1. | Y. D. Hsiao, and C. T. Chang*, 2024, “Joint incremental learning network for flexible modeling of carbon dioxide
solubility in aqueous mixtures of amines ,”Separation and Purification Technology, 125299. | |
2. | Y. D. Hsiao, and C. T. Chang*, 2023, “Progressive Learning for Surrogate Modeling of Amine Scrubbing CO2 Capture Processes,” Chem. Eng. Res. Des. 194,
653 - 665. | |
3. | Y. D. Hsiao, and C. T. Chang*, 2023, “Expandable Neural Networks for Efficient Modeling of Various Amine Scrubbing Configurations for CO2 Capture,”
Chem. Eng. Sci. 281, 119191. | |
4. | C. I. Tu, and C. T. Chang, 2023, Comprehensive Modeling and Optimization of Standby Mechanisms in Continuous Chemical Plants. Ind. Eng. Chem. Res., 62,12,5150 – 5169 | |
5. | Shoeb Moon Ali, and C. T. Chang*, Jo-Shu Chang, 2022, “Application of Dynamic Flexibility Index for Process Design Improvement,” Chem. Eng. Res. Des. 185, 368 - 376. | |
6. | Shoeb Moon Ali, and C. T. Chang*, Jo-Shu Chang, 2022, “Application of Dynamic Flexibility Index for Evaluation of Process Control System Designs,” Comput. & Chem. Engng. 166, 107988. | |
7. | F. Y. Lo, C. H. Hsu, and C. T. Chang*, 2021, “Practicable Total-Site Heat
Integration plan for Retrofitting Multiple Heat Exchanger Networks,” Chem.
Eng. Res. Des. 174, 137 - 157. | |
8. | Shoeb Moon Ali, Shang-Wei Hwang, Chuei-Tin Chang∗, Jo-Shu Chang, 2021, "An Effective Numerical Procedure for Evaluating Flexibility Indices of Dynamic Systems with Piecewise Constant Manipulated Variables",
Computers and Chemical Engineering 154, 107464 | |
9. | Sing-Zhi Chan, Chuei-Tin Chang*, 2021, "Optimization of Multilayer Standby Mechanisms inContinuous Processes under Varying Loads", Chemical Engineering Research and Design 166, 89–96 | |
10. | F. Y. Lo, Y. X. Zhu, and C. T. Chang*, 2020, “Optimal Retrofit of a Multiplant Heat Exchanger Network with a Fair Benefit Allocation Plan,” Ind. Eng. Chem. Res., 59, 18088-18105. | |
11. | C. R. Zhang, C. Y. Yeh, and C. T. Chang*, 2020, “Synthesis, Validation, and Evaluation of Operating Procedures
Based on Timed Automata and Dynamic Simulation,” Ind. Eng. Chem. Res., 59, 8769-8782. | |
12. | S. Z. Chan, C. T. Chang*, 2020, “Optimal designs of multi-event interlocks,” Reliability Engineering and System Safety, 199, 106915. | |
13. | S. Z. Chan, H. Y. Liu, Y. K. Luo, and C. T. Chang*, 2020, “Optimization of Multilayer Standby Mechanisms in Continuous Chemical Processes,” Ind. Eng. Chem. Res., 59, 2049-2059. | |
14. | B. H. Li*, Y. E. C. Castillo, and C. T. Chang, 2019, “An improved design method for retrofitting industrial heat exchanger networks based on Pinch Analysis,” Chem. Eng. Res. Des., 148, 260-270. | |
15. | T. Y. Chen, and C. T. Chang*, 2019, “A Design Approach to Synthesize, Validate and Evaluate Operating Procedures based on Untimed Automata and Dynamic Simulation,” Ind. Eng. Chem. Res., 58, 8172-8183. | |
16. | S. T. Feng, Y. C. Chen, and C. T. Chang*, 2019, “An Automata Based Hybrid Modeling Method to Synthesize Sequential Diagnostic Tests,” Chem. Eng. Res. Des., 145, 29-47. | |
17. | H. H. Chang, C. T. Chang*, and B. H. Li, 2018, “Game-Theory Based Optimization Strategies for Stepwise Development of Indirect Interplant Heat Integration Plans,” Energy, 148, 90-111. | |
