OP179/OP279
–6–
REV. G
THEORY OF OPERATION
The OP179/OP279 is the latest entry in Analog Devices’ expand-
ing family of single-supply devices, designed for the multimedia
and telecom marketplaces. It is a high output current drive,
rail-to-rail input /output operational amplifier, powered from a
single 5 V supply. It is also intended for other low supply voltage
applications where low distortion and high output current drive
are needed. To combine the attributes of high output current
and low distortion in rail-to-rail input/output operation, novel
circuit design techniques are used.
For example, TPC 1 illustrates a simplified equivalent circuit for
the OP179/OP279’s input stage. It is comprised of two PNP
differential pairs, Q5-Q6 and Q7-Q8, operating in parallel, with
diode protection networks. Diode networks D5-D6 and D7-D8
serve to clamp the applied differential input voltage to the
OP179/OP279, thereby protecting the input transistors against
avalanche damage. The fundamental differences between these
two PNP gain stages are that the Q7-Q8 pair are normally OFF
and that their inputs are buffered from the operational amplifier
inputs by Q1-D1-D2 and Q9-D3-D4. Operation is best under-
stood as a function of the applied common-mode voltage: When
the inputs of the OP179/OP279 are biased midway between the
supplies, the differential signal path gain is controlled by the
resistively loaded (via R7, R8) Q5-Q6. As the input common-mode
level is reduced toward the negative supply (VNEG or GND), the
input transistor current sources, I1 and I3, are forced into satura-
tion, thereby forcing the Q1-D1-D2 and Q9-D3-D4 networks
into cutoff; however, Q5-Q6 remain active, providing input stage
gain. On the other hand, when the common-mode input voltage
is increased toward the positive supply, Q5-Q6 are driven into
cutoff, Q3 is driven into saturation, and Q4 becomes active,
providing bias to the Q7-Q8 differential pair. The point at which
the Q7-Q8 differential pair becomes active is approximately equal
to (VPOS – 1 V).
I2
R5
4k
D7
I1
R6
4k
D8
D5
D6
R3
2.5k
R4
2.5k
Q4
Q3
Q2
Q5
Q6
Q9
Q1
R1
6k
R2
3k
VPOS
VNEG
R7
2.2k
R8
2.2k
I3
D1
D2
D3
D4
VO
–
+
IN–
IN+
Q8
Q7
Figure 1. OP179/OP279 Equivalent Input Circuit
The key issue here is the behavior of the input bias currents
in this stage. The input bias currents of the OP179/OP279 over
the range of common-mode voltages from (VNEG + 1 V) to
(VPOS – 1 V) are the arithmetic sum of the base currents in Q1-Q5
and Q9-Q6. Outside of this range, the input bias currents are
dominated by the base current sum of Q5-Q6 for input signals
close to VNEG, and of Q1-Q5 (Q9-Q6) for input signals close to
VPOS. As a result of this design approach, the input bias currents
in the OP179/OP279 not only exhibit different amplitudes, but
also exhibit different polarities. This input bias current behavior
is best illustrated in TPC 3. It is, therefore, of paramount
importance that the effective source impedances connected to
the OP179/OP279’s inputs are balanced for optimum dc and
ac performance.
100
60
0
10
10k
1k
100
1
40
20
80
FREQUENCY – Hz
VOLTAGE
NOISE
DENSITY
–
nV/
Hz
VS
5V
TA
25 C
TPC 19. Voltage Noise Density vs.
Frequency
120
60
0
1k
1M
100k
10k
100
40
20
80
100
FREQUENCY – Hz
COMMON-MODE
REJECTION
–
dB
TA
25 C
VS
2.5V
TPC 21. Common-Mode
Rejection vs. Frequency
COMMON-MODE VOLTAGE – Volts
60
0
5
30
10
1
20
0
50
40
4
3
2
VOLTAGE
NOISE
DENSITY
–
nV/
Hz
VS
5V
TA
25 C
FREQUENCY
1kHz
TPC 20. Voltage Noise Density vs.
Common-Mode Voltage