EE 435. Lecture 16. Compensation Systematic Two-Stage Op Amp Design

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1 EE 435 Lecture 16 Compensation Systematic Two-Stage Op Amp Design

2 Review from last lecture Review of Basic Concepts Pole Locations and Stability Theorem: A system is stable iff all closed-loop poles lie in the open left half-plane. Note: Practically want to avoid having closed-loop amplifier poles close to the imaginary axis to provide reasonable stability margin, to minimize ringing in the time-domain, and to minimize peaking in the frequency domain. Im 45 o Typical Acceptable Region for Poles Re 45 o 1 pole-pair angle corresponds to Q= = o 1 pole angle (on pole pair) corresponds to Q = 2

3 Review from last lecture Review of Basic Concepts Nyquist Plots The Nyquist Plot is a plot of the Loop Gain (Aβ) versus j in the complex plane for - < < Theorem: A system is stable iff the Nyquist Plot does not encircle the point -1+j. Note: If there are multiple crossings of the real axis by the Nyquist Plot, the term encirclement requires a formal definition that will not be presented here

4 Review from last lecture Review of Basic Concepts Nyquist Plots DFB s = 1+A sβs Im Im Re -1+j Re s-plane A(s)β -1+j is the image of ALL poles The Nyquist Plot is the image of the entire imaginary axis and separates the image complex plane into two parts Everything outside of the Nyquist Plot is the image of the LHP Nyquist plot can be generated with pencil and paper

5 Review from last lecture Review of Basic Concepts Nyquist Plots Im Phase Margin -1+j Re Unit Circle Phase margin is 18 o angle of Aβ when the magnitude of Aβ =1

6 Review from last lecture Review of Basic Concepts Nyquist Plots Im Gain Margin -1+j Re Unit Circle Gain margin is 1 magnitude of Aβ when the angle of Aβ =18 o

7 Review of Basic Concepts Nyquist Plots Theorem: A system is stable iff the phase margin is positive Theorem: A system is stable iff the gain margin is positive The phase margin is often the parameter that is specified when compensating operational amplifiers Phase margins of 45 o to 6 o or sometimes even 75 o are often used The definition of phase margin does not depend upon the order of the system and is affected by the location of the zeros of the system The phase margin is a function of β

8 Review of Basic Concepts Nyquist Plots Engineers have some comfort in how far an amplifier is from becoming stable when specifying phase margin criteria (but this is often not mathematically justifiable) Pole Q criteria are generally much better to use than phase margin criteria but industry is heavily phase-margin entrenched! Separate magnitude and phase plots are often used rather than Nyquist Plots when assessing phase margins or gain margins The magnitude and phase plots convey exactly the same information as Nyquist Plots but have a linear (or logarithmic) axis rather than the highly skewed imaginary axis of the Nyquist Plot

9 Example A feedback amplifier has a characteristic polynomial of D(s) s 2 9s 1.8E3 Without using the quadratic equation, determine the poles by inspection and determine the ratio of the two poles.

10 solution A feedback amplifier has a characteristic polynomial of D(s) s 2 9s 1.8E3 D(s) s 2 9s 1.8E3 P h =-9 D(s) s 2 9s 1.8E3 P L =-2 Ratio = 45

11 Review Analysis of two-stage op amps is very systematic and can be done by inspection if characteristics of quarter circuit are known Compensation is essential for stability when applying feedback Miller compensation is very useful for decreasing size of internal compensation capacitor but it does not act as a shunting capacitor at high frequencies Nyquist plots are a viable alternative for determining stability from the loop gain Nyquist plot is a mapping by the function Aβ from the s-plane to the s-plane and the image of the imaginary axis is the Nyquist plot Phase margin (and sometimes gain margin) are widely used to specify compensation expectations but probably not as useful as pole-q compensation criterion however legacy will keep these concepts around for a long time

12 Nyquist and Gain-Phase Plots Nyquist and Gain-Phase Plots convey identical information but gain-phase plots often easier to work with Mag 7 6 = Im Mag Phase Re j = - = Phase Note: The two plots do not correspond to the same system in this slide

13 Angle in degrees Magnitude in db Gain and Phase Margin Examples β 1 T(s) 1 s o Phase Margin

14 Angle in degrees Magnitude in db Gain and Phase Margin Examples Gain Margin β 1 T(s) 1 s o -25-3

15 Angle in degrees Magnitude in db Gain and Phase Margin Examples β 1 T(s) 1 s Phase Margin -18 o -25-3

16 Angle in degrees Magnitude in db Gain and Phase Margin Examples β 1 Gain Margin T(s) 1 s o -25-3

17 Angle in degrees Magnitude in db Gain and Phase Margin Examples β 1 1 T(s) s Phase Margin -18 o

18 Angle in degrees Magnitude in db Gain and Phase Margin Examples T(s) s 1 s Be aware of the multiple values of the arctan function!

19 Angle in degrees Magnitude in db Gain and Phase Margin Examples β 1 T(s) s 1 s Phase Margin

20 Angle in degrees Magnitude in db Gain and Phase Margin Examples 8 6 T(s) s 1 s β Phase Margin

21 Relationship between pole Q and phase margin In general, the relationship between the phase margin and the pole Q is dependent upon the order of the transfer function and on the location of the zeros In the special case that the open loop amplifier is second-order lowpass, a closed form analytical relationship between pole Q and phase margin exists and this is independent of A and β.. Q cos(φ sin(φ M M ) ) φ M cos Q 4 1 2Q 2 The region of interest is invariable only for.5 < Q <.7 larger Q introduces unacceptable ringing and settling smaller Q slows the amplifier down too much

22 Pole Q Phase Margin vs Q Second-order low-pass Amplifier Phase Margin

23 Phase Margin vs Q Second-order low-pass Amplifier Pole Q Phase Margin

24 Phase Margin vs Q Second-order low-pass Amplifier Pole Q Phase Margin

25 Magnitude Response of 2 nd -order Lowpass Function Q MAX for no peaking = Q From Laker-Sansen Text

26 Phase Response of 2 nd -order Lowpass Function 1 2Q From Laker-Sansen Text

27 Step Response of 2 nd -order Lowpass Function 1 2Q Q MAX for no overshoot = 1/2 From Laker-Sansen Text

28 Step Response of 2 nd -order Lowpass Function 1 2Q From Laker-Sansen Text

29 Compensation Summary Gain and phase margin performance often strongly dependent upon architecture Relationship between overshoot and ringing and phase margin were developed only for 2 nd -order lowpass gain characteristics and differ dramatically for higher-order structures Absolute gain and phase margin criteria are not robust to changes in architecture or order It is often difficult to correctly break the loop to determine the loop gain Aβ with the correct loading on the loop (will discuss this more later)

30 End of Lecture 16

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