TL/H/8726
Predicting Op Amp Slew Rate Limited Response LB-19
National Semiconductor
Linear Brief 19
August 1972
Predicting Op Amp Slew
Rate Limited Response
The following analysis of sine and step voltage responses
applies to all single dominant pole op amps such as the
LM101A, LM107, LM108A, LM112, LM118 and the LM741.
Each of these op amps has an open loop response curve
with a shape similar to the one shown in
Figure 1
. The dis-
tinguishing feature of this curve is the single low frequency
turnover from a flat response to a uniform b20 dB per dec-
ade of frequency (b6 dB/octave) drop in gain, at least until
the curve passes through the 0 dB line. Closing the loop to
40 dB (X100) as shown with a dotted line on
Figure 1
does
not change the shape of the curve, but it does move the
turnover to a higher frequency. These open loop and closed
loop response curves determine the gain applied to small
signal inputs. The logical question then arises as to when a
signal can no longer be treated as a small signal and the
amplifier response begins to deviate from this curve.
TL/H/8726–1
FIGURE 1. Open and Closed Loop Frequency Response
The answer lies in the slew rate limit of the op amp. The
slew rate limit is the maximum rate of change of the amplifi-
er’s output voltage and is due to the fact that the compensa-
tion capacitor inside the amplifier only has finite currents1
available for charging and discharging. A sinusoidal output
signal will cease being a small signal when its maximum rate
of change equals the slew rate limit Srof the amplifier. The
maximum rate of change for a sine wave occurs at the zero
crossing and may be derived as follows:
voeVPsin 2qft (1)
dvo
dt e2qfV
Pcos 2 qft (2)
dvo
dt Àte0
e2qfV
p(3)
Sre2qfmax Vp(4)
where: voeoutput voltage
Vpepeak output voltage
Sremaximum dvo
dt
The maximum sine wave frequency an amplifier with a given
slew rate will sustain without causing the output to take on a
triangular shape is therefore a function of the peak ampli-
tude of the output and is expressed as:
fmax eSr
2qVp
(5)
Equation 5 demonstrates that the borderline between small
signal response and slew rate limited response is not just a
function of the peak output signal but that by trading off
either frequency or peak amplitude one can continue to
have a distortion free output.
Figure 2
shows a quick refer-
ence graphical presentation of equation 5 with the area
above any VPEAK line representing an undistorted small sig-
nal response and the area below a given VPEAK line repre-
senting a distorted sine wave response due to slew rate
limiting.
TL/H/8726–2
FIGURE 2. Sine Wave Response
As a matter of convenience, amplifier manufacturers often
give a ‘‘full-power bandwidth’’ or ‘‘large signal response’’ on
their specification sheets.
C1995 National Semiconductor Corporation RRD-B30M115/Printed in U. S. A.
LB-19 Predicting Op Amp Slew Rate Limited Response
This frequency can be derived by inserting the amplifier
slew rate and peak rated output voltage into equation 5. The
bandwidth from DC to the resulting fmax is the full-power
bandwidth or ‘‘large signal response’’ of the amplifier. For
example the full-power bandwidth of the LM741 with a 0.5V
msS
ris approximately 6 kHz while the full-power bandwidth
of the LM118 with an Srof 70 V/ms is approximately 900
kHz.
The step voltage response at the output of an op amp can
also be divided into a small signal response and a slew rate
limited response. The signal turnover and uniform b20 dB/
decade slope shown in the small signal frequency response
curve of
Figure 1
are also characteristic of a low pass filter
and one can in fact model an op amp as a low pass RC filter
followed by a very wideband amplifier.
Figure 3
shows a
model of a X100 circuit witha3dBdown rolloff frequency of
TL/H/8726–3
FIGURE 3. Small Signal Op Amp Model
10 kHz. From basic filter theory2the 10% to 90% rise time
of single pole low pass filter is:
tre0.35
f3dB
(6)
which for this example would be 35 ms. Again this small
signal or low pass filter response ceases when the required
rate of change of the output voltage exceeds the slew rate
limit Srof the amplifier. Mathematically stated:
VSTEP
tr
tSr(7)
This means that as soon as the amplitude of the output step
voltage divided by the rise time of the circuit exceeds the Sr
of the amplifier, the amplifier will go into slew rate limiting.
The output will then be a ramp function with a slope of Sr
and a rise time equal to:
tÊreVSTEP
Sr
(8)
Subsituting equation 6 into equation 7 gives the critical val-
ue of VSTEP directly in terms of f3dB:
VSTEP f3db
0.35
tSr(9)
which can be graphed as shown in
Figure 4
. Any point in the
area above a VSTEP line represents an undistorted low pass
filter type response and any point in the area below a given
VSTEP line represents a slew rate limited response.
TL/H/8726–4
FIGURE 4. Step Voltage Response
The above equations and graphs should allow one to avoid
the pitfalls of slew rate limiting and also provide a means of
using engineering tradeoffs to extend the response of the
single dominant pole type of ampilfier.
REFERENCES
1. Solomon, J. E.; Davis, W. R.; and Lee, P. L.:
‘‘A Self-Com-
pensated Monolithic Operational Amplifier With Low Input
Current and High Slew Rate’’,
pp. 14– 15, ISSCC Digest
Tech. Papers, February 1969.
2. Millman, J. and Hawkias, C. C.:
‘‘Electronic Devices and
Circuits’’,
pp. 465– 466, McGraw-Hill Book Company,
New York, 1967.
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