Speech signal distortion in single-sideband radio channels due to intermodulation

Hallak, A. G.

January 1983

No description available.

621.319

Planar transmission line analyses using the Method of Lines

Keen, Alan G.

January 1991

No description available.

621.319

Studies of the transmission properties of waveguide dichroic surfaces

Langsford, P. E.

January 1982

No description available.

621.319

Reduction of spinning reserve requirements on the Northern Ireland electrical power network

McIlwaine, Stephen Andrew

January 1987

No description available.

621.319

Transmission line matrix modelling for semiconductor transport

Chakrabarti, Abhimanyu

January 1996

No description available.

621.319

The miraculous and French society, 950-1100

Morison, P. R.

January 1983

No description available.

621.319

Techniques for power system simulation using multiple processors

Taylor, Alistair James Eden

January 1990

The thesis describes development work which was undertaken to improve the speed of a real-time power system simulator used for the development and testing of control schemes. The solution of large, highly sparse matrices was targeted because this is the most time-consuming part of the current simulator. Major improvements in the speed of the matrix ordering phase of the solution were achieved through the development of a new ordering strategy. This was thoroughly investigated, and is shown to provide important additional improvements compared to standard ordering methods, in reducing path length and minimising potential pipeline stalls. Alterations were made to the remainder of the solution process which provided more flexibility in scheduling calculations. This was used to dramatically ease the run-time generation of efficient code, dedicated to the solution of one matrix structure, and also to reduce memory requirements. A survey of the available microprocessors was performed, which concluded that a special-purpose design could best implement the code generated at run-time, and a design was produced using a microprogrammable floating-point processor, which matched the code produced by the earlier work. A method of splitting the matrix solution onto parallel processors was investigated, and two methods of producing network splits were developed and their results compared. The best results from each method were found to agree well, with a predicted three-fold speed-up for the matrix solution of the C.E.G.B. transmission system from the use of six processors. This gain will increase for the whole simulator. A parallel processing topology of the partitioned network and produce the necessary structures for the remainder of the solution process.

621.319

Mathematical modelling of the optimal power dispatch problem

Ali, Habib K.

January 1990

This thesis is concerned with the optimum operating conditions in a power system. The various aspects of the problem are modelled and solved as a number of optimization problems applying linear programming techniques. A generalized linear mathematical model has been developed for this purpose. A two-stage formulation is adopted to represent the various problems considered. In each case one power system quantity is chosen as an objective function to be optimized under a number of constraints and operating limits relating to the power system relationships and upper and lower bounds on the variables. These include constraints derived from the power flow equations and transmission network capacity. Limits are also imposed on bus voltage magnitudes and generator outputs. With the appropriate selection of the combination of objective function and constraints, the model can be used to minimize the overall generation cost, the total system losses or the total reactive power generation. The two-stage modelling of the problem also allows optimizing two different objective functions at the same time. Two such combinations are possible. In one case the total system losses can be minimized in the first stage and the generation cost minimized in the second stage. The other combination minimizes the total system reactive power output and the active power generation cost. Using the same model, the problem is then solved using decomposition techniques. These imply breaking up the original problem into a number of smaller problems that can be solved almost independently. The mathematical model has been developed in general terms and the associated computer program is written for a general power system. A sample system of medium size has been used to test the validity of the various aspects of the suggested model and produce numerical results.

621.319

Transient analysis of cable systems including the effects of non-linear protective devices

Unver, U.

January 1979

No description available.

621.319

Insulation co-ordination in HVDC transmission

El-Batal, S.

January 1972

No description available.

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