18. | B. J. Liao, K. T. Yi, and C. T. Chang*, 2018, “Optimal Design Refinements To Accommodate HEN Cleaning Schedules,” Ind. Eng. Chem. Res., 57(3), 997-1013. | |
19. | Y. Jin, C. T. Chang*, S. Li*, and D. Jiang, 2018, “On the use of risk-based Shapley values for cost sharing in interplant heat integration programs,”Applied Energy, 211, 904-920. | |
20. | Y. Y. Lepar, Y. C. Wang, and C. T. Chang*, 2017, “Automatic Generation of Interlock Designs Using Genetic Algorithms,” Computers and Chemical Engineering, 101, 167-192. | |
21. | R. S. Wu, and C. T. Chang*, 2017, “Development of Mathematical Programs for Evaluating Dynamic and Temporal Flexibility Indices Based on KKT Conditions,”J. Taiwan Inst. Chem. Eng, 73, 86-92 | |
22. | C. J. Wang, Y. C. Chen, S. T. Feng, and C.T. Chang*, 2017, "Automata-Based Operating Procedure for Abnormal Situation Management in Batch Processes ," Computers and Chemical Engineering, 97, 220-241 | |
23. | K. Y. Cheng, and C. T. Chang*, 2016, “Model Based Approach to Synthesize Spare-Supported Cleaning Schedules for Existing Heat Exchanger Networks,”Computers and Chemical Engineering, 93, 413–427 | |
24. | W. C. Hsieh, and C. T. Chang*, 2016, “Timed-Automata Based Method for Synthesizing Diagnostic Tests in Batch Processes,” Computers and Chemical Engineering, 84, 12–27 | |
25. | V. S. K. Adi, R. Laxmidewi and C.T. Chang*, 2016, "An Effective Computation Strategy for Assessing Operational Flexibility of High-Dimensional Systems with Complicated Feasible Regions", Chem. Eng. Sci. 147, 137–149 | |
26. | Yi-Chung Kuo and Chuei-Tin Chang*, 2016, "On Heuristic Computation and Application of Flexibility Indices for Unsteady Process Design", Ind. Eng. Chem. Res. 55, 670–682 | |
27. | V. S. K. Adi, and C. T. Chang*, 2015, “Flexibility Analyses and Their Applications in Solar-Driven Membrane Distillation Desalination System Designs,”Chapter 10 in Synthesis, Design and Resource Optimization in Batch Chemical Plants, Majozi, T. (Editor), pp. 233 - 264, CRC Press, Boca Raton, FL (ISBN9781482252415). | |
28. | V. S. K. Adi, and C. T. Chang, 2015, “Development of Flexible Designs for PVFC Hybrid Power Systems,” Renewable Energy, 74,176-186. | |
29. | D. Jiang, and C. T. Chang, 2015, “An Algorithmic Approach to Generate Timesharing Schemes for Multi-Period HEN Designs,” Chem. Eng. Res. Des, 93, 402 - 410. DOI: 10.1016/j.cherd.2014.04.011 | |
30. | C. C. Kuo, and C. T. Chang, 2015, “Improved Model Formulations for MultiPeriod Hydrogen Network Designs,” Ind. Eng. Chem Res. 53, 20204 - 20222. | |
31. | S. L. Cheng, C. T. Chang, D. Jiang , 2014, “A Game-Theory Based Optimization Strategy to Configure Inter-Plant Heat Integration Schemes,” Chem. Eng. Sci. 118, 60 - 73. | |
32. | A. Kang, and C. T. Chang , 2014, “Automata Generated Test Plans for Fault Diagnosis in Sequential Material- and Energy-Transfer Operations,” Chem. Eng. Sci. 113, 101 - 115. | |
33. | Y. C. Chiang,and C. T. Chang , 2014, “Single-Objective and Multiobjective Designs for Hydrogen Networks with Fuel Cells,” Ind. Eng. Chem. Res. 53, 6006 - 6020 (DOI: 10.1021/ie404068p). | |
