1. Advanced Control of Marine Power System
Raja Toqeer
21 January 2004

2. Introduction
Research focus is on Generator Excitation and Turbine Control.
Marine Power System is chosen as a case study.
Design and Analysis using different Control Methodologies.
Comparison of Control Methodologies
Simulation tools Matlab/Simulink and PSS/E

3. Generator Excitation and Turbine Control
wref
Turbine
Generator
Exciter
AVR
Measurement
Network
Governor Vt
Vref
Fluid Out w If + -
Speed Control
Terminal
Voltage
Control
Fluid in
Value

4. Marine Power System
Integrated Full Electric Propulsion (IFEP) is a proposed marine power system for the next generation Electric Ship.
IFEP power system has economic benefits
Low Running Cost (maintenance & fuel)
Stand alone nature of IFEP allow the designer to address a generator control system that give maximum performance and operational benefits.

5. IFEP Power System Description
IFEP System Topology
Generators
two GTA
two DG.
Propeller load
Induction machine
Services Load
lighting, computer and other ship service
4.1 KV
3.3 KV
0.4 KV
GTA
20MW IM
20MW DG
2MW
2MW
GTA
20MW IM
20MW DG
2MW
2MW

6. IFEP Power System Linearisation
Power System analysis in PSS/E.
Assumed that System dynamics depends upon Propellers operating conditions (OC).
Manoeuvre for Propellers OC is defined.
50 Linear state space models are obtained.
Manoeuvre

7. Open Loop System is Unstable
IFEP Models Analysis
Open Loop System at 50 operating conditions
Eigenvalues
Step Response
Open Loop System is Unstable

8. Motivation for Advanced Control
Traditionally Generator voltage and speed control is perform with AVR & Governors.
Large disturbance changes the system conditions in highly non-linear manner.
Due to this controller parameters may no longer be valid.
Also MIMO nature of IFEP system introduce Electro-Mechanical coupling.
These characteristics provide motivation for advanced control techniques application like Eigenstructure Assignment and Neurocontrol.

9. Conventional Controllers
Conventional Controller (CC)
Voltage is Controlled with AVR
Speed is Controlled with Governor
AVR and Governor both based upon decentralised PID controllers.
PID controllers are designed upon some optimal operating conditions (OC).
The tuning of the PID is required when OC changes to satisfy the performance requirements.

10. Conventional Controllers Configuration
8-Inputs
8-outputs -
Controller
IFEP system r y

11. Eigenstructure Assignment Control
First introduced by Wonham in 1960s for linear multivariable control systems.
Eigenstructure Assignment allows the designer to satisfy Performance requirement with the choice of Eigenvalues and Eigenvectors.
Synthesis technique
Full State Feedback (FSFB) control
Output Feedback control

12. EA Controller Configuration
FSFB Control Law: U= -Kx+Pr
8-Inputs
8-outputs u y r x P B C -
24-States A K
EA Algorithm

13. NeuroController
NeuroController is a control system based upon neural network architecture.
Two Separate NeuroController for Excitation and Turbine Control
A NeuroIdentifier for power system dynamics identifications.
Trained Online Continuously

14. NeuroController Configuration
TDL
Desired
Response
Predictor
IFEP System
TDL
Neuro-
Controller
Error
Neuro-
TDL
Identifier
Error

15. MODEL 1 CONTROLLER RESPONSE
Eigenvalues
Step Response
Specifications
Stability and Performance Requirements Met

16. MODEL 1 CONTROLLER Test Controller 1 is Tested for Model 1 to 10
Eigenvalues
Step Response
Instability and Performance Degradation

17. MULTI MODEL CONTROL STRATEGY
MMC proposed to address the Performance and Robust Stability Issues
Scheduling Variables
(Demand Power)
Controller
Bank
Control
Signals
Inputs
Outputs
IFEP
System -
Design of local Controllers at all operating conditions

18. MULTI MODEL CONTROL TEST
Multi Model Control applied to Model 1 to 10
Eigenvalues
Step Response
Stability and Performance Requirements Met

19. CONCLUSION
Classical Controllers are designed upon linear models and tuning of controllers is required when Operating Conditions changes.
Eigenstructure Assignment Controllers are designed upon linear models; shows better performance then Classical Controllers but lacking in robustness.
NeuroController applied to non-linear system it adjust automatically when Operating Conditions changes.