of 6 mils with good processing.
an16f
AN16-3
Application Note 16
The charge stored under the emitter is most effective in
obtaining a fast charge transfer from base to emitter with
minimum change of emitter base voltage. Using the notation in Figure 4, this charge varies as:
QE ∝
WB AE
SE
∝ ( X C – XE ) XE
where SE is the emitter periphery. With XC fixed, it can be
shown that QE is maximized for XE = 0.5XC.
As will be seen on the complete schematic, the isolationbase transistor is used as a bias diode for current sources
because of its high VBE. One (Q28) is also used in the
collector of the output follower because the behavior at
very high current densities is much better than a standard
transistor.
1020
N+ EMITTER
NET CONCENTRATION (cm–3)
A sketch of a charge storage PNP is shown in Figure 4.
With the dimensions shown, current gains of 10 can be
obtained regularly. A sinker base contact is shown here
because a low resistance from the base terminal to the
area under the emitter is important.
1019
P+ ISOLATION
N+
SUBCOLLECTOR
1018
1017
0
XC
4
8
12
JUNCTION DEPTH (μm)
16
AN16 F05
P+ COLLECTOR
WB
2 MILS
XE
4 MILS
Figure 5. Impurity Profile of Isolation-Base Transistor. In
Contrast, Typical Standard NPN Has Peak Base Concentration
of 5 × 1016cm–3 and Base Width of 1μm
WB
2 MILS
N+
N
N– BASE
0.4 MILS
+ SUBCOLLECTOR
AN16 F04
SINKER
BASE
CONTACT
Figure 4. Charge Storage PNP is Lateral Structure with Base and
Emitter Dimensions of Several Mils. As Above, Current Gains of
10 are Practical
Isolation-Base Transistor
Transistors can be made by substituting an isolation diffusion for the normal base diffusion. Figure 5 shows the
impurity profile of such a transistor. Base doping under
the emitter is three orders of magnitude higher than standard transistors, and the base extends all the way to the
subcollector. The measured current gains of 0.1 are not
lower than might be expected.
The emitter-base voltage of an isolation-base transistor is
about 120mV greater than a standard IC transistor when
operating at the same emitter current. Production variations in VBE are much less than standard NPNs, probably
because net base doping is little affected by anything but
the isolation doping.
Complete Circuit
A complete schematic of the LT1010 buffer is given in
Figure 6. Component identification corresponds to the
simplified schematics. All details discussed thus far have
been integrated into the diagram.
Current limiting for the output follower is provided by
Q22 and Q31, which serve to clamp the voltage into the
follower boost circuitry when the voltage across R22
equals a diode drop.
Negative current limit is less conventional because putting
a sense resistor in the emitter of Q30 will seriously degrade
negative slew under load. Instead, the sense resistor, R17,
is in the collector. When the drop across it turns on Q27,
this transistor supplies current directly to the sink current
control amplifier, limiting sink current.
Should the output terminal rise above V+ because of some
fault condition, Q27 can saturate, breaking the current limit
loop. Should this happen, Q26 (a lateral collector near Q27
base) takes over to control current by removing sink drive
through Q16. This reserve current limit oscillates, but in
a controlled fashion.
an16f
AN16-4
Application Note 16
Clamp diodes, from the output to each supply, should
be used if the output can be driven beyond the supplies
by a high-current source. Unlike most ICs, the LT1010 is
designed so that ordinary junction diodes are effective
even when the IC is much hotter than the external diodes.
In current limit or thermal limit, excessive input-output
voltage might damage internal circuitry. To avoid this,
back-to-back isolation Zeners, Q32 and Q33, clamp the
input to the output. They are effective as long as the input
current is limited to about 40mA.
Current limit is backed up by thermal overload protection. The thermal sensor is Q1, with its base biased near
400mV. When Q1 gets hot enough to pull base drive off
Q2 (about 160°C), the collector of Q2 will rise, turning on
Q16 and Q20. These two transistors then shut down the
buffer. Including R2 generates hysteresis to control the
frequency of thermal limit oscillation.
Other details include the negative saturation clamp, Q17
and Q18. This clamp allows the output to saturate within
100mV of the negative supply rail without increasing supply
current while recovering cleanly from saturation. The base
of Q17 is connected internally into Q30 to sense voltage
on the internal collector side of the saturation resistance
to insure optimum operation at high currents.
Base drive to Q20 is limited by R15, a pinched base resistor. The value of this resistor varies as transistor hfe
over temperature and in production, controlling the turn
off current near 2mA. An emitter into the isolation wall
capacitor, C2, keeps Q20 from turning on with fast signals
on its collector.
When sinking large currents, the base of Q19 loads the
control amplifier. This unbalances the control loop and
reduces the output follower bias current. To compensate
for this, the base current of Q30 is routed to the bias diode,
Q12, through Q19. A small resistor, R19, aids compensation. This action raises the bias to Q23 and is responsible
for increasing the input PNP bias current with sink current.
R9
15
V+
R10
300
R20
200
Q28
Q25
Q12
BIAS
R8
15k
R19
200
Q23
Q29
R21
3k
Q24
R3
440
Q5
R5
1k
R6
1k
Q9
Q10
R7
1k
R18
2k
R17
2
C1
30
Q11
Q27
Q26
R22
2
R23
5
Q22
Q19
Q6
R12
1k
Q1
Q7
R1
4k
R2
450
Q4
R4
4k
OUTPUT
Q15
Q8
Q2
Q18
Q17
Q13
Q32
Q31
R16
200
Q30
R14
4k
Q20
Q33
INPUT
Q21
Q16
Q14
R13
4k
R15
24k
C2
100
AN16 F06
V–
Figure 6. Complete Schematic of the LT1010 Buffer. Component Identification Corresponds to Simplified Schematics.
The Isolation-Base Transistors Are Drawn with Heavy Base, as Is the Charge Storage PNP. Follower Drive Boost Has
Been Included Along with Negative Saturation Clamp (Q17 and Q18) and Protection Circuitry
an16f
AN16-5
Application Note 16
Final details of the design are that the collectors of Q10
and Q11 are segmented so that only a fraction of the
emitter current is sent to the current mirror, with the rest
dumped to V-. This allows the transistors to be operated
A
B
C
D
F
at their fT peak without requiring large C1. Lastly, R8 has
been included to shape the temperature characteristics of
output stage quiescent current.
A
E
G
H
Figure 7. Plot of the LT1010. Die Size Is 50 × 82 Mils
A photomicrograph of the LT1010 die is shown in Figure 7.
The features pointed out are identified below.
D) A high fT, 0.3 mil stripe, cross geometry is used for
the sink transistor driver (Q19).
A) Output transistors were designed to maximize high
frequency performance, while obtaining some ballasting.