34. | E. Wibisono, V. S. K. Adi, and C. T. Chang , 2014, “A Model Based Approach to Identify Optimal System Structures and Maintenance Policies for Safety Interlocks with Time-Varying Failure Rates,” Ind. Eng. Chem. Res. 53, 4398 - 4412 (DOI: 10.1021/ie402902q). | |
35. | J. H. Li, C. T. Chang, and D. Jiang, 2014, “Systematic Generation of Cyclic Operating Procedures Based on Timed Automata,” Chem. Eng. Res. Des. 92, 139 - 155. | |
36. | D. Jiang, and C. T. Chang, 2013, “An Algorithmic Revamp Strategy for Improving Operational Flexibility of Multi-Contaminant Water Networks,” Chem.Eng. Sci. 102, 289 - 299. | |
37. | V. S. K. Adi, and C. T. Chang, 2013, “A Mathematical Programming Formulation for Temporal Flexibility Analysis,” Comput. & Chem. Engng. 57, 151-158. | |
38. | V. S. K. Adi, and C. T. Chang, 2013, “SMDDS Design Based on Temporal Flexibility Analysis,” Desalination 320, 96 - 104. | |
39. | D. Jiang, and C. T. Chang, 2013, “A New Approach to Generate Flexible Multi-Period HEN Designs with Timesharing Mechanisms,” Ind. Eng. Chem. Res. 52, 3794 - 3804. | |
40. | B. H. Li, Y. K. Liang, and C. T. Chang, 2013, “Manual design strategies for multi-contaminant water-using networks in batch processes,” Ind. Eng. Chem. Res. 52, 1970 - 1981. | |
41. | C. F. Chen, K. J. Wu, C. T. Chang, D. S. H. Wong, and S. S. Jang, 2013, “Generation and Verification of Optimal Dispatching Policies for Multi-Product Multi-Tool Semiconductor Manufacturing Processes,” Comput. & Chem. En-gng. 52, 112 - 121. | |
42. | E. Sadeli, and C. T. Chang, 2012, “Heuristic Approach to Incorporate Timesharing Schemes in Multi-Period HEN Designs,” Ind. Eng. Chem. Res. 51,7967 - 7987. | |
43. | B. H. Li, and C. T. Chang, 2012, “Judicious Generation of Alternative Water Network Designs with Manual Evolution Strategy,” Chem. Eng. Res. Des. 90,1245 - 1261. | |
44. | M. L. Yeh, and C. T. Chang, 2012, “An Automata-Based Approach to Synthesize Untimed Operating Procedures in Batch Chemical Processes,” Korean. J. Chem. Eng. 29, 583 - 594. | |
45. | M. L. Yeh, and C. T. Chang, 2012, “An Automata Based Method for Online Synthesis of Emergency Response Procedures in Batch Processes,” Comput.&Chem. Engng. 38, 151 - 170. | |
46. | S. Y. Huang, and C. T. Chang, 2012, “An Improved Mathematical Programming Model for Generating Optimal HEN Designs,” Ind. Eng. Chem. Res. 51,3508 - 3515. | |
47. | V. S. K. Adi, and C. T. Chang, 2011, “A Two-Tier Search Strategy to Identify Nominal Operating Conditions for Maximum Flexibility,” Ind. Eng. Chem. Res. 50,10707-10716 | |
48. | M. L. Yeh, and C. T. Chang, 2011, “An Automaton-Based Approach to Evaluate and Improve Online Diagnostic Schemes for Multi-Failure Scenarios in Batch Processes,” Chem. Eng. Res. Des. 89.2652-2666. | |
49. | B. H. Li, and C. T. Chang, 2011, “Multi-Objective Optimization of Water Using Networks with Multiple Contaminats,” Ind. Eng. Chem. Res. 50, 5651-5660. | |
50. | B. H. Li, and C. T. Chang, 2011, “Efficient Flexibility Assessment Procedure for Water Network Designs,” Ind. Eng. Chem. Res. 50, 3763-3774. | |
51. | B. H. Li, and C. T. Chang, 2011, “A Model-Based Search Strategy for Exhaustive Identification of Alternative Water Network Designs,” Ind. Eng. Chem. Res. 50, 3653-3659. | |
