Title :
Adjoint techniques for sensitivity analysis in high-frequency structure CAD
Author :
Nikolova, Natalia K. ; Bandler, John W. ; Bakr, Mohamed H.
Author_Institution :
Dept. of Electr. & Comput. Eng., McMaster Univ., Hamilton, Ont., Canada
Abstract :
There is a revival of the interest in adjoint sensitivity analysis techniques. This is partly because current computer-aided-design software based on full-wave electromagnetic (EM) solvers remains too slow for the purposes of practical high-frequency structure design despite the increasing capacity of computers. The adjoint-variable methods for design sensitivity analysis offer computational speed and accuracy. They can be used for efficient gradient-based optimization, in tolerance and yield analysis. Adjoint-based sensitivity analysis for circuits has been well studied and extensively covered in the microwave literature. In comparison, sensitivities with full-wave analysis techniques have attracted little attention, and there have been few applications into feasible and versatile algorithms. We review adjoint-variable methods used in high-frequency structure design with both circuit analysis techniques and full-wave EM analysis techniques. A brief discussion on adjoint-based sensitivity analysis for nonlinear dynamic systems is also included.
Keywords :
S-parameters; circuit CAD; circuit analysis computing; circuit complexity; circuit optimisation; computational electromagnetics; finite difference time-domain analysis; finite element analysis; gradient methods; microwave circuits; mode matching; nonlinear network analysis; reviews; sensitivity analysis; tolerance analysis; FEM; Tellegen approach; adjoint techniques; circuit analysis techniques; computational accuracy; computational speed; finite-difference methods; full-wave EM analysis; gradient-based optimization; high-frequency structure CAD; microwave circuits; mode-matching; nonlinear dynamic systems; sensitivity analysis; tolerance analysis; yield analysis; Algorithm design and analysis; Circuit analysis; Design automation; Design optimization; Electromagnetic modeling; Microwave antennas; Microwave circuits; Physics computing; Power engineering computing; Sensitivity analysis;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2003.820905