E) Isolation-base transistor (Q28) carries the same 500mA
peak current as the output transistor but is much smaller.
B) Clamp PNP base (Q17) is connected by subcollector
stripe to region furthest from Q30 collector contact to
isolate saturation resistance.
F) MOS capacitor (C1) takes up considerable area.
C) Output resistors are in floating tub so that IC tubs are
not forward biased when junction diodes clamp output
below V–.
H) Charge storage PNP.
G) Capacitance formed by diffusing emitter into isolation
wall takes advantage of unused area.
an16f
AN16-6
Application Note 16
Buffer Performance
Phase Delay
The operating case temperature range for the LT1010 is
–55°C to 125°C. The maximum junction temperature for
the internal power transistors is 150°C. A commercial
version, the LT1010C, is also available. It rated for 0°C
to 100°C case temperature with a maximum junction
temperature of 125°C.
The following curves describe the buffer performance in
some detail. The fact that quiescent current boost (5mA
– 40mA) is not available on the TO-39 package should
be noted.
PHASE LAG (DEGREES)
The thermal resistance for one output transistor, excluding
the package, is 20°C/W because it was kept as small as possible to enhance speed. This explains the junction-to-case
thermal resistance of 40°C/W for the TO-39 package and
25°C/W for the TO-3 and TO-220, again for one transistor.
With AC loads, both transistors will be conducting; if the
frequency is high enough, thermal resistance is reduced
by 10°C/W.
50
20
RL = 50Ω
10
CL = 100pF
RS = 50Ω
IBIAS = 0
TJ = 25°C
2
50
20
RL = 50Ω
FREQUENCY (MHz)
200Ω
10
CL = 100pF
RS = 50Ω
RBIAS = 20Ω
TJ = 25°C
2
40
20
Figure 9. The Phase Delay Gives More Useful Information
About High Frequency Performance Than Bandwidth. This Is
a Plot of Phase Delay as a Function of Frequency with 50Ω
and 100Ω Loads. Capacitive Loading Is 100pF, and Quiescent
Current Is Not Boosted
5
RL = 200Ω
5
10
FREQUENCY (MHz)
AN16 F09
Bandwidth
50
200Ω
5
PHASE LAG (DEGREES)
Table 1 in the Introduction summarizes the typical specifications of the LT1010 buffer. The IC is supplied in three
standard power packages: the solid kovar base TO-5
(TO-39), the steel TO-3, and the plastic TO-220. The bias
terminal is not available in the TO-39 package because it has
only four leads, compared to five for the other packages.
5
10
FREQUENCY (MHz)
20
AN16 F09
30
Figure 10. This Shows Reduction in Phase Lag with
Quiescent Current Boosted to 40mA (RBIAS = 20Ω)
50Ω
20
VIN = 100mVPP
CL = 100pF
AV = –3dB
TJ = 25°C
10
0
0
30
20
10
QUIESCENT CURRENT (mA)
40
AN16 F08
Figure 8. The Dependence of Small Signal Bandwidth on Load
Resistance and Quiescent Current Boost Is Shown Here. The
100pF Capacitive Load That Is Specified Limits the Bandwidth
That Can Be Obtained with Boost and Light Loads
an16f
AN16-7
Application Note 16
Step Response
150
10
VOLTAGE GAIN (dB)
RL = 100Ω
TJ = 25°C
100
VOLTAGE CHANGE (mV)
Capacitive Loading
50
INPUT
OUTPUT
0
–50
RS = 50Ω
IBIAS = 0
TJ = 25°C
0
100pF
3nF
–10
0.1μF
–100
–150
0
10
20
30
–20
1
10
FREQUENCY (MHz)
0.1
TIME (ns)
AN16 F11
Figure 11. The Small Signal Step Response with 100Ω Load
Shows a 2ns Output Delay. This Gives an Excess Phase Delay
of 15° at 20MHz, Explaining Why the –3dB Bandwidth Is
Greater Than the Frequency for 45° Phase Delay.
Output Impedance
AN16 F13
Figure 13. These Frequency Response Plots, with Capacitive
Load Only, Show That Nothing Unusual Happens as Load
Capacitance Is Varied Over a Wide Range. Minor Peaking Is
Reduced with Quiescent Current Boost
Slew Response
100
OUTPUT VOLTAGE (V)
IBIAS = 0
TJ = 25°C
OUTPUT IMPEDANCE (Ω)
100
10
20 V = ±15V
S
R = 100Ω
15 T L = 25°C
J
f ≤ 1MHz
10
POSITIVE
5
IBIAS = 0
0
–5
NEGATIVE
–10
RBIAS = 20Ω
–15
1.0
0.1
1
10
FREQUENCY (MHz)
100
–20
–80
0
50
100
150
200
250
TIME (ns)
AN16 F12
Figure 12. The Unloaded Small Signal Output Impedance Stays
Down to 1MHz, Indicating the Frequency Limit of the Follower
Boost Circuitry
AN16 F14
Figure 14. The Negative Slew Delay Is Reduced by Using
Quiescent Current Boost (40mA). Positive Slew Is Not
Affected by Boost.
an16f
AN16-8
Application Note 16
400
80
SUPPLY CURRENT (mA)
VS = ±15V
0V ≥ VIN ≥ –10V
SLEW RATE (V/μs)
300
RL = 200Ω
100Ω
200
50Ω
100
0
20
10
30
QUIESCENT CURRENT (mA)
0
60
40
20
0
40
VS = ±15V
VIN = ±10V
IL = 0
TC = 25°C
0
2
3
FREQUENCY (MHz)
1
4
AN16 F15
5
AN16 F17
Figure 15. The Worst-Case Slew Response, Going from
0V to –10V, Is Plotted Here. It Is Clear That Substantial
Improvement Can be Made with Quiescent Current Boost
Figure 17. The No Load Supply Current Increases Above 1MHz
Under Large Signal Conditions. This Is a Quiescent Current
Boost Caused by Charging of Internal Capacitances. It Does
Give Very Good Power Bandwidth Even with Load, Although the
Excess Dissipation May Cause the IC to Go into Power Limit
Input Offset Voltage
15
200
VIN = 0V
OFFSET VOLTAGE (mV)
OUTPUT VOLTAGE (V)
10
5
0
–5
150
V+ = 38V
V– = –2V
100
V+ = 2V
V– = –38V
50
VS = ±15V
RL = 100Ω
IBIAS = 0
–10
–15
–1
0
1
2
TIME (μs)
3
4
AN16 F16
Figure 16. This 500ns Slew Residue Is Caused by Recovery
of the Follower Boost Circuitry. For Positive Outputs, the
Boost Circuit Is Hit Hard by the Input Through the Charge
Storage PNP. For Negative Outputs, it Is Hit by the Leading
Edge Overshoot on the Output. Recovery Is from a Positive
Boost Overshoot in Both Cases.
