Equivalence checking tools often use a flip-flop matching step to avoid the state space traversal. Due to sequential optimizations performed during synthesis (merge, replication, redundancy removal, ...) and don't care conditions, the matching step can be very complex as well as incomplete. If the matching is incomplete, even the use of a fast and efficient SAT solver during the combinational equivalence-checking step may not prevent the failure of this approach. In this paper, we present a flip-flop matching engine, which is able to verify optimized circuits and handle don't care conditions
Retiming combined with combinational optimization is a power-ful sequential synthesis method. Howeve...
Abstract — Combinational equivalence checking is an essential task in circuit design. In this paper ...
The rapidly increasing complexities of hardware designs are forcing design methodologies and tools t...
Full sequential equivalence checking by state space traversal has been shown to be unpractical for l...
In this paper, we address the problem of verifying the equivalence of two sequential circuits. State...
[[abstract]]In this paper we address the problem of verifying the equivalence of two sequential circ...
Because general algorithms for sequential equivalence checking require a state space traversal of th...
[[abstract]]In this paper, we address the problem of verifying the equivalence of two sequential cir...
Today's digital systems are at the forefront of modern technology. Electronic chips with a billion t...
[[abstract]]In this paper, we present a practical method for verifying the functional equivalence of...
Behavioral synthesis involves generating hardware design via compilation of its Electronic System Le...
Checking the functional equivalence of sequential circuits is an important practical problem. Becaus...
The paper explores several ways to improve the speed and capacity of combinational equivalence check...
Verifying the equivalence of sequential circuits is computationally expensive. Therefore it is inter...
128 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1998.We address the issue of trans...
Retiming combined with combinational optimization is a power-ful sequential synthesis method. Howeve...
Abstract — Combinational equivalence checking is an essential task in circuit design. In this paper ...
The rapidly increasing complexities of hardware designs are forcing design methodologies and tools t...
Full sequential equivalence checking by state space traversal has been shown to be unpractical for l...
In this paper, we address the problem of verifying the equivalence of two sequential circuits. State...
[[abstract]]In this paper we address the problem of verifying the equivalence of two sequential circ...
Because general algorithms for sequential equivