1. Normalization.- 2. Signal Flow Diagram.- 3. Open-Loop Control.- 3.1 Basic Concepts.- 3.2 Example of a Calculation.- 3.2.1 Controller.- 3.2.2 Controlled System.- 3.2.3 Signal-flow Diagram.- 3.2.4 Conclusion.- 4. Basic Concepts and Definitions of Feedback Control.- 4.1 Basic Principle of a Feedback Control.- 4.2 The Feedback Control System.- 4.3 Control Requirements.- 4.3.1 Accuracy and Steady-state-stability (Constancy).- 4.3.2 Response to Command and Disturbance.- 5. Calculation of Feedback Control in the Steady-State.- 5.1 Amplification.- 5.2 Steady-State Closed-Loop Amplification.- 5.3 Additive and Multiplicative Disturbances.- 5.4 Basis of Calculation.- 5.4.1 Additive Disturbances.- 5.4.2 Multiplicative Disturbances.- 5.5 Controllable and Noncontrollable Errors.- 5.6 Example.- 5.6.1 Control Element and Controlled System.- 5.6.2 Controller.- 5.6.3 Output Transducer.- 5.6.4 Signal-Flow Diagram.- 5.6.5 Conclusion.- 6. Basic Mathematics of Dynamic Control.- 6.1 Differential Equations (DE’s).- 6.2 Equations of Irrational Elements.- 6.2.1 Dead-Time Elements (DT-Element).- 6.2.2 Characteristic-Curve Elements (CC-Element).- 6.2.3 Multiplier (M-Element).- 6.3 Example.- 6.3.1 Control Amplifier.- 6.3.2 Half-Controlled Single-Phase Bridge Circuit.- 6.3.3 Armature Circuit.- 6.3.4 Developed Torque.- 6.3.5 Accelerating Torque.- 6.3.6 Motor Speed.- 6.3.7 Motor EMF.- 6.3.8 Response.- 7. Unit Step Response.- 7.1 Definition.- 7.2 Unit Step Response of Common Control-Circuit Elements.- 7.2.1 P-Element (Proportional Element).- 7.2.2 I-Element (Integrator).- 7.2.3 PI-Element.- 7.2.4 D-Element (Differentiator).- 7.2.5 PD-Element.- 7.2.6 TD1-Element (First-Order Time-Delay Element).- 7.2.7 TD2-Element (Second-Order Time-Delay Element).- 7.2.8 DD-Element (Time-Delay and Differentiation Element).- 7.2.9 DT-Element (Dead-Time Element).- 7.2.10 Nonlinear Elements.- 7.3 Significance of the unit Step Response.- 8. Sinusoidal Transfer Function.- 8.1 Transformation of DE’s into Transfer-Function Equations.- 8.2 Sinusoidal and Laplace Transfer Functions.- 8.3 Transfer Function and Complex AC Analysis.- 8.4 Transfer Functions of Common Control-Circuit Elements.- 8.5 Example.- 9. System Diagram.- 9.1 Symbolic Representation of Control-System Elements.- 9.1.1 Rational System Elements.- 9.1.2 Irrational System Elements.- 9.2 Example.- 10. Conversion of System Diagrams and Transfer Functions.- 10.1 Conversion Rules for Rational Elements.- 10.2 Conversion Rules for Irrational Elements.- 10.3 Negative and Positive Feedback.- 10.3.1 Negative Feedback.- 10.3.2 Positive Feedback.- 10.3.3 Examples.- 10.4 Resolution of Control-System Elements into P- and I-Elements.- 10.5 Conversion of a TD2-Element.- 10.5.1 Negative Feedback of a TD1- and an I-Element.- 10.5.2 Replacement of a TD2-Element by two Series-Connected TD1-Elements.- 10.5.3 Example: Armature Circuit of DC Drives.- 11. Stability.- 11.1 Definition.- 11.2 Stability Analysis of Positive Feedback.- 11.3 Stability Criteria.- 11.4 The Nyquist Criterion.- 12. Use of Bode Diagrams.- 12.1 Bode Diagrams.- 12.2 Bode Diagrams of Common Control-System Elements.- 12.2.1 P-Element.- 12.2.2 I-Element.- 12.2.3 PI-Element.- 12.2.4 D-Element.- 12.2.5 PD-Element.- 12.2.6 TD1-Element.- 12.2.7 TD2-Element.- 12.2.8 DD-Element.- 12.2.9 Dead-Time Element.- 12.3 Rules for Calculation.- 12.3.1 Multiplication of Transfer-Functions.- 12.3.2 Inversion.- 12.4 Curve-Drawing Instrument.- 12.4.1 Determination of the Phase Angle.- 12.4.2 Conversion $$\left| G \right|$$ of into $${\left| G \right|_}$$.- 12.4.3 Drawing the Gain Characteristic.- 12.5 Stability Analysis by Bode Diagram.- 13. Stabilization of Control Systems without an I-Element in the Controlled System.- 13.1 P-Controller.- 13.2 I-Controller.- 13.3 PI-Controller.- 13.4 PD-Controller.- 13.5 PID-Controller.- 14. Stabilization of Control Systems with an I-Element in the Controlled System.