0
–50
0
50
100
TEMPERATURE (°C)
150
AN16 F18
Figure 18. The Offset Voltage is Determined by Matching
Between the Output Follower and the Input PNP. The Charge
Storage PNP on the Input Is Run at High Injection Levels to
Maximize Stored Charge. Therefore, the High Offset Voltage
Drift Shown Here Is No Surprise. The Offset Voltage Change
with Supply Voltage Shown in the Figure Is Mostly Positive
Supply Sensitivity. Changing the Negative Supply by 35V
Shifts Offset by 5mV
an16f
AN16-9
Application Note 16
Input Bias Current
1.000
VIN = 0V
IOUT = 0
VS = 40V
150
V+ = 38V
V– = –2V
0.999
GAIN (V/V)
BIAS CURRENT (μA)
200
Voltage Gain
100
VS = 4.5V
0.998
V+ = 2V
V– = –38V
50
0
–50
0
50
150
100
TEMPERATURE (°C)
0.997
–50
0
100
50
TEMPERATURE (°C)
AN16 F21
AN16 F19
Figure 19. The Increase in Bias Current with Temperature
Reflects the Current Gain Characteristics of the Charge
Storage PNP. Sensitivity of Bias Current to Supply Voltage
Is About Three Times Greater on Positive Supply
150
Figure 21. The Unloaded Voltage Gain Is High Enough to Be
Ignored in Most Any Application. In Practice, Gain Will Be
Determined by the Load Working Against the Output Resistance
Output Resistance
200
12
VS = ±15V
RL = 75Ω
IOUT ≤ 150mA
OUTPUT RESISTANCE (Ω)
10
BIAS CURRENT (μA)
150
TJ = 125°C
100
25°C
–55°C
50
8
6
4
2
0
–150
–100
–50
0
50
100
150
OUTPUT CURRENT (mA)
AN16 F20
Figure 20. The Change in Input Bias Current with Load Current
Is Not Excessive, but it Shows That the Follower Is Not Designed
for Working with High Source Resistances. For Positive Output
Current, Increase Is Caused by Follower Boost. For Negative
Output, It Results from Sink Transistor Base Current Increasing
Bias to the Input PNP Current Source
0
–50
0
100
50
TEMPERATURE (°C)
150
AN16 F22
Figure 22. The Output Resistance Is Essentially Independent of
DC Output Loading. The Temperature Sensitivity Is Shown Here
an16f
AN16-10
Application Note 16
Output Noise Voltage
4
TJ = 25°C
SATURATION VOLTAGE (V)
NOISE VOLTAGE (nV/√Hz)
200
150
100
RS = 1kΩ
50
3
IL = –150mA
2
–50mA
1
RS = 50Ω
–5mA
0
10
100
1k
FREQUENCY (Hz)
0
–50
10k
0
50
100
TEMPERATURE (°C)
AN16 F23
Figure 23. The Noise Performance of a Buffer Is of Small
Concern Unless it Is Grossly Bad. This Plot Shows That the
Buffer Noise Is Low by Comparison to the Excess Output
Noise of Op Amps
Saturation Voltage
AN16 F25
Figure 25. This Curve Gives the Negative Saturation Voltage.
Unloaded Saturation Voltage Is <0.1V, Again Increasing Linearly
with Current. The Saturation Characteristics Are Negligibly
Affected by Supply Voltage and Are Used to Determine Output
Swing Under Load
Supply Current
7
VIN = 0
IOUT = 0
IBIAS = 0
IL = 150mA
SUPPLY CURRENT (mA)
SATURATION VOLTAGE (V)
4
3
2
50mA
5mA
1
0
–50
150
0
50
100
TEMPERATURE (°C)
150
AN16 F24
Figure 24. The Positive Saturation Voltage (Referred to the
Positive Supply) Is Plotted Here as a Function of Temperature.
Unloaded Saturation Voltage Is 0.9V, with the Saturation Voltage
Increasing Linearly with Current to 150mA
6
TJ = –55°C
25°C
5
125°C
4
3
0
20
10
30
TOTAL SUPPLY VOLTAGE (V)
40
AN16 F26
Figure 26. Supply Current Is Not Greatly Affected by Supply
Voltage, as Shown in This Expanded-Scale Plot. This Accounts
for the 4V to 40V Supply Range with Unchanged Specifications
an16f
AN16-11
Application Note 16
0.8
VS = ±20V
HARMONIC DISTORTION (%)
BIAS TERMINAL VOLTAGE (V)
1.0
0.9
RBIAS = 100Ω
0.8
20Ω
0.7
0.6
0.5
–50
IBIAS = 0
VS = ±15V
VOUT = ±10V
0.6 TC = 25°C
0.4
RL = 50Ω
0.2
100Ω
0
0
100
50
TEMPERATURE (°C)
1
150
10
100
FREQUENCY (kHz)
AN16 F29
AN16 F27
Figure 27. The Quiescent Current Boost Is Determined by
the Bias Terminal Voltage Across an External Resistor. This
Expanded-Scale Plot Shows the Change in Bias Terminal
Voltage with Temperature. The Voltage Increases Less Than
20mV as the Total Supply Voltage Is Raised from 4.5V to 40V
Total Harmonic Distortion
Figure 29. Distortion Is Low to 100kHz, Even without
Quiescent Current Boost. The Influence of Load
Resistance Is Indicated Here
Maximum Power
10
RL = 50Ω
f = 10kHz
VS = ±15V
0.3 TC = 25°C
TC = 85°C
8
PEAK POWER (W)
HARMONIC DISTORTION (%)
0.4
0.2
IBIAS = 0
RBIAS = 50Ω
6
TO-3, TO-220
4
0.1
TO-39
2
0
0.1
1000
1
10
OUTPUT VOLTAGE (VPP)
100
AN16 F28
Figure 28. The Buffer Distortion Is Not High, Even When
it Is Outside a Feedback Loop, as Shown Here. The
Reduced-Distortion Curve Is for 20mA Supply Current
0
1
10
PULSE WIDTH (ms)
100
AN16 F30
Figure 30. These Curves Indicate the Peak Power Capability of
One Output Transistor for TC = 85°C. With AC Loading, Power Is
Divided Between the Two Output Transistors. This Can Reduce
Thermal Resistance to 30°C/W for the TO-39 and 15°C/W for the
TO-3, as Long as the Frequency Is High Enough That the Peak
Rating of Neither Transistor Is Exceeded
an16f
AN16-12
Application Note 16
Short Circuit Characteristics
0.5
VS = ±15V
VOUT = 0
0.4
OUTPUT CURRENT (A)
Isolating Capacitive Loads
SINK
0.3
SOURCE
0.2
0.1
0
–50
0
100
50
TEMPERATURE (°C)
150
AN16 F31
Figure 31. The Output Short Circuit Current Is Plotted Here as
a Function of Temperature. Above 160°C it Falls Off Sharply
Because of Thermal Limit. The Peak Output Current Is Equal to
the Short Circuit Current; with Capacitive Loads Greater Than
1nF, Current Limiting Can Reduce Slew Rate
INPUT CURRENT (mA)
50
The buffered follower in Figure 33a shows the recommended method of isolating capacitive loads. At lower
frequencies, the buffer is within the feedback loop so that
offset voltage and gain errors are negligible. At higher frequencies (above 80kHz here) op amp feedback is through
C1 so that phase shift from the load capacitance acting
against the buffer output impedance does not cause
instability.
The initial step response is the same as if the buffer were
outside the feedback loop; the gain error of the buffer is
then corrected by the op amp with a time constant determined by R1C1. This is shown in Figure 33b.
With small load capacitors, the bandwidth is determined
by the slower of the two amplifiers. The op amp and the
buffer in Figure 33 give a bandwidth near 15MHz. This is
reduced for capacitive loads greater than 1nF (determined
by the output impedance of the buffer).
Feedback-loop stability with large capacitive loads is determined by the ratio of the feedback time constant (R1C1) to
that of the buffer output resistance and load capacitance
(ROUTCL). A stability factor, m, can be expressed as
VS = ±15V
VOUT = 0
TJ = 25°C
25
m=
0
R1C1
ROUT CL
where ROUT is the buffer output resistance.
–25
–50
–15
R1
2k
–10
5
–5
0
INPUT VOLTAGE (V)
10
R2
2k
AN16 F32
Figure 32. The Input Characteristics, with the Output Shorted,
Are Plotted Here. The Input Is Clamped to the Output to Protect
Internal Circuitry. Therefore, it Is Necessary to Externally
Limit Input Current. The Output-Current Limit of IC Op Amps Is
Adequate Protection
C1
1μF
–
15
VIN
A1
A2
LT1010
+LT118A
VOUT
CL
m = R1C1
ROUTCL
AN16 F33
(33a) Connection Diagram
Y
)V
VOUT
R
)V = OUT VOUT
RL
Y = R1C1
CL = 0
tq
(33b) Step Response
Figure 33. Capacitive Loading on This Buffered Follower
Reduces Bandwidth Without Causing Ringing. Step Response
with No Capacitive Load Has Residue as Shown Here
an16f
AN16-13
OUTPUT VOLTAGE (2.5V/DIVISION)
Application Note 16
IL = 0
RL = 100Ω
m=4
m=2
With R1C1 as shown in Figure 33, any op amp with a
bandwidth greater than 200kHz will give the same results
on stability. Settling time, however, will be dominated by
the slew rate limitations of slow op amps.
m = 10
m=1
TIME (10μs/DIVISION)
AN16 F34
Figure 34. Large Signal Step Response (±5V) of the
Buffered Follower in Figure 33 for Indicated Loads
The measured large signal step response for the circuit
in Figure 33a is given in Figure 34 for various loads. For
m ≥ 4 (CL ≤ 0.068μF) there is overshoot but no ringing.
For m < 1 (CL > 0.33μF) ringing becomes pronounced.
20
Certain op amps, like the LM118, have back-to-back
protection diodes across the input terminals. With input
rise times in excess of the op amp slew rate, C1 can be
charged through these diodes, increasing settling time.
Including R2 in series with the input takes care of the
problem. Good supply bypass (22μF solid tantalum) should
be used because high peak currents are required to drive
load capacitors and supply transients can feed into the op
amp, increasing settling time.
The same load isolation technique is shown applied to
an inverting amplifier in Figure 36. The response differs
in that the output rise time and bandwidth are limited by
R1C1. This does reduce overshoot for m ≥ 4, as shown
in Figure 37. For m < 4, response approaches that of the
follower.
VOLTAGE ERROR (mV)
IL = 0
m=4
AND 10
10
R2
2k
m=1
R1
2k
VIN
m=2
C1
1μF
–
0
A1
A2
LT1010
+LT118A
R3
1k
RL = 100Ω
–10
m = R1C1
ROUTCL
VOUT
CL
AN16 F36
(36a) Connection Diagram
–20
0
20
40
60
TIME (μs)
80
100
Y
AN16 F35
Figure 35. Measured Settling For Output Steps in Figure 34.
For Capacitive Loads Less Than 0.068μF (m = 4) Settling Is
Based on a 2μs Time Constant
VOUT
Y = R1C1
CL = 0
tq
(36b) Step Response
The settling time constant is determined by R1C1 for
m ≥ 4. Without capacitive loading, the initial error on the
output step is smaller, so time to settle is less. The settling
characteristics are shown in Figure 35.
Figure 36. With an Inverter, Bandwidth and Rise Time Are
Limited by R1CL. For m ≥ 4, Capacitive Loading Has Little
Effect on Bandwidth
an16f
AN16-14
Application Note 16
Integrators
5
A lowpass amplifier can be formed just by using large C1
with the inverter in Figure 36, as long as the op amp is
capable of supplying the required current to the summing
junction and the increase in closed loop output impedance
above the cutoff frequency is not a problem (it will never
rise above the buffer output impedance).
OUTPUT VOLTAGE (V)
CL = 0
0
–5
5
CL = 0.068μF
m=4
0
If the integrating capacitor must be driven from the buffer
output, the circuit in Figure 39 can be used to provide capacitive load isolation. The method does introduce errors,
as is shown in the figure.
–5
–20
0
20
60
40
TIME (μs)
80
100
120
AN16 F37
Figure 37. Large Signal Pulse Response of the Inverter
in Figure 36.
Although the small signal bandwidth is reduced by C1,
considerable isolation can be obtained without reducing it
below the power bandwidth. Often, bandwidth reduction is
desirable to filter high frequency noise or unwanted signals.
The op amp does not respond instantly to an input step,
and the input current is supplied by the buffer output.
The resulting change in buffer output voltage is seen at
the real summing junction and is corrected at an R1C1
time constant. As the output ramps, the voltage change
across C1 generates a current through R1, shifting the
real summing junction off ground.
An alternate method of isolating capacitive loads is to buffer
an inverter output with the follower shown in Figure 33.
Capacitive load isolation for non-inverting amplifiers is
shown in Figure 38, along with the step response for small
CL. Rise time of the initial step is reduced with increasing
CL, and response approaches that of the inverter.
C2
1μF
REAL
SUMMING
JUNCTION
R2
10k
VIN
R1
2k
CS
R3
10k
–
+
A2
LT1010
A1
VOUT
CL
R1
AN16 F39
–
+
VIN
R2
m = R1C1
ROUTCL
C1
A2
LT1010
A1
m = R1C1
ROUTCL
VOUT
CL
C1
1μF
(39a) Connection Diagram
AN16 F38
(38a) Connection Diagram
Y
)V
VOUT
)V
)V % VIN
Y = R1C1
CL = 0
tq
(38b) Step Response
Figure 38. With Non-Inverting Amplifier, Rise Time of Initial Step
Decreases with Increasing CL. Stability Requirements Are the
Same as for Follower and Inverter
R
)V = R1C1 + OUT )VIN
R2C2 RIN
Y = R1C1
CL = 0
Y
VOUT
tq
(39b) Step Response
Figure 39. Capacitive Load Isolation for a Lowpass or Integrating
Amplifier When Integrating Capacitor Must Go to Buffer Output.
Response Given Is for Negative Input Step
an16f
AN16-15
Application Note 16
Figure 40 shows the voltage on the real summing junction
for an input square wave. Both error terms are apparent in
the top curve. With CL = 0.33μF, response is reasonable.
This suggest that m = 1 be used as a stability criterion
for this type of circuit if the shift of real summing node
voltage with output ramp is a problem. A capacitor can
be used on the real summing junction to absorb current
transients and reduce spiking, as shown in the lower curve.
CF
0.01μF
IIN
CS
–
A2
LT1010
A1
+
AN16 F41
VOUT
SUMMING VOLTAGE (5mV/DIVISION)
Figure 41. Buffer Increases Current Available to Summing Node.
Input Capacitor Absorbs Input Impulses and Raises Loop Gain
CL = 0, CS = 0
CL = 0.33μF, CS = 0
CL = 0, CS = 3.3μF
0
40
80
120
TIME (μs)
160
200
The summing node response to a 100mA, 100ns input
impulse is shown in Figure 42 for three different cases.
With CS = 0.33μF, the LT118A will settle faster than the
LF156 because of its higher gain-bandwidth product; but
CS cannot be made much smaller for Cf = 0.01μF. The LF156
works with CS = 0.02μF and settles even faster because it
goes through unity gain at a frequency where the LT1010
is better able to handle Cf = 0.01μF as a load capacitance.
However, the smaller CS does allow the summing node to
get further off null during the input impulse.
Figure 40. Step Response of the Integrating Amplifier in
Figure 39. The Real Summing Junction Voltage Is Shown
for ±0.5mA Input Change
With large R2 and CS = 0, the output voltage of the integrator
will be the response of an ideal integrator plus the voltage
of the real summing junction. Large CS will increase the
high frequency loop gain so that this is no longer true.
Impulse Integrator
With certain sensors, like radiation detectors, the output
is delivered in short, high current bursts. Frequently, it is
necessary to integrate these impulses to determine net
charge. A complication with some solid-state sensors is
that the peak voltage across them must be kept low to
avoid error.
SUMMING VOLTAGE (5mV/DIVISION)
AN16 F40
LF156, CS = 0.33μF
LT118A, CS = 0.33μF
LF156, CS = 0.02μF
0
2
4
6
TIME (μs)
8
10
AN16 F42
Figure 42. Summing Node Voltage of Impulse Integrator
in Figure 41 with 100mA, 100ns Input Impulse and –10mA
Recovery
The circuit in Figure 41 will integrate high current pulses
while keeping the summing note under control. Although
it increases noise gain, CS is often required for stability
and to absorb the leading edge of fast pulses. The buffer
increases the peak current available to the summing node
and improves stability by isolating Cf and CS from the op
amp output. Increased output drive capability is a bonus.
an16f
AN16-16
Application Note 16
Parallel Operation
Parallel operation provides reduced output impedance,
more drive capability and increased frequency response
under load. Any number of buffers can be directly paralleled as long as the increased dissipation in individual
units caused by mismatches of output resistance and
offset voltage is taken into account.
V+
IS
VIN
IS
A1
LT1010
VOUT
)IOUT
A2
LT1010
IS –)IOUT
Parallel operation is not thermally unstable. Should one
unit get hotter than its mates, its share of the output and
its standby dissipation will decrease.
As a practical matter, parallel connection needs only some
increased attention to heat sinking. In some applications,
a few ohms equalization resistance in each output may be
wise. Only the most demanding applications should require
matching, and then just of output resistance at 25°C.
Wideband Amplifiers
AN16 F43
IS +)IOUT
V–
Figure 43. When Two Buffers Are Paralleled, a Current
Can Flow Between Outputs, But Total Supply Current Is
Not Greatly Affected
When the inputs and outputs of two buffers are connected
together as shown in Figure 43, a current, ΔIOUT, flows
between the output:
∆IOUT =
Output load current will be divided based on the output resistance of the individual buffers. Therefore, the
available output current will not quite be doubled unless
output resistances are matched. As for offset voltage above,
the 25°C limits should be used for worst-case calculations.
VOSI – VOS2
ROUT1 +ROUT2
where VOS and ROUT are the offset voltage and output
resistance of the respective buffers.
Figure 44 shows the buffer inside the feedback loop of
a wideband amplifier that is not unity gain stable. In this
case, C1 is not used to isolate capacitive loads. Instead, it
provides an optimum value of phase lead to correct for the
buffer phase lag with a limited range of load capacitances.
V+
INPUT
R3
20
+
A1
HA2526
–
A2
LT1010
C1
15pF
OUTPUT
R2
800
AN16 F44
R1
100
Figure 44. Capacitive Load Isolation Described Earlier Does Not
Apply For Amplifiers That Are Not Unity Gain Stable. This 8MHz,
AV = 9 Amplifier Handles Only 200pF Load Capacitance
Normally, the negative supply current of one unit will
increase and the other decrease, with the positive supply current staying the same. The worst-case (VIN→V+)
increase in standby dissipation can be assumed to be
ΔIOUT VT, where VT is the total supply voltage.
With the TO-3 and TO-220 packages, behavior can be
improved by raising the quiescent current with a 20Ω
resistor from the bias terminal to V+. Alternately, devices
in the TO-39 package can be operated in parallel.
Offset voltage is specified worst-case over a range of supply voltages, input voltage and temperature. It would be
unrealistic to use these worst-case numbers above because
paralleled units are operating under identical conditions.
The offset voltage specified for VS = ±15V, VIN = 0 and
TA = 25°C will suffice for a worst-case condition.
Putting the buffer outside the feedback loop, as shown
in Figure 45, will give capacitive load isolation, with large
output capacitors only reducing bandwidth. Buffer offset,
referred to the op amp input, is divided by the gain. If the
load resistance is known, gain error is determined by the
output resistance tolerance. Distortion is low.
an16f
AN16-17
Application Note 16
The 50Ω video line splitter in Figure 46 puts feedback on
one buffer, with others slaved. Offset and gain accuracy
of slaves depends on their matching with master.
