Dominik Stoffel scite author profile

Abstract-This paper proposes a new approach to multilevel logic optimization based on automatic test pattern generation (ATPG). It shows that an ordinary test generator for single stuckat faults can be used to perform arbitrary transformations in a combinational circuit and discusses how this approach relates to conventional multilevel minimization techniques based on Boolean division. Furthermore, effective heuristics are presented to decide what network manipulations are promising for minimizing the circuit. By identifying indirect implications between signals in the circuit, transformations can be derived which are "good" candidates for the minimization of the circuit. A main advantage of the proposed approach is that it operates directly on the structural netlist description of the circuit so that the technical consequences of the performed transformations can be evaluated in an easy way, permitting better control of the optimization process with respect to the specific goals of the designer. Therefore, the presented technique can serve as a basis for optimization techniques targeting nonconventional design goals. This has already been shown for random pattern testability [11] and low-power consumption [28]. This paper only considers area minimization, and our experimental results show that the method presented is competitive with conventional technologyindependent minimization techniques. For many benchmark circuits, our tool Hannover implication tool based on learning (HANNIBAL) achieves the best minimization results published to date. Furthermore, the optimization approach presented is shown to be useful in formal verification. Experimental results show that our optimization-based verification technique works robustly for practical verification problems on industrial designs.

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An Algebraic Approach for Proving Data Correctness in Arithmetic Data Paths

Wienand

Wedler

Stoffel

et al.

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This paper proposes a new approach for proving arithmetic correctness of data paths in System-on-Chip modules. It complements existing techniques which are, for reasons of complexity, restricted to verifying only the control behavior. The circuit is modeled at the arithmetic bit level (ABL) so that our approach is well adapted to current industrial design styles for high performance data paths. Normalization at the ABL is combined with the techniques of computer algebra. We compute normal forms with respect to Gröbner bases over rings Z/ 2 n. Our approach proves tractable for industrial data path designs where standard property checking techniques fail.

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STABLE: A new QF-BV SMT solver for hard verification problems combining Boolean reasoning with computer algebra

Pavlenko

Wedler

Stoffel

et al. 2011

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A Normalization Method for Arithmetic Data-Path Verification

Wedler

Stoffel

Brinkmann³

et al. 2007

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

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Dominik Stoffel

Logic optimization and equivalence checking by implication analysis

An Algebraic Approach for Proving Data Correctness in Arithmetic Data Paths

STABLE: A new QF-BV SMT solver for hard verification problems combining Boolean reasoning with computer algebra

A Normalization Method for Arithmetic Data-Path Verification

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