Quantitative Process Control Theory

Book description

Quantitative Process Control Theory explains how to solve industrial system problems using a novel control system design theory. This easy-to-use theory does not require designers to choose a weighting function and enables the controllers to be designed or tuned for quantitative engineering performance indices such as overshoot.In each chapter, a s

Table of contents

  1. Front Cover
  2. Dedication
  3. Contents
  4. List of Figures (1/2)
  5. List of Figures (2/2)
  6. List of Tables
  7. Symbol Description
  8. Preface
  9. About the Author
  10. 1. Introduction (1/4)
  11. 1. Introduction (2/4)
  12. 1. Introduction (3/4)
  13. 1. Introduction (4/4)
  14. 2. Classical Analysis Methods (1/6)
  15. 2. Classical Analysis Methods (2/6)
  16. 2. Classical Analysis Methods (3/6)
  17. 2. Classical Analysis Methods (4/6)
  18. 2. Classical Analysis Methods (5/6)
  19. 2. Classical Analysis Methods (6/6)
  20. 3. Essentials of the Robust Control Theory (1/6)
  21. 3. Essentials of the Robust Control Theory (2/6)
  22. 3. Essentials of the Robust Control Theory (3/6)
  23. 3. Essentials of the Robust Control Theory (4/6)
  24. 3. Essentials of the Robust Control Theory (5/6)
  25. 3. Essentials of the Robust Control Theory (6/6)
  26. 4. H∞ PID Controllers for Stable Plants (1/8)
  27. 4. H∞ PID Controllers for Stable Plants (2/8)
  28. 4. H∞ PID Controllers for Stable Plants (3/8)
  29. 4. H∞ PID Controllers for Stable Plants (4/8)
  30. 4. H∞ PID Controllers for Stable Plants (5/8)
  31. 4. H∞ PID Controllers for Stable Plants (6/8)
  32. 4. H∞ PID Controllers for Stable Plants (7/8)
  33. 4. H∞ PID Controllers for Stable Plants (8/8)
  34. 5. H2 PID Controllers for Stable Plants (1/8)
  35. 5. H2 PID Controllers for Stable Plants (2/8)
  36. 5. H2 PID Controllers for Stable Plants (3/8)
  37. 5. H2 PID Controllers for Stable Plants (4/8)
  38. 5. H2 PID Controllers for Stable Plants (5/8)
  39. 5. H2 PID Controllers for Stable Plants (6/8)
  40. 5. H2 PID Controllers for Stable Plants (7/8)
  41. 5. H2 PID Controllers for Stable Plants (8/8)
  42. 6. Control of Stable Plants (1/7)
  43. 6. Control of Stable Plants (2/7)
  44. 6. Control of Stable Plants (3/7)
  45. 6. Control of Stable Plants (4/7)
  46. 6. Control of Stable Plants (5/7)
  47. 6. Control of Stable Plants (6/7)
  48. 6. Control of Stable Plants (7/7)
  49. 7. Control of Integrating Plants (1/8)
  50. 7. Control of Integrating Plants (2/8)
  51. 7. Control of Integrating Plants (3/8)
  52. 7. Control of Integrating Plants (4/8)
  53. 7. Control of Integrating Plants (5/8)
  54. 7. Control of Integrating Plants (6/8)
  55. 7. Control of Integrating Plants (7/8)
  56. 7. Control of Integrating Plants (8/8)
  57. 8. Control of Unstable Plants (1/8)
  58. 8. Control of Unstable Plants (2/8)
  59. 8. Control of Unstable Plants (3/8)
  60. 8. Control of Unstable Plants (4/8)
  61. 8. Control of Unstable Plants (5/8)
  62. 8. Control of Unstable Plants (6/8)
  63. 8. Control of Unstable Plants (7/8)
  64. 8. Control of Unstable Plants (8/8)
  65. 9. Complex Control Strategies (1/8)
  66. 9. Complex Control Strategies (2/8)
  67. 9. Complex Control Strategies (3/8)
  68. 9. Complex Control Strategies (4/8)
  69. 9. Complex Control Strategies (5/8)
  70. 9. Complex Control Strategies (6/8)
  71. 9. Complex Control Strategies (7/8)
  72. 9. Complex Control Strategies (8/8)
  73. 10. Analysis of MIMO Systems (1/6)
  74. 10. Analysis of MIMO Systems (2/6)
  75. 10. Analysis of MIMO Systems (3/6)
  76. 10. Analysis of MIMO Systems (4/6)
  77. 10. Analysis of MIMO Systems (5/6)
  78. 10. Analysis of MIMO Systems (6/6)
  79. 11. Classical Design Methods for MIMO Systems (1/4)
  80. 11. Classical Design Methods for MIMO Systems (2/4)
  81. 11. Classical Design Methods for MIMO Systems (3/4)
  82. 11. Classical Design Methods for MIMO Systems (4/4)
  83. 12. Quasi-H∞ Decoupling Control (1/6)
  84. 12. Quasi-H∞ Decoupling Control (2/6)
  85. 12. Quasi-H∞ Decoupling Control (3/6)
  86. 12. Quasi-H∞ Decoupling Control (4/6)
  87. 12. Quasi-H∞ Decoupling Control (5/6)
  88. 12. Quasi-H∞ Decoupling Control (6/6)
  89. 13. H2 Decoupling Control (1/6)
  90. 13. H2 Decoupling Control (2/6)
  91. 13. H2 Decoupling Control (3/6)
  92. 13. H2 Decoupling Control (4/6)
  93. 13. H2 Decoupling Control (5/6)
  94. 13. H2 Decoupling Control (6/6)
  95. 14. Multivariable H2 Optimal Control (1/8)
  96. 14. Multivariable H2 Optimal Control (2/8)
  97. 14. Multivariable H2 Optimal Control (3/8)
  98. 14. Multivariable H2 Optimal Control (4/8)
  99. 14. Multivariable H2 Optimal Control (5/8)
  100. 14. Multivariable H2 Optimal Control (6/8)
  101. 14. Multivariable H2 Optimal Control (7/8)
  102. 14. Multivariable H2 Optimal Control (8/8)
  103. Bibliography (1/3)
  104. Bibliography (2/3)
  105. Bibliography (3/3)

Product information

  • Title: Quantitative Process Control Theory
  • Author(s): Weidong Zhang
  • Release date: December 2011
  • Publisher(s): CRC Press
  • ISBN: 9781439855614