lecture 2: non-ideal amps and op-ampsrfic.eecs.berkeley.edu/105/pdf/module1-3_ann_1.pdf ·...
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![Page 1: Lecture 2: Non-Ideal Amps and Op-Ampsrfic.eecs.berkeley.edu/105/pdf/module1-3_ann_1.pdf · 2017-02-10 · Op-Amp Model zThe following model closely resembles the insides of an op-amp](https://reader033.vdocuments.mx/reader033/viewer/2022041808/5e55b2a9b855055f302e20ff/html5/thumbnails/1.jpg)
Department of EECS University of California, Berkeley
Prof. Ali M. Niknejad
Lecture 2: Non-Ideal Amps and Op-Amps
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Practical Op-Amps
z Linear Imperfections:– Finite open-loop gain (A0 < ∞ )– Finite input resistance (Ri < ∞ )– Non-zero output resistance (Ro > 0 )– Finite bandwidth / Gain-BW Trade-Off
z Other (non-linear) imperfections:– Slew rate limitations– Finite swing– Offset voltage– Input bias and offset currents– Noise and distortion
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Simple Model of Amplifier
z Input capacitance and output capacitance are addedz Any amplifier has input capacitance due to
transistors and packaging / board parasiticsz Output capacitance is usually dominated by the
load– Driving cables or a board trace– Intrinsic capacitance of actuator
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Transfer Function
z Using the concept of impedance, it’s easy to derive the transfer function
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Operational Transconductance Amp
z Also known as an “OTA”– If we “chop off” the output stage of an op-amp, we get
an OTAz An OTA is essentially a Gm amplifier. It has a
current output, so if we want to drive a load resistor, we need an output stage (buffer)
z Many op-amps are internally constructed from an OTA + buffer
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Op-Amp Model
z The following model closely resembles the insides of an op-amp.
z The input OTA stage drives a high Z node to generate a very large voltage gain.
z The output buffer then can drive a low impedance load and preserve the high voltage gain
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Op-Amp Gain / Bandwidth
z The dominant frequency response of the op-amp is due to the time constant formed at the high-Z node
z An interesting observation is that the gain-bandwidth product depends on Gm and Cx only
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Preview: Driving Capacitive Loads
z In many situations, the load is capacitor rather than a resistor
z For such cases, we can directly use an OTA (rather than a full op-amp) and the gain / bandwidth product are now determined by the load capacitance
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EE 105 Fall 2016 Prof. A. M. Niknejad
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OTA Power Consumption
z For a fixed load, the current consumption of the OTA is fixed by the gain/bandwidth requirement, assuming load dominates
z Gm scales with current, so driving a larger capacitance requires more power
CL ≫Cx
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Gain/Bandwidth Trade-off
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Open-Loop Frequency Response
A( jw)= A0
1+ jw /wb
A0 : dc gainwb : 3dB frequencywt = A0wb : unity-gain bandwidth(or "gain-bandwidth product")
For high frequency, w >>wb
A( jw)= wt
jw
Single pole response with a dominant pole at ωb
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Bandwidth Extension
z Suppose the core amplifier is single pole with bandwidth:
z When used feedback, the overall transfer function is given by
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Gain / Bandwidth Product in Feedback
z Even though the bandwidth expanded by (1+T), the gain drops by the same factor. So overall the gain-bandwidth (GBW) product is constant
z The GBW product depends only the the Gm of the op-amp and the Cx internal capacitance (or load in the case of an OTA)
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Unity Gain Frequency
z The GBW product is also known as the unity gain frequency.
z To see this, consider the frequency at which the gain drops to unity
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Unity Gain Feedback Amplifier
z An amplifier that has a feedback factor f=1, such as a unity gain buffer, has the full GBW product frequency range
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Closed-Loop Op Amp
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Frequency Response of Closed-Loop Inverting Amplifier Example
Same unity-gain frequency: ftR2
R1
f3dB »A0
R2 / R1
fb
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Non-Dominant Poles
z As we have seen, poles in the system tend to make an amplifier less stable. A single pole cannot do harm since it has a maximum phase shift of 90°
z A second pole in the system is not affected by feedback (prove this) and it will add phase shift as the frequency approaches this second pole
z For this reason, non-dominant poles should be at a much higher frequency than the unity-gain frequency
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Positive Feedback
z Positive Feedback is also usefulz We can create a comparator circuit with hysteresisz Also, as long as T < 1, we can get stable gain … instead
of reducing the gain (negative feedback), positive feedback enhances the gain.
z In theory we can boost the gain to any desired level simply by making T close to unity:
z ε is a very small number– In practice if the gain varies over process / temperature /
voltage, then the circuit can go stable and oscillate– Positive feedback also has a narrow-banding effect
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Back to Circuit Model
z Here’s the equivalent circuit for an amplifier with feedback
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EE 105 Fall 2016 Prof. A. M. Niknejad
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Circuit Interpretation
z Here we see the action of the feedback is to lower the impedance seen by the Gm by the loop gain, which expands the bandwidth by the same factor