This paper examines three algorithmic approaches for the frequency-domain harmonic-balance method in a coupled device and circuit simulator. These are the nonquasi-static, quasi-static, and modified Volterra series approaches. A detailed qualitative and quantitative comparison between these approaches is provided in terms of accuracy and the computational resources required. [ABSTRACT FROM AUTHOR]
Conventional fault simulation techniques for field programmable gate arrays (FPGAs) are very complicated and time consuming. The alternative, FPGA fault emulation technique, is incomplete and can be used only after the FPGA chip is manufactured. In this paper, we present efficient algorithms for computing the fault coverage of a given FPGA test configuration. The faults considered are opens and shorts in FPGA interconnects. The presented technique is able to report all detectable and undetectable faults and, compared with conventional methods, is orders of magnitude faster. [ABSTRACT FROM AUTHOR]
Rizzoli, Vittorio, Masotti, Diego, Mastri, Franco, and Montanari, Emanuele
Subjects
SYSTEM analysis, SYSTEMS design, ALGORITHMS, ELECTRIC circuits, COMPUTER simulation, SIMULATION methods & models, JACOBIAN matrices, NUMERICAL solutions to equations
Abstract
This paper discusses a self-consistent set of modern computational concepts providing an effective approach to the circuit-level harmonic-balance (HB) simulation of nonlinear microwave systems of complex topology. The system is automatically split into the interconnection of a near-optimal number of nonlinear blocks at run time. The resulting structure is then exploited by the domain-partitioning concept. A block-wise constant spectrum is used rather than a common spectrum by considering for each block only the set of spectral lines that are relevant to its electrical function, which leads to a very significant reduction in the number of problem unknowns. System simulation under digitally modulated RF drive is reduced to a sequence of modified multitone HB analyses that are backward coupled through the envelope dynamics. Besides providing high numerical efficiency, this set of techniques opens the way to an effective co-simulation of RF and baseband transceiver sections. [ABSTRACT FROM AUTHOR]