- 14.1 P- and PD-Controllers.- 14.2 I-Controller.- 14.3 PI-Controller.- 14.4 PID-Controller.- 15. Closed Control Loops.- 15.1 Calculation.- 15.2 Approximation Procedure.- 15.3 Nichols Chart.- 16. Normalized Bode Diagrams and Step Responses.- 16.1 Sum of Small Time Constants.- 16.2 Systems with an I-Element in the Controlled System.- 16.2.1 Optimal Stabilization.- 16.2.2 Response to a Unit Step of Command or Disturbance.- 16.2.3 Smoothing of the Command Variable.- 16.3 System without an I-Element in the Controlled System.- 16.3.1 System with Compensation of the Large Time Constant.- 16.3.2 Controller Setting by the Symmetrical Optimum.- 16.3.3 Criteria for Optimum Response to Disturbance.- 16.3.4 Controller Design with $${\phi _x} = - 143^\circ$$ and Symmetrical Stabilization.- 16.4 Summary.- 17. Improvement of Dynamic Behaviour by Internal Loops.- 18. Programming Control Systems on the Analog Computer.- 18.1 Computer Elements.- 18.2 Basis of Programming.- 18.3 Example.- 19. Programming Control Systems on the Digital Computer.- 19.1 Basic Principle.- 20. Hints on Calculating Bode Diagrams with the Digital Computer.- 20.1 Determination of Amplitude and Phase Angle.- 20.2 Amplitude and Phase Angle of the Most Important Control System Elements.- 21. Connection of Control Amplifiers.- 21.1 Negative Feedback.- 21.2 Basic Connections.- 21.3 Controller Connections.- 21.4 Special Connections.- 21.4.1 Smoothing.- 21.4.2 D-Limiting.- 21.4.3 PI-Controller with Adjustable P-Amplification.- 21.4.4 PI-Controller with Adjustable Time Constant.- 21.4.5 PD-Controller with TD1-Element in the Feedback Loop.- 21.4.6 Limiting.- 21.4.7 Inhibition of Control.- 21.4.8 Slope of Characteristic.- 21.5 Control Amplifier Errors.- 21.5.1 Static Errors.- 21.5.2 Dynamic Errors.- 22. Static and Dynamic Characteristics of Line-Commutated Rectifiers.- 22.1 Static Characteristic.- 22.2 Internal Resistance.- 22.3 Dynamic Behaviour.- 22.4 Representation in the System Diagram.- 23. System Diagram of the dc Drive.- 23.1 System Diagram for Variable Field Excitation.- 23.2 System Diagram for Constant Field Excitation.- 24. Speed Control of a Converter Drive with Current Feedback.- 24.1 Connection Diagram.- 24.2 System Diagram.- 24.3 Current Control.- 24.4 Speed Control.- 24.5 Making Allowance for the EMF-Loop.- 25. Voltage Control of Converter Drives.- 25.1 Simple Voltage Control.- 25.2 Voltage Control with Current Feedback.- 25.3 Comments on the System Diagram.- 26. Control of Ward-Leonard Drives.- 26.1 Speed Control with Current Feedback.- 26.2 Speed Control with Current Feedback and Exciter-Current Control.- 27. Speed Control by Field Weakening.- 28. Control with an Oscillatory Mechanical System.- 28.1 System Diagram of an Undamped Two-Mass System.- 28.2 System Diagram of a Damped Two-Mass System.- 28.3 Bode Diagram and Dynamic Behaviour.- 28.4 Determination of Characteristic Values.- 28.5 Measures to Improve Dynamic Behaviour.- 29. Superimposed Control Systems.- 29.1 Control of Tension.- 29.2 Control of a Loop.- 29.3 Control by Level Gauge.- 29.4 Positional Control.- 30. Adaptive Controllers in Drive Systems.- 30.1 Speed Control by Motor Field Weakening.- 30.2 Control of Converter Drives with Discontinuous and Continuous Armature Current.- 30.2.1 System Diagram of the Control for Discontinuous Armature Current.- 30.2.2 Requirements of an Adaptive Armature-Current Controller.- 30.3 Adaptive Speed Controller with Variation of the Run-Up Time Constant.- 31. Digital Control.- 31.1 Digital Feedback Control.- 31.2 The z-Transform.- 31.3 The z-Transform Function of a P-, PI- and PID-Controller.- 31.4 Example of a Digital Control.- 31.4.1 Micro-Controller.- 31.4.2 Current Controller Design.- 31.4.3 Speed Controller Design.- 31.4.4 Controller Algorithm.- References.- Fig. 4 Nichols Chart.- Table 4 The most Important Controller Connections.- Table 5 The most Important Control-System Elements.