Track and Hold
When driving long cables, including a resistor in series
with the output should be considered. Although it reduces
gain, it does isolate the feedback amplifier from the effects
of unterminated lines which present a resonant load.
The buffered input-follower drives the hold capacitor,
C4, through Q1, a low resistance (<5Ω) FET switch. The
positive hold command is supplied by TTL logic with Q3
level shifting to the switch driver, Q2.
When working with wideband amplifiers, special attention should always be paid to supply bypassing, stray
capacitance and keeping leads short. Direct grounding
of test probes, rather than the usual ground clip lead, is
absolutely necessary for reasonable results.
When the FET gate is driven to V– for hold, it pulls charge
that depends upon the input voltage and drain-gate capacitance out of the hold capacitor. A compensating charge is
put into the hold capacitor through C3.
The LT1010 has slew limitations that are not obvious
from standard specifications. Negative slew is subject to
glitching, but this can be minimized with quiescent current boost. The appearance is always worse with fast rise
signal generators than in practical applications.
R2
1.6k
–
A1
HA2625
A2
LT1010
AN16 F45
OUTPUT
+
INPUT
R1
400
Figure 45. Buffer Outside Feedback Loop Gives Capacitive
Load Isolation. Buffer Offset Is Divided by Amplifier Gain,
Gain Error Is Determined by Output Resistance Tolerance
and Distortion Is Low
R3
800
–
C1
20pF
A1
HA2625
INPUT
A2
LT1010
+
R1
50
R2
200
A3
LT1010
R4
39
OUTPUT 1
R5
39
A 5MHz track and hold circuit is shown in Figure 47. It has
a power bandwidth of 400kHz with a ±10V signal swing.
Below the FET pinch voltage, the gate capacitance increases
sharply. Since the FET will always be pinched off in hold,
the turn-off charge from this excess capacitance will be
constant over the input voltage range.
Going into hold, the inverting amplifier, A4, makes the
positive voltage step into C3 proportional to the negative
step on the switch gate, plus a constant to account for
the increased capacitance below pinch-off. The step into
hold is made independent of the input level with R7 and
adjusted to zero with R10 (initially setting up for VIN = ±5V
avoids special problems at input voltage extremes). The
circuit is brought into adjustment range for a particular
design with an appropriate value for C3, although a couple
hundred ohms in series with C3 may be advised for larger
values to insure the stability of A4.
The positive input voltage range is determined by the
common mode range of the op amps. However, if the
output of A4 saturates, gate-capacitance compensation
will be affected.
The input voltage must be above the negative supply by
at least the pinch voltage of the FET to keep it off in hold.
In addition, the negative supply must be sufficient to
maintain current in D2; or gate-capacitance compensation will suffer. The voltage on the emitter of Q2 can be
made more negative than the op amp supplies to extend
the operating range.
OUTPUT 2
AN16 46
OTHER
SLAVES
Figure 46. This Video Line Splitter Has Feedback on One Buffer
with Others Slaved. Offset and Gain Accuracy of Slaves Depends
on Matching with Master
Since internal dissipation can be quite high when driving fast signals into a capacitive load, using a buffer in a
power package is recommended.1 Raising buffer quiescent
current to 40mA with R3 improves frequency response.
Note 1. Overheating of the buffer causes a sharp reduction in slew rate
before thermal limit is activated.
an16f
AN16-18
Application Note 16
V+
R1
2k
INPUT
R3
20
+
A1
LT118A
–
A2
LT1010
C1
50pF
R5
1k
HOLD
R6
1k
OUTPUT
+
+
D2*
6V
A4
LT118A
R4
2k
D1
HP2810
Q3
2N2907
A3
LT118A
C3
100pF
R2
2k
C2
150pF
–
Q1
2N5432
S D
–
C4
1nF
Q2
2N2222
R8
5k
R9
10k
C5
10pF
R10
50k
R7
200k
V–
R11
6.2k
AN16 F47
*2N2369 EMITTER BASE JUNCTION
Figure 47. A 5MHz Track and Hold. With Buffer, Bandwidth and Slew Rate Is Little Affected
by the Hold Capacitor. Compensation for Gate Capacitance of FET Switch Is Included
This circuit is equally useful as a fast acquisition sample
and hold. An LF156 might be used for A3 to reduce drift in
hold because its lower slew rate is not usually a problem
in this application.
R1
100k
0.01%
Maximum output resistance is obtained by trimming the
resistors. High frequency output characteristics will depend
on the bandwidth and slew rate of the op amp, as well
as stray capacitance to the op amp inputs. This ±150mA
current source had a measured output resistance of 3MΩ
and 48nF equivalent output capacitance.
IOUT =
V1
–
A1
LT1012
Bidirectional Current Sources
The voltage-to-current converter in Figure 48 uses the
standard op amp configuration. It has differential input,
so either input can be grounded for the desired output
sense. Output is bidirectional.
R2
100k
0.01%
+
A2
LT1010
R2 (V2 – V1)
R1R4
R4
10
0.1%
IOUT
R3
100k
0.01%
V2
R4
100k
0.01%
AN16 F48
Figure 48. This Voltage/Current Converter Requires Excellent
Resistor Matching or Trimming to Get High Output Resistance.
Buffer Increases Output Current and Capacitive Load Stability
with Small R4
Using an LT118A and lower feedback resistors would give
much lower output capacitance at the expense of output
resistance.
an16f
AN16-19
Application Note 16
In Figure 49, an instrumentation amplifier is used to
eliminate the feedback resistors and any sensitivity to
stray capacitances. The circuit had a measured output
resistance of 6MΩ and an equivalent output capacitance
of 19nF. Pins 7 and 8 of the LM163 are differential inputs,
but they are loaded internally with 50kΩ to V–. Either
input can be grounded to get the desired output sense.
Because of the loading, the input should be driven from
a low impedance source like an op amp.
V+
VREF
200mV
+
8
A1
1/2 LM10
–
2
–
3
+
1
C1
1nF
7
A2
1/2 LM10
R3
15k
A3
LT1010
6
VOUT
C2
500pF
4
R1
20k
AN16 F50
R2
200
Both circuits are stable for all capacitive loads.
A2
LT1010
IOUT =
VIN
10R1
Figure 50. This Voltage Regulator Operates From a Single
Supply Yet Is Adjustable Down to 200mV and Can Source
or Sink Current
Voltage/Current Regulator
VIN
7
–
6
A1
LM163
10X
2
R1
10
0.1%
IOUT
3
AN16 F49
Figure 51 shows a fast power buffer that regulates the
output voltage at VV until the load current reaches a value
programmed by VI. For heavier loads it is a fast, precision
current regulator.
