Introduction to Chapter 1
1. 1 Characteristics of modern power system
1.2 Main tasks of power system dispatching
1.3 development of power system dispatching system and modern dispatching automation system
1.3. 1 China power system zoning and hierarchical dispatching
1.3.2 development of dispatching automation system
1.4 basic structure of dispatching automation system
1.4. 1 information acquisition and control execution subsystem
1.4.2 information transmission subsystem
1.4.3 information processing subsystem
1.4.4 man-machine contact subsystem
Chapter 2 Substation System-Substation Automation
2. 1 Introduction
2.2 The basic content of substation automation
2.2. 1 relay protection function
2.2.2 Monitoring function
2.2.3 Functions of automatic control device
2.2.4 Remote control and data communication functions
2.3 the structure of substation automation
2.3. 1 substation automation design principles and requirements
2.3.2 Centralized substation automation system
2.3.3 Substation automation system with hierarchical and distributed structure and centralized screen installation.
2.3.4 Substation automation system combining decentralized distribution with centralized distribution.
2.4 Development of Substation Automation
Chapter III Data Acquisition of Power System
3. 1 Introduction
3.2 Switch input circuit
3.2. 1 isolation circuit
3.2.2 Filter Dither Circuit
drive control
3.2.4 Address decoding circuit
3.2.5 Input/output control mode
3.3 Switch output circuit
3.4 Analog input circuit
3.5 Analog output circuit
3.5. 1 structural form
3.5.2D/A converter
Chapter IV Data Communication of Power System
4. 1 Introduction
4. 1. 1 Basic functions of power system telecontrol communication
4. 1.2 Basic structure of telecontrol communication in power system
4. 1.3 Basic principles of data communication
4. 1.4 Basic types of telecontrol communication configuration
4.2 Information transmission and channels
4.2. 1 power system transmission channel
Multiplexing
Digital modulation and demodulation
4.3 Error control
4.3. 1 Overview
4.3.2 Error control mode
4.3.3 Classification of error control codes
4.3.4 Several Basic Concepts about Error Control Coding
4.3.5 Introduction of Error Correction Coding Mode
4.3.6 Cyclic redundancy check code
4.4 Basic mode and protocol of telecontrol information transmission
4.4. 1 Overview
4.4.2 Telecontrol Information Transmission Protocol
4. 4. 3 IEC IEC related international standards
Chapter 5 Master Station System -SCADA/EMS System
5. 1 Introduction
5.2 Hardware structure of dispatching automation
5.2. 1 centralized system
distributed system
5.3 System software of dispatching automation system
5.3. 1 operating system
5.3.2 Development Support Environment
5.4 Application Support Platform for Dispatching Automation System
5.4. 1 Task Scheduling and Real-time Communication Subsystem
Database Management System (DBMS)
graphics system
5.5SCADA system
5.5. Basic functions of1SCADA system
5.5.2SCADA database
5.5.3 Evaluation index of SCADA system
5.6 Basic functions of EMS application software
5.7 Safety protection of computer monitoring system and dispatching data network of power grid and power plant
5.8 Development direction of EMS system-standardization and componentization
5.8. 1 open system
Introduction to CORBA
Summarize and analyze
Main advantages
Basic framework of CORBA
IEC 6 1970 standard
Chapter VI Real-time Topology Analysis and State Estimation of Power System
6. 1 Introduction
6. 1. 1 What is a state?
