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Direct z-Domain Digital Controller Design. OUTLINE Advantages/disadvantages. Design procedures. Direct z-design examples.

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Presentation on theme: "Direct z-Domain Digital Controller Design. OUTLINE Advantages/disadvantages. Design procedures. Direct z-design examples."— Presentation transcript:

1 Direct z-Domain Digital Controller Design

2 OUTLINE Advantages/disadvantages. Design procedures. Direct z-design examples.

3 Digital from Analog Designs:

4 Direct z-Design Advantage: No approximation. Disadvantages: 1. Controllers: typically same form as Section 6.3, but poles are not restricted to RHP. 2. z-plane is less familiar & selection of pole locations is less intuitive. 3. Stable region inside unit circle (much smaller than left half of the s-plane).

5 Design Procedures Design simplified using MATLAB. ☻ Use Procedures 5.1-3 with minor changes. ☻ Modify (5.14) (for z-domain) (5.14)

6 PD Compensator Zero

7 Example 6.12 Design a digital controller for the type 0 analog plant for I. zero e(∞) due to a unit step, II. ζ = 0.7, and III. Ts ≈ 1s.

8 Solution Select T = 0.02 s, obtain z-transfer function. Zero e( ∞ ) due to step: Use a PI controller type 1, pole at z =1 Zero at z = 0.98, meets the design specs. Results almost identical to Example 6.8

9 Example 6.13 Design a controller for the analog plant to obtain: T s < 1 s, ζ = 0.7

10 Solution Obtain TF for plant, ADC and DAC ( T = 0.01 s ). PD controller: Pole-zero cancellation and add pole at origin (approx. realizable). Controller meets transient response specs. Like Example 6.9

11 Example 6.13 Design a controller in the z-domain for the analog plant for τ < 0.3 s, dominant pole ζ ≥ 0.7, e(∞) due to step input = 0.

12 Solution Plant type 0, same as Example 6.10, let T = 0.005s For e( ∞ ) due to step input = 0, use PI control pole at z = 1, zero at z = 0.995

13 Root Locus for PI Control

14 PID Needed For ζ = 0.7, the closed-loop poles are close to the unit circle (much slower than specified). Need PID controller: cancel pole closest to (not on) the unit circle. Add pole at z = 0 (realizable controller).

15 Root Locus for PID Control

16 Step Response for PID Control

17 Time Response Meets all design specifications < 5 % overshoot with a fast time response Better than Example 6.10 (digital controller via analog design). Analog design can possibly be improved with trial and error (time consuming). Direct design in the z-domain using MATLAB can be easier than indirect design.

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