+
5
R2
2k
A1
LT118A
The purpose of C1 is to lower the drive impedance to the
buffer at high frequencies because the high frequency
output impedance of the LM10 runs above 1kΩ. Without
C1 there could be low level oscillation at certain capacitive loads.
It is important to connect Pin 4 of the LM10 and the bottom
of R2 to a common ground point to avoid poor regulation
because of ground loop problems.
D1
1N457
R1
2k
VV
1V/V
OUTPUT
R4
2k
0.1%
–
The circuit’s ability to handle capacitive loads is determined
by R3 and C1. The values given are optimized for up to
1μF output capacitance, as might be required for an IC
test supply.
R3
2Ω
A2
LT1010
+
Voltage Regulator
Even though it operates from a single supply, the circuit
in Figure 50 will regulate voltage down to 200mV. It will
also source or sink current.
C1
1nF
–
R5
2k
0.1%
A3
LT118A
C2
10pF
D2
1N457
+
Figure 49. Voltage/Current Converter Using Instrumentation
Amplifier Does Not Require Matched Resistors
R6
99.8k
0.1%
R7
VI
99.8k
0.1% 10mA/V
Figure 51. This Circuit Is a Power Buffer with Automatic
Transition into Precision, Programmable Current Limit.
Fast, Clean Response Into and Out of Current Limit is a
Feature of the Design.
With output current below the current limit, the current
regulator is disconnected from the loop by D1, with D2
keeping its output out of saturation. This output clamp
enables the current regulator to get control of the output
current from the buffer current limit within a microsecond
for an instantaneous short.
an16f
AN16-20
Application Note 16
In the voltage regulation mode, A1 and A2 act as a fast
voltage follower using the capacitive load isolation technique described earlier. Load transient recovery, as well as
capacitive load stability, are determined by C1. Recovery
from short circuit is clean.
Bidirectional current limit can be provided by adding another op amp connected as a complement to A3. Increased
output current and less sensitivity to capacitive loading
are obtained by paralleling buffers.
This circuit can be used to make an operational power
supply with a bandwidth up to 10MHz that is well suited
to IC testing. Output impedance is low without output capacitors and current limit is fast so that it will not damage
sensitive circuits. The bandwidth and slew rate are reduced
to 2MHz and 15V/μs2 (without paralleling) by the 0.01μF
required for supply bypass on many ICs. Large output
capacitors can be accommodated by switching a larger
capacitor across C1.
Overload Clamping
The input of a summing amplifier is at virtual ground as
long as it is in the active region. With overloads this is no
longer true unless the feedback is kept active.
Figure 53 shows a chopper-stabilized current-to-voltage
converter. It is capable of 10pA resolution, yet is able to
keep the summing node under control with overload currents to ±150mA.
During normal operation, D3 and D4 are not conducting; and R1 absorbs any leakage current from the Zener
clamps, D6 and D7. In overload, current is supplied to
the summing node through the Zener clamps rather than
the scaling resistor, R2. A capacitor on the input absorbs
fast transients.
A2
LT1010
D6
1N746
Supply Splitter
Dual supply op amps and comparators can be operated
from a single supply by creating an artificial ground at
half the supply voltage. The supply splitter in Figure 52
can source or sink 150mA.
The output capacitor, C2, can be made as large as necessary to absorb current transients. An input capacitor is
also used on the buffer to avoid high frequency instability
that can be caused by high source impedance.
V+
C3
0.1μF
R1
10k
A1
LT1010
C1
1nF
R2
10k
V+/2
C2
0.1μF R2
1M
D7
1N746
R1
200
VOUT
D3
1N457
D4
1N457
D1
1N457
D2
1N457
–
IIN
C1
2.2μF
A1
+LT7652
C4
2μF
C3
2μF
AN16 F53
Figure 53. Chopper-Stabilized Current/Voltage Converter Has
Picoampere Sensitivity, Yet Is Capable of Keeping Summing
Node Under Control with 150mA Input Current
Note 2. Slewing large capacitors causes high buffer dissipation.
C2
0.01μF
AN16 F52
Figure 52. Using the Buffer to Supply an Artificial
Ground (V+/2) to Operate Dual Supply Op Amps and
Comparators from a Single Supply
an16f
AN16-21
Application Note 16
Conclusions
A new class-B output stage has been described that is particularly well suited to IC designs. It is fast and avoids the
parasitic oscillation problems of the quasi-complementary
output. This has been combined with the charge storage
transistor, a new diode structure and a novel boost circuit
to make a general-purpose buffer that combines speed,
large output drive and low standby current. The buffer
has been well characterized and shows few disagreeable
characteristics.
The applications section has demonstrated that buffers
can be quite useful in everyday analog design. They also
make touchy wideband amplifiers easy to use. The availability of a low cost, high performance IC buffer should be
a stimulus to expanding upon these applications. Buffers
no longer need to be considered an exotic component;
they will become a standard analog design tool.
Acknowledgement
Thanks are due to Felisa Velasco for special engineering
assembly which was key to product development and
to Guy Hoover for doing most of the experimental work
presented here.
APPENDIX
The following summarizes some design details that might
otherwise be overlooked when first using the buffer. An
equivalent circuit is given, and guaranteed electrical characteristics from the data sheet are listed for reference.
could be used with decoupling resistors. Sometimes the
op amp has much better high frequency rejection on one
supply, so bypass requirements are less on this supply.
Power Dissipation
Supply Bypass
The buffer is no more sensitive to supply bypassing than
slower op amps, as far as stability is concerned. The
0.1μF disc ceramic capacitors usually recommended for
op amps are certainly adequate for low frequency work.
As always, keeping the capacitor leads short and using
a ground plane is prudent, especially when operating at
high frequencies.
The buffer slew rate can be reduced by inadequate supply bypass. With output current changes much above
100mA/μs, using 10μF solid tantalum capacitors on both
supplies is good practice, although bypassing from the
positive to the negative supply may suffice.
When used in conjunction with an op amp and heavily
loaded (resistive or capacitive), the buffer can couple into
supply leads common to the op amp causing stability
problems with the overall loop and extended settling time.
Adequate bypassing can usually be provided by 10μF
solid tantalum capacitors. Alternately, smaller capacitors
In many applications, the LT1010 will require heat sinking. Thermal resistance, junction to still air is 150°C/W
for the TO-39 package, 100°C/W for the TO-220 package
and 60°C/W for the TO-3 package. Circulating air, a heat
sink or mounting the package to a printed circuit board
will reduce thermal resistance.
In DC circuits, buffer dissipation is easily computed. In
AC circuits, signal waveshape and the nature of the load
determine dissipation. Peak dissipation can be several times
average with reactive loads. It is particularly important to
determine dissipation when driving large load capacitance.