52. | Y. H. Lee, C. T. Chang, D. S. H. Wong, and S. S. Jang, 2011, “Petri-Net Based Scheduling Strategy for Semiconductor Manufacturing Processes,” Chem. Eng. Res. Des. 89, 291-300. | |
53. | C. T. Chang and C. Y. Chen, 2011, “Fault Diagnosis with Automata Generated Languages,”Comput. & Chem. Engng. 35, 2, 329-341. | |
54. | L. P. Chung and C. T. Chang, 2011, “Petri-Net Models for Comprehensive Hazard Analysis of MOCVD Processes,” Comput. & Chem. Engng. 35, 2, 356-371. | |
55. | B. H. Li and C. T. Chang, 2011, “Heuristic Evolution Strategies for Simplifying Water-Using Network with Multiple Contaminants,” Chem. Eng. Sci. 66, 558-562. | |
56. | Y. C. Liao, and C. T. Chang, 2010, “Design and Maintenance of Multichannel Protective Systems,” Ind. Eng. Chem. Res. 49, 11421–11433. | |
57. | V. S. K. Adi and C. T. Chang, 2010, “A Sequential Approach to Design Batch Distillation Processes for Homogeneous Azeotropic Systems,” Ind. Eng. Chem. Res. 49, 4308 - 4328. | |
58. | B. H. Li and C. T. Chang, 2010, “Retrofitting Heat Exchanger Networks Based on Simple Pinch Analysis,” Ind. Eng. Chem. Res. 49, 3967 - 3971. | |
59. | Y. C. Chen, M. L. Yeh, C. L. Hong, and C. T. Chang, 2010, “A Petri-Net Based Approach To Configure On-Line Fault Diagnosis Systems for Batch Processes,”Ind. Eng. Chem. Res. 49, 4249 - 4268. | |
60. | E. Riyanto and C. T. Chang, 2010, “A Heuristic Revamp Strategy to Improve Operational Flexibility ofWater Networks Based on Active Constraints,” Chem. Eng. Sci. 65, 2758 - 2770. | |
61. | J. Y. Chen and C. T. Chang, 2009, “Fault Diagnosis Strategies Based on Qualitative Predictions of Symptom Evolution Behaviors,” J. Proc. Cont. 19, 842 - 858. | |
62. | C. T. Chang, B. H. Li and C. W. Liou, 2009,“Development of A Generalized MINLP Model for Assessing and Improving the Operational Flexibility of Water Network Designs,” Ind. Eng. Chem. Res. 48, 3496–3504. | |
63. | H. T. Chen, S. H. Hwang and C. T. Chang, 2009, “Interactive Identification of Continuous-Time Hammerstein and Weiner Systems Using a Two-Stage Estimation Algorithm,” Ind. Eng. Chem. Res. 48, 3, 1495 - 1510. | |
64. | S. H. Hwang, H. T. Chen, and C. T. Chang, 2008, “An Exponentially Weighted Moving Average Method for Identification and Monitoring of Stochastic Systems,” Ind. Eng. Chem. Res. 47, 8239 - 8249. | |
65. | J. Y. Chen and C. T. Chang, 2008, “Development of an Optimal Sensor Placement Procedure Based on Fault Evolution Sequences,” Ind. Eng. Chem. Res. 47, 7335 - 7346. | |
66. | K. H. Liang and C. T. Chang, 2008, “A Simultaneous Optimization Approach to Generate Design Specifications and Maintenance Policies for the Multi-Layer Protective Systems in Chemical Processes,” Ind. Eng. Chem. Res. 47, 5543 - 5555. | |
67. | H. G. Dong, C. Y. Lin and C. T. Chang, 2008, “Simultaneous Optimization Approach for Integrated Water-Allocation and Heat-Exchange Networks,” Chem. Eng. Sci. 63, 3664 - 3678. | |
68. | T. H. Kuo and C. T. Chang, 2008, “Optimal Planning Strategy for the Supply Chains of Light Aromatic Compounds in Petrochemical Industries,” Comput. & Chem. Engng. 32, 6, 1147 - 1166. | |
