Feedback
1
Figure 8.1 General structure of the feedback amplifier. This is a signal-flow diagram, and the quantities x represent either voltage or current signals.
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Figure E8.1
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Figure 8.2 Illustrating the application of negative feedback to improve the signal-to-noise ratio in amplifiers.
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Figure 8.3 Illustrating the application of negative feedback to reduce the nonlinear distortion in amplifiers. Curve (a) shows the amplifier transfer
characteristic without feedback. Curve (b) shows the characteristic with negative feedback (β = 0.01) applied.
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Figure 8.4 The four basic feedback topologies: (a) voltage-mixing voltage-sampling (series–shunt) topology; (b) current-mixing current-sampling
(shunt–series) topology; (c) voltage-mixing current-sampling (series–series) topology; (d) current-mixing voltage-sampling (shunt–shunt) topology.
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Figure 8.5 A transistor amplifier with shunt–series feedback. (Biasing not shown.)
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Figure 8.6 An example of the series–series feedback topology. (Biasing not shown.)
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Figure 8.7 (a) The inverting op-amp configuration redrawn as (b) an example of shunt–shunt feedback.
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Figure 8.8 The series–shunt feedback amplifier: (a) ideal structure and (b) equivalent circuit.
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Figure 8.9 Measuring the output resistance of the feedback amplifier of Fig. 8.8(a): Rof : Vt/I.
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Figure 8.10 Derivation of the A circuit and β circuit for the series–shunt feedback amplifier. (a) Block diagram of a practical series–shunt feedback
amplifier. (b) The circuit in (a) with the feedback network represented by its h parameters.
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Figure 8.10 (Continued) (c) The circuit in (b) with h21 neglected.
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Figure 8.11 Summary of the rules for finding the A circuit and β for the voltage-mixing voltage-sampling case of Fig. 8.10(a).
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Figure 8.12 Circuits for Example 8.1.
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Figure 8.12 (Continued)
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Figure E8.5
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Figure 8.13 The series–series feedback amplifier: (a) ideal structure and (b) equivalent circuit.
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Figure 8.14 Measuring the output resistance Rof of the series–series feedback amplifier.
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Figure 8.15 Derivation of the A circuit and the β circuit for series–series feedback amplifiers. (a) A series–series feedback amplifier. (b) The circuit of
(a) with the feedback network represented by its z parameters.
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Figure 8.15 (Continued) (c) A redrawing of the circuit in (b) with z21 neglected.
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Figure 8.16 Finding the A circuit and β for the voltage-mixing current-sampling (series–series) case.
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Figure 8.17 Circuits for Example 8.2.
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Figure 8.17 (Continued)
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Figure 8.17 (Continued).
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Figure 8.18 Ideal structure for the shunt–shunt feedback amplifier.
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Figure 8.19 Block diagram for a practical shunt–shunt feedback amplifier.
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Figure 8.20 Finding the A circuit and β for the current-mixing voltage-sampling (shunt–shunt) feedback amplifier in Fig. 8.19.
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Figure 8.21 Circuits for Example 8.3.
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Figure 8.21 (Continued)
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Figure 8.22 Ideal structure for the shunt–series feedback amplifier.
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Figure 8.23 Block diagram for a practical shunt–series feedback amplifier.
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Figure 8.24 Finding the A circuit and β for the current-mixing current-sampling (shunt–series) feedback amplifier of Fig. 8.23.
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Figure 8.25 Circuits for Example 8.4.
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Figure 8.25 (Continued)
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Figure 8.25 (Continued)
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Figure E8.7
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Figure 8.26 A conceptual feedback loop is broken at XX′ and a test voltage Vt is applied. The impedance Zt is equal to that previously seen looking to
the left of XX′. The loop gain Aβ = –Vr/Vt, where Vr is the returned voltage. As an alternative, Aβ can be determined by finding the open-circuit transfer
function Toc, as in (c), and the short-circuit transfer function Tsc, as in (d), and combining them as indicated.
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Figure 8.27 The loop gain of the feedback loop in (a) is determined in (b) and (c).
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Figure 8.28 The Nyquist plot of an unstable amplifier.
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Figure 8.29 Relationship between pole location and transient response.
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Figure 8.30 Effect of feedback on (a) the pole location and (b) the frequency response of an amplifier having a single-pole open-loop response.
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Figure 8.31 Root-locus diagram for a feedback amplifier whose open-loop transfer function has two real poles.
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Figure 8.32 Definition of ω0 and Q of a pair of complex-conjugate poles.
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Figure 8.33 Normalized gain of a two-pole feedback amplifier for various values of Q. Note that Q is determined by the loop gain according to
Eq. (8.65).
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Figure 8.34 Circuits and plot for Example 8.5.
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Figure 8.35 Root-locus diagram for an amplifier with three poles. The arrows indicate the pole movement as A0β is increased.
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Figure E8.13
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Figure 8.36 Bode plot for the loop gain Aβ illustrating the definitions of the gain and phase margins.
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Figure 8.37 Stability analysis using Bode plot of |A|.
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Figure 8.38 Frequency compensation for β = 10−2. The response labeled A′ is obtained by introducing an additional pole at fD. The A″ response is
obtained by moving the original low-frequency pole to f ′D.
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Figure 8.39 (a) Two cascaded gain stages of a multistage amplifier. (b) Equivalent circuit for the interface between the two stages in (a). (c) Same
circuit as in (b) but with a compensating capacitor CC added. Note that the analysis here applies equally well to MOS amplifiers.
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Figure 8.40 (a) A gain stage in a multistage amplifier with a compensating capacitor connected in the feedback path and (b) an equivalent circuit. Note
that although a BJT is shown, the analysis applies equally well to the MOSFET case.
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Figure 8.41 Circuit of the shunt–series feedback amplifier in Example 8.4.
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Figure 8.42 Circuits for simulating (a) the open-circuit voltage transfer function Toc and (b) the short-circuit current transfer function Tsc of the
feedback amplifier in Fig. 8.41 for the purpose of computing its loop gain.
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Figure 8.43 Circuit for simulating the loop gain of the feedback amplifier circuit in Fig. 8.41 using the replica-circuit method.
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Figure 8.44 (a) Magnitude and (b) phase of the loop gain Aβ of the feedback amplifier circuit in Fig. 8.41.
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Figure P8.4
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Figure P8.19
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Figure P8.26
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Figure P8.30
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Figure P8.32
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Figure P8.33
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Figure P8.34
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Figure P8.35
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Figure P8.38
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Figure P8.39
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Figure P8.40
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Figure P8.42
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Figure P8.44
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Figure P8.46
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Figure P8.48
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Figure P8.51
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Figure P8.52
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Figure P8.81
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