With AC loading, power is divided between the two output
transistors. This reduces the effective thermal resistance,
junction to case, to 30°C/W for the TO-39 package and
15°C/W for the TO-3 and TO-220 packages, as long as
the peak rating of neither output transistor is exceeded.
Figure 30 indicates the peak dissipation capabilities of
one output transistor.
an16f
AN16-22
Application Note 16
Overload Protection
idealized buffer with the unloaded gain specified for the
LT1010. Otherwise, it has zero offset voltage, bias current
and output resistance. The output of A1 saturates to its
supply terminals.
The LT1010 has both instantaneous current limit and
thermal overload protection. Foldback current limiting has
not been used, enabling the buffer to drive complex loads
without limiting. Because of this, it is capable of power
dissipation in excess of its continuous ratings.
Loaded voltage gain can be determined from the unloaded
gain, AV, the output resistance, ROUT, and the load resistance, RL, using
Normally, thermal overload protection will limit dissipation and prevent damage. However, with more than 30V
across the conducting output transistor, thermal limiting
is not quick enough to insure protection in current limit.
The thermal protection is effective with 40V across the
conducting output transistor as long as the load current
is otherwise limited to 150mA.
A VL =
A VLRL
ROUT +RL
Maximum positive output swing is given by
VOUT
+
(V
=
Drive Impedance
+
)
– VSOS+ RL
RSAT +RL
where VSOS is the unloaded output saturation voltage and
RSAT is the output saturation resistance.
When driving capacitive loads, the LT1010 likes to be driven
from a low source impedance at high frequencies. Certain
low power op amps (e.g., the LM10) are marginal in this
respect. Some care may be required to avoid oscillations,
especially at low temperatures.
The input swing required for this output is
⎛ R
⎞
VIN+ = VOUT + ⎜ 1+ OUT ⎟ – VOS + ∆VOS
RL ⎠
⎝
Bypassing the buffer input with more than 200pF will solve
the problem. Raising the operating current also works, but
this cannot be done with the TO-39 package.
where ΔVOS is the clipping allowed in making the saturation measurements (100mV)
Equivalent Circuit
The negative output swing and input drive requirements
are determined similarly. The values given in Figure A are
typicals; worst-case numbers are obtained from the data
sheet reproduced on the back page.
Below 1MHz, the LT1010 is quite accurately represented
by the equivalent circuit shown in Figure A for both small
and large signal operation. The internal element, A1, is an
V+
+
IB
75μA
INPUT
+
VOS
70mV
VSOS+
0.9V
R´
7Ω
ROUT
7Ω
A1
AV = 0.999
OUTPUT
RSAT = R´ + ROUT
R´
8Ω
+
VSOS–
0.1V
V–
Figure A. An Idealized Buffer, A1, as Modified by This
Equivalent Circuit Describes the LT1010 at Low Frequencies
an16f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
AN16-23
Application Note 16
Absolute Maximum Ratings
Total Supply Voltage .............................................±22V
Continuous Output Current ............................... ±150mA
Continuous Power Dissipation (Note 1)
LT1010MK...........................................................5.0W
LT101OCK ...........................................................4.0W
LT1010CT............................................................4.0W
LT1010MH ..........................................................3.1W
LT1010CH ...........................................................2.5W
Input Current (Note 2)......................................... ±40mA
Operating Junction Temperature
LT1010M ............................................ –55°C to 150°C
LT1010C................................................ 0°C to 125°C
Storage Temperature Range................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec) .................. 300°C
Connection Diagrams
BOTTOM VIEW
INPUT
PARAMETER
Output Offset Voltage
IB
Input Bias Current
AV
ROUT
Large-Signal Voltage Gain
Output Resistance
Slew Rate
VSOS+
Positive Saturation Offset
VSOS–
Negative Saturation Offset
Note 4, IOUT = 0
RSAT
Saturation Resistance
Note 4, IOUT = ±150mA
VBIAS
Bias Terminal Voltage
IS
Supply Current
Note 5, RBIAS = 20Ω
IOUT = 0, IBIAS = 0
Note 1: For case temperatures above 25°C, dissipation ust be derated
based on a thermal resistance of 25°C/W with the K and T packages or
40°C/W with the H package. See applications information.
Note 2: In current limit or thermal limit, input current increases sharply
with input-output differentials greater than 8V; so input current must be
limited. Input current also rises rapidly for input voltages 8V above V+ or
0.5V below V–.
Note 3: Specifications apply for 4.5V ≤ VS ≤ 40V, V– + 0.5V ≤ VIN ≤ V+
– 1.5V and IOUT = 0, unless otherwise stated. Temperature range is
–55°C ≤ TJ ≤ 150°C, TC ≤ 125°C, for the LT1010M and 0°C ≤ TJ ≤ 125°C,
TC ≤ 100°C, for the LT1010C. The l and boldface type on limits denote
the specifications that apply over the full temperature range.
KOVAR BASE TO-39 PACKAGE
LT1010MH, LT1010CH
FRONT VIEW
V–
5
OUTPUT
4
BIAS
3
V– (TAB)
2
V+
1
INPUT
5-LEAD PLASTIC TO-220
LT1010CT
l
l
VS = ±15V, VIN = ±10V,
VOUT = ±8V, RL = 100Ω
Note 4, IOUT = 0
V– (CASE)
STEEL TO-3 PACKAGE
LT1010MK, LT1010CK
l
IOUT = ±1mA
IOUT = ±150mA
OUTPUT
BIAS
OUTPUT
CONDITIONS (Note 4)
(Note 3)
VS = ±15V, VIN = 0V
IOUT = 0mA
IOUT ≤ 150mA
INPUT
V– (CASE)
Electrical Characteristics
SYMBOL
VOS
BOTTOM VIEW
V+
V+
l
LT1010M
MIN
MAX
20
150
–10
220
40
90
0
150
0
250
0
300
0.995
1.00
6
9
6
9
12
75
LT1010C
MIN
MAX
0
150
–20
220
20
100
0
250
0
500
0
800
0.995
1.00
5
10
5
10
12
75
UNITS
mV
mV
mV
μA
μA
μA
V/V
Ω
Ω
Ω
V/μs
1.0
1.1
0.2
0.3
18
24
810
925
8
9
1.0
1.1
0.2
0.3
22
28
840
880
9
10
V
V
V
V
Ω
Ω
mV
mV
mA
mA
l
l
l
l
l
750
560
700
560
Note 4: The output saturation characteristics are measured with 100mV
output clipping. See applications information for determining available
output swing and input drive requirements for a given load.
Note 5: With the TO-3 and TO-220 packages, output stage quiescent
current can be increased by connecting a resistor between the bias pin
and V+. The increase is equal to the bias terminal voltage divided by this
resistance.
an16f
AN16-24
Linear Technology Corporation
IM/GP 885 2K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 1985