69. | T. H. Kuo and C. T. Chang, 2008, “Application of a Mathematic Programming Model for Integrated Planning and Scheduling of Petroleum Supply Networks,” Ind. Eng. Chem. Res. 47, 6, 1935 - 1954. | |
70. | H. G. Dong, C. Y. Lin and C. T. Chang, 2008, “Simultaneous Optimization Strategy for Synthesizing Heat Exchanger Networks with Multi-Stream Mixers,” Chem. Eng. Res. Des. 86, 299 - 309. | |
71. | B. H. Li and C. T. Chang, 2007, “A Simple and Efficient Initialization Strategy for Optimizing Water-Using Network Designs,” Ind. Eng. Chem. Res. 46, 25, 8781 - 8786. | |
72. | J. Y. Chen and C. T. Chang, 2007, “Systematic Enumeration of Fuzzy Diagnosis Rules for Identifying Multiple Faults in Chemical Processes,” Ind. Eng. Chem. Res. 46, 11, 3635-3655. | |
73. | J. W. Lai, C. T. Chang and S. H. Hwang, 2007, “Petri-Net Based Binary Integer Programs for Automatic Synthesis of Batch Operating Procedures,” Ind. Eng. Chem. Res. 46, 9, 2797-2813. | |
74. | K. F. Cheng and C. T. Chang, 2007, “Integrated Water Network Designs for Batch Processes,” Ind. Eng. Chem. Res. 46, 4, 1241-1253. | |
75. | B. H. Li and C. T. Chang, 2006, “A Mathematical Programming Model for Discontinuous Water Reuse System Design,” Ind. Eng. Chem. Res. 45, 14, 5027-5036. | |
76. | C. T. Chang and B. H. Li, 2006, “Optimal Design of Wastewater Equalization Systems in Batch Processes,” Comput.& Chem. Engng. 30, 5, 797-806. | |
77. | J. W. Lai, H. H. Chou and C. T. Chang, 2006, “Petri-Net Based Integer Programs for Synthesizing Optimal Material-Transfer Procedures in Pipeline Networks,” Journal of the Chinese Institute of Engineers 29, 2, 337-346. | |
78. | J. Y. Chen and C. T. Chang, 2006, “Fuzzy Diagnosis Method for Control Systems with Coupled Feed Forward and Feedback Loops,” Chem. Eng. Sci. 61, 3105-3128. | |
79. | Y. F. Wang, H. H. Chou and C. T. Chang, 2005, “Generation of Batch Operating Procedures for Multiple Material-Transfer Tasks with Petri Nets,” Comput. & Chem. Engng. 29, 8, 1822-1836. | |
80. | B. H. Li and C. T. Chang, 2005, “Improved Optimization Strategies for Generating Practical Water Usage and Treatment Network Structures,” Ind. Eng. Chem. Res. 44, 10, 3607-3618. | |
81. | N. Balasubramanian, M. L. Yeh, C. T. Chang, and S. J. Chen, 2005, “Hierarchical Petri Nets for Modeling Metabolic Phenotype in Prokaryotes,” Ind. Eng. Chem. Res. 44, 7, 2218-2240. | |
82. | H. H. Chou and C. T. Chang, 2005, “A Petri-Net Based Strategy to Synthesize the Operating Procedures for Cleaning Pipeline Networks,” Ind. Eng. Chem. Res. 44, 1, 114-123. | |
83. | Y. F. Wang and C. T. Chang, 2004, “A Petri-Net Based Deductive Reasoning Strategy for Fault Identification in Batch Processes,” Ind. Eng. Chem. Res. 43, 11, 2704-2720. | |
84. | S. N. Ju, C. L. Chen and C. T. Chang, 2004, “Constructing Fault Trees for the Advanced Process Control Systems - An Application to the Cascade Control Loops,” IEEE Trans. Reliability 53, 1, 43-60. | |
85. | C. A. Lai, C. T. Chang, C. L. Ko and C. L. Chen, 2003, “The Optimal Sensor Placement and Maintenance Strategies for Mass-Flow Networks,” Ind. Eng. Chem. Res. 42, 4366-4375. | |
86. | S. Y. Chang and C. T. Chang, 2003, “A Fuzzy-Logic Based Fault Diagnosis Strategy for Process Control Loops,” Chem. Eng. Sci. 58, 3395-3411 | |
