ADA4051-2ARMZ Analog Devices Inc, ADA4051-2ARMZ Datasheet - Page 15
ADA4051-2ARMZ
Manufacturer Part Number
ADA4051-2ARMZ
Description
IC OPAMP RRIO ZERO DRIFT 8MSOP
Manufacturer
Analog Devices Inc
Datasheet
1.ADA4051-1AKSZ-R7.pdf
(20 pages)
Specifications of ADA4051-2ARMZ
Slew Rate
0.06 V/µs
Amplifier Type
Chopper (Zero-Drift)
Number Of Circuits
2
Output Type
Rail-to-Rail
Gain Bandwidth Product
125kHz
Current - Input Bias
20pA
Voltage - Input Offset
2µV
Current - Supply
13µA
Current - Output / Channel
15mA
Voltage - Supply, Single/dual (±)
1.8 V ~ 5.5 V
Operating Temperature
-40°C ~ 125°C
Mounting Type
Surface Mount
Package / Case
8-MSOP, Micro8™, 8-uMAX, 8-uSOP,
Op Amp Type
Low Power
No. Of Amplifiers
2
Bandwidth
125kHz
Supply Voltage Range
1.8V To 5.5V
Amplifier Case Style
MSOP
No. Of Pins
8
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
-3db Bandwidth
-
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
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THEORY OF OPERATION
The ADA4051-1/ADA4051-2 micropower chopper operational
amplifiers feature a novel, patent-pending technique that sup-
presses offset-related ripple in a chopper amplifier. Instead of
filtering the ripple in the ac domain, this technique nulls the
amplifier’s initial offset in the dc domain, thus preventing ripple
at the overall output.
Auto-zeroing and chopping are two techniques widely used in
high precision CMOS amplifiers to achieve low offset, low offset
drift, and no 1/f noise. Each of these techniques has pros and
cons. Auto-zeroing results in more in-band noise due to aliasing
introduced by sampling. On the other hand, chopping produces
offset-related ripple because it modulates the initial offset
associated with the amplifier up to its chopping frequency.
To accomplish the best noise vs. power trade-off, the chopping
technique is the better approach when designing a low offset
amplifier because there is no increased in-band noise. It is
preferable to suppress the offset-related ripple inside a chopper
amplifier because the offset-related ripple would otherwise need
to be eliminated by an extra off-chip postfilter.
Figure 59 shows the block diagram design of the ADA4051-1/
ADA4051-2 chopper amplifiers employing a local feedback loop
called autocorrection feedback (ACFB). The main signal path
contains an input chopping switch network (CHOP1), a first
transconductance amplifier (Gm1), an output chopping switch
network (CHOP2), a second transconductance amplifier (Gm2),
and a third transconductance amplifier (Gm3). CHOP1 and
CHOP2 operate at 40 kHz of chopping frequency to modulate
the initial offset and 1/f noise from Gm1 up to the chopping
frequency. A fourth transconductance amplifier (Gm4) in the
ACFB senses the modulated ripple at the output of CHOP2,
caused by the initial offset voltage of Gm1. Then, the ripple is
demodulated down to a dc domain through a third chopping
switch network (CHOP3), operating with the same chopping
clock as CHOP1 and CHOP2. Finally, a null transconductance
amplifier (Gm5) tries to null any dc component at the output of
Gm1 that would otherwise appear in the overall output as ripple.
A switched-capacitor notch filter (NF) functions to selectively
suppress the undesired offset-related ripple without disturbing
the desired input signal from the overall input. The desired input
dc signal appears as a dc signal at the output of CHOP2. Then,
the initial offset is modulated up to the chopping frequency by
CHOP3 and filtered out by the NF. Therefore, initial offset does
not create any feedback and does not disturb the desired input
signal. The NF is synchronized with the chopping clock to filter
out the modulated component. In the same manner, the offset
of Gm5 is filtered out by the combination of CHOP3 and the
NF, enabling accurate ripple sensing at the output of CHOP2.
In parallel with the high dc gain path, a feedforward transcon-
ductance amplifier (Gm6) is added to bypass the phase shift
introduced by the ACFB at the chopping frequency. Gm6 is
designed to have the same transconductance as Gm1 to avoid
Rev. B | Page 15 of 20
pole-zero doublets. This design prevents any instability introduced
by the ACFB in the overall feedback loop.
+IN
The voltage noise density, which is equal to the thermal noise
floor dominated by the Gm1, is essentially flat from dc to the
chopping frequency because CHOP1 and CHOP2 eliminate the
1/f noise generated in Gm1 and the ACFB does not contribute
any additional noise. Although the ACFB suppresses the ripple
related to the chopping, there is a remaining voltage ripple. To
further suppress the remaining ripple down to a desired level, it
is recommended to have a postfilter at the output of the amplifier.
The remaining voltage ripple originates from two sources. The
first type of ripple is due to the residual ripple associated with
the initial offset of the Gm1. It is proportional to the magnitude
of the initial offset and creates a spectrum at the chopping
frequency (f
gain buffer, this ripple has a typical value of 4.9 μV rms and a
maximum of 34.7 μV rms. The second type of ripple is due to
the intermodulation between the high frequency input signal
and the chopping frequency. This ripple depends on the input
frequency (f
the difference between the chopping frequency and the input
frequency (f
summation of the chopping frequency and the input frequency
(f
frequencies is shown in Figure 60.
–IN
Figure 60. ADA4051-1/ADA4051-2 Modulated Output Ripple vs. Input Frequency
CHOP
Figure 59. ADA4051-1/ADA4051-2 Chopper Amplifiers Block Diagram
+ f
500
400
300
200
100
CHOP1
0
IN
0
). The magnitude of the ripple for different input
CHOP
IN
CHOP
) and creates a spectrum at frequencies equal to
Gm6 (= Gm1)
1
Gm1
Gm5
). When the amplifier is configured as a unity-
− f
2
IN
), as well as at frequencies equal to the
NF
3
INPUT FREQUENCY (kHz)
CHOP2
CHOP3
ADA4051-1/ADA4051-2
4
Gm4
5
6
7
C3
Gm2
8
C2
Gm3
C1
9
10
OUT
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