P
Pei-Hsin Ho
Researcher at Synopsys
Publications - 48
Citations - 6345
Pei-Hsin Ho is an academic researcher from Synopsys. The author has contributed to research in topics: Model checking & Hybrid system. The author has an hindex of 28, co-authored 48 publications receiving 6233 citations. Previous affiliations of Pei-Hsin Ho include Cornell University & Intel.
Papers
More filters
Book ChapterDOI
Hybrid Automata: An Algorithmic Approach to the Specification and Verification of Hybrid Systems
TL;DR: This work presents two semidecision procedures for verifying safety properties of piecewiselinear hybrid automata, in which all variables change at constant rates, and demonstrates that for many of the typical workshop examples, the procedures do terminate and thus provide an automatic way for verifying their properties.
Journal ArticleDOI
HYTECH: a model checker for hybrid systems
TL;DR: HyTech is a symbolic model checker for linear hybrid automata, a subclass of hybrids that can be analyzed automatically by computing with polyhedral state sets that combines automaton transitions for capturing discrete change with differential equations for capturing continuous change.
Journal ArticleDOI
Automatic symbolic verification of embedded systems
TL;DR: The model-checking procedure and the implementation of the verification procedure-implemented in the Cornell Hybrid Technology tool, HyTech-applies to hybrid automata whose continuous dynamics is governed by linear constraints on the variables and their derivatives.
Proceedings ArticleDOI
Automatic symbolic verification of embedded systems
TL;DR: A model checking procedure and its implementation for the automatic verification of embedded systems, used to prove digital controllers and distributed algorithms correct in hybrid automata systems.
Book ChapterDOI
HYTECH: A Model Checker for Hybrid Systems
TL;DR: HyTech is a symbolic model checker for linear hybrid automata, an expressive, yet automatically analyzable, subclass of hybrids, and a key feature of HyTech is its ability to perform parametric analysis, i.e. to determine the values of design parameters for which alinear hybrid automaton satisfies a temporal requirement.