6. 1.2 Who decides the country
6. 1.3 Typical connection mode of plant and station
6.2 Real-time determination of network topology
6.2. 1 Wiring Analysis of Plant and Station
Network connection analysis
6.3 Static State Estimation of Power System
6.3. 1 Overview
6.4 Topological method for observability analysis of measurement system
6.4. 1 Some basic understanding of measurement system analysis
6.4.2 Steps of Observability Analysis
6.4.3 Merging survey islands through boundary injection survey.
6.4.4 Observability analysis based on definite solution conditions of power flow
6.4.5 Errors and bad data of real-time data
6.4.6 Mathematical model of state estimation problem
maximum likelihood estimate
6.5 Power System Static State Estimation Algorithm
6. 5. 1 Newton method to solve the problem of weighted least squares estimation
6.5.2 Fast Decomposition State Estimation Algorithm
6.5.3 Application of Sparse Matrix Technology
6.5.4 Relationship between State Estimation and Conventional Power Flow
6.6 Detection and Identification of Bad Data in Power System State Estimation
6.6. 1 Overview
6.6.2 Residual equation-the relationship between measurement error and residual.
6.6.3 Detection of Bad Data
6.6.4 Identification of bad data
6.7 Robust State Estimation
6.7. 1 Overview
6.7.2m-Estimation
6.7.3 Maximum Exponential Square Robust State Estimation
Chapter VII Real-time Static Security Analysis of Power System
7. 1 Introduction
7. 1. 1 Safety and reliability of power system operation
7. 1.2 Mathematical model of power system operation
7. 1.3 classification of real-time operation state of power system
7. 1.4 power system safety control classification
7. 1.5 general block diagram of safety control function
7.2 Power Flow Algorithm in Static Security Analysis of Power System
7.2. 1 DC power flow method
Newton-Raphson power flow calculation
7.2.3 Fast decoupling power flow calculation
7.3 Static Security Assessment of Power System
7.3. 1 Auxiliary Theorem of Matrix Inversion
7.3.2 Calculation of AC breaking power flow by fast decomposition method
Simulation of generator disconnection
7.4 Safety control countermeasures
7.4. 1 sensitivity analysis
Quasi-steady state sensitivity
7.4.3 Mathematical model of correction control
7.4.4 Solution of control variable variation δ U
7.4.5 Mathematical model of linear programming
7.5 Power system security control countermeasures
7.5. 1 Analysis of active power safety correction countermeasures in power system
7.5.2 Analysis of Countermeasures for Reactive Power Safety Correction in Power System
7.6 Brief Introduction of Optimal Power Flow in Power System
Chapter VIII Automatic Generation Control
8. 1 Introduction
8.2 hierarchical active frequency control
8.2. 1 primary frequency modulation
8.2.2 Secondary frequency modulation
8.2.3 Third frequency modulation
8.3 Automatic Generation Control of Interconnected Power System
8.3. 1 Analysis of automatic frequency modulation characteristics of combined power system
8.3.2 Control area and regional control deviation of interconnected power system
8.3.3 AGC control strategy of single control area in interconnected power system
8.3.4 Application and cooperation of multi-zone control strategy in interconnected power system
8.3.5 Optimal control of multiple areas
8.4 Basic composition and working principle of AGC master station software
Overview of AGC master station software
8.4.2 Basic flow of load frequency control
8.4.3 Time difference correction and unexpected power compensation
8.4.4 AGC Some Problems in AGC
8.5 Determination of performance evaluation criteria and parameters of automatic generation control
Chapter 9 Reactive Power and Voltage Automatic Control
9. 1 Overview
9.2 Basic characteristics of reactive voltage
9.3 reactive power supply, reactive power compensation and voltage regulating equipment
9.3. 1 synchronous generator
electric transmission line
transformer
parallel capacitor
shunt reactor
series capacitor
Synchronous camera
Static compensator
9.4 Automatic Voltage Control of Provincial Power Grid
9.4. 1 Two-stage voltage control mode
9.4.2 Three-level voltage control mode
9.4.3 Model and algorithm of the third-stage voltage control
9.4.4 Model and algorithm of second-stage voltage control
9.4.5 Basic working principle of the first-stage voltage control
9.5 Automatic Voltage Control of Regional Power Grid
9.5. 1 automatic voltage control software structure
filter
Correction control
9.5.4 Global Optimal Control
Safety monitoring module
Chapter 10 dispatcher training system
10. 1 Overview
10.2DTS architecture
Basic concepts of 10.2. 1DTS system
Basic functions and modules of 10.2.2DTS system
10.2.3DTS simulates the room structure.
10.2.4 the position of dts system in the dispatching center network.
10.3 software support platform
10.4 simulation support system (teacher desktop system)
10.4. 1 Teaching plan formulation and management
10.4.2 simulation process control
10.5 power system model
10.5. 1 steady state model
10.5.2 steady-state simulation
10.5.3 dynamic model
10.5.4 transient time domain simulation
10.5.5 Long-term dynamic model
10.6 secondary equipment model
10.6. 1 overview
10.6.2 automatic device model
10.6.3 relay protection model
10.7 control center model
10.7. 1SCADA model
10.7.2PAS model (EMS advanced application model)
10. 7. 3 GC model
10.7.4AVC model
10.8 training evaluation
10.9 integration of dts and EMS
10. 10 Joint training and anti-accident drills of several dispatching centers.
10. 10. 1 centralized model
10. 10.2 decomposition coordination mode
The application of 10. 1 1DTS
10.11.1dispatcher's FM operation, voltage regulation and reactive power control training.
10. 1.2 dispatcher switching operation training
10. 1 1.3 accident handling training
10. 1 1.4 Resume operation training.
10. 1 1.5 secondary system learning
10. 1.6 operation mode research and accident analysis
10. 1 1.7 Study on Power Grid Planning
10.11.8 SCADA/EMS test and evaluation tool
refer to