87. | S. N. Ju, C. L. Chen and C. T. Chang, 2003, “Fault Tree Structures of Override Control Systems,” Reliab. Eng. Sys. Saf. 81, 163-181. | |
88. | Y. F. Wang and C. T. Chang, 2003, “A Hierarchical Approach to Construct Petri Nets for Modeling Fault Propagation Mechanisms in Sequential Operations,” Comput. & Chem. Engng. 27, 2, 259-280. | |
89. | N. Balasubramanian, C. T. Chang and Y. F. Wang, 2002, “Petri-Net Models for Risk Analysis of Hazardous Liquid Loading Operations,” Ind. Eng. Chem. Res. 41, 4823-4836. | |
90. | S. Y. Chang, C. R. Lin and C. T. Chang, 2002, “A Fuzzy Diagnosis Approach Using Dynamic Fault Trees,” Chem. Eng. Sci. 57, 2971-2985. | |
91. | C. T. Chang, Y. S. Lin and C. Georgakis, 2002, “A Simple Graphic Approach for Observer Decomposition,” Journal of Process Control 12, 857-873. | |
92. | Y. F. Wang, J. Y. Wu and C. T. Chang, 2002, “Automatic Hazard Analysis of Batch Operations with Petri Nets,” Reliab. Eng. Sys. Saf. 76, 91-104. | |
93. | M. J. Tsai and C. T. Chang, 2001, “Water Usage and Treatment Design Using Genetic Algorithms,” Ind. Eng. Chem. Res. 40, 4874-4888. (NSC89-2214-E006-027) | |
94. | C. T. Chang, C. S. Tsai and K. H. Chen, 2000, “Resilient Alarm Logic Design for Process Networks,” Ind. Eng. Chem. Res. 39, 4974-4985. | |
95. | C. S. Tsai, C. T. Chang, S. W. Yu and C. S. Kao, 2000, “Robust Alarm Generation Strategy,” Comput. & Chem. Engng. 24, 743-748. | |
96. | C. H. Huang, C. T. Chang, H. C. Ling and C. C. Chang, 1999, “A Mathematical Programming Model for Water Usage and Treatment Design,” Ind. Eng. Chem. Res. 38, 7, 2666-2679. | |
97. | C. T. Chang and J. I. Hwang, 1998, “Simplification Techniques for EKF Computations in Fault Diagnosis - Suboptimal Gains,” Chem. Eng. Sci. 53, 22, 3853-3862 (NSC85-2214-E006-015). | |
98. | C. T. Chang and J. I. Hwang, 1998, “Simplification Techniques for EKF Computations in Fault Diagnosis - Model Decomposition,” AIChE Journal 44, 6, 1392-1403. (NSC85-2214-E006-015). | |
99. | C. T. Chang and J. H. Hsia, 1998, “Operating Strategies for Charging Batch Reactors Under Multiple Constraints,” Ind. Eng. Chem. Res. 37, 4, 1364-1371. (NSC86-2214-E006-009) | |
100. | C. S. Tsai and C. T. Chang, 1997, “Optimal Alarm Logic Design for Mass Flow Networks,” AIChE Journal 43, 11, 3021-3030. (NSC86-2214-E006-013) | |
101. | D. H. Kuo, D. S. Hsu, C. T. Chang and D. H. Chen, 1997, “Prototype for Integrated Hazard Analysis,” AIChE Journal 43, 6, 1494-1510. (NSC83-0421-P006-005Z) | |
102. | D. H. Kuo, D. S. Hsu and C. T. Chang, 1997, “A Prototype for Integrating Automatic Fault Tree/Event Tree/HAZOP Analysis,” Comput. & Chem. Engng. 21, Suppl., S923-S928. | |
103. | C. T. Chang and L. C. Chen, 1997, “The Use of Mixers in Heat Recovery System Design,” Chem. Eng. Sci. 52, 2, 183-194. (NSC-85-2214-E-006-027) | |
104. | C. T. Chang, H. C. Hwang, K. S. Hwang and D. S. Hsu, 1997, “The Loop Identification and Classification Algorithms for Digraph-Based Safety Analysis,” Comput. & Chem. Engng. 21, 2, 223-239. (NSC-80-0402-E-006-02) | |
105. | C. T. Chang and J. R. Hwang, 1996, “A Multi-Objective Programming Approach to Waste Minimization in the Utility Systems of Chemical Processes,” Chem. Eng. Sci. 51, 16, 3951-3965. (NSC-83-0402-E-006-012) | |
106. | C. S. Tsai and C. T. Chang, 1996, “Statistical Operating Strategies for Charging the Batch Reactors,” AIChE Journal 42, 5, 1304-1318. | |
107. | C. S. Tsai and C. T. Chang, 1996, “A Statistics Based Approach to Enhancing Safety and Reliability of the Batch-Reactor Charging Operation,” Comput. & Chem. Engng. 20, Suppl., S647-S652. | |
108. | C. S. Tsai, C. T. Chang and C. S. Chen, 1996, “Fault Detection and Diagnosis in Batch and Semi-Batch Processes Using Artificial Neural Networks,” Chem. Eng. Comm. 143, 39-71. (NSC-82-0421-P-006-008Z) | |
109. | C. T. Chang and J. W. Chen, 1995, “Implementation Issues Concerning the EKF-Based Fault Diagnosis Techniques,” Chem. Eng. Sci. 50, 18, 2861-2882. (NSC-84-2214-E-006-008) | |
110. | C. S. Tsai and C. T. Chang, 1995, “Dynamic Process Diagnosis Via Integrated Neural Networks,” Comput.& Chem. Eng. 19, Suppl., S747-S752. (NSC-82-0421-P-006-008Z) | |
111. | C. T. Chang, D. S. Hsu and D. M. Hwang, 1994, “Studies on the Digraph-Based Approach for Fault-Tree Synthesis. 2. The Trip Systems,” I&EC Research 33, 7, 1700-1707. | |
112. | C. T. Chang and K. S. Hwang, 1994, “Studies on the Digraph-Based Approach for Fault-Tree Synthesis. 1. The Ratio-Control Systems,” I&EC Research 33, 6, 1520-1529. | |
113. | C. T. Chang, K. K. Chu and J. R. Hwang, 1994, “Application of the Generalized Stream Structure in HEN Synthesis,” Comput. & Chem. Engng. 18, 4, 345-368. (NSC-81-0402-E-006-545) | |
114. | C. T. Chang, K. N. Mah and C. S. Tsai, 1993, “A Simple Design Strategy for Fault Monitoring Systems,” AIChE Journal 39, 7, 1146-1163. (NSC-81-0414-P-006-15B) | |
115. | C. T. Chang, C. S. Tsai and T. T. Lin, 1993, “The Modified Differential Quadratures and Their Applications,” Chem. Eng. Comm. 123, 135-164. (NSC-79-0402-E-006-08) | |
116. | C. T. Chang and H. C. Hwang, 1992, ”New Developments of the Digraph-Based Techniques for Fault-Tree Synthesis,” I&EC Research 31, 6, 1490-1502. | |
117. | C. T. Chang, 1991, “Letter to the Editor,” Comput. & Chem. Engng. 15, 12, 859. | |
118. | J. R. Quan and C. T. Chang, 1989, ”New Insights in Solving Distributed System Equations by the Quadrature Method - II. Numerical Experiments,” Comput. & Chem. Engng. 13, 9, 1017-1024. | |
119. | J. R. Quan and C. T. Chang, 1989, “New Insights in Solving Distributed System Equations by the Quadrature Method - I. Analysis,” Comput. & Chem. Engng. 13, 7, 779-788. | |
120. | C. T. Chang and J. R. Quan, 1989, “A Unified Approach for Solving Nonlinear Differential Equations in Process Engineering,” IchemE Symp. Ser., No.114, 177-186. | |
121. | C. T. Chang and T. P. Yu, 1988, “Development of An Evolutionary Stream Merging Method in Heat Exchanger Network Design,” IChemE Symp. Ser., No.109, 159-179. | |
122. | C. T. Chang and M. A. F. Epstein, 1987, “Simulation Studies of A Feedback Control Strategy for Batch Crystallizers,” AIChE Symposium Ser., No.253, Vol.83, 110-119. | |
123. | C. T. Chang and M. A. F. Epstein, 1982, “Identification of Batch Crystallization Control Strategies Using Characteristic Curves,” AIChE Symposium Ser., No.215, Vol.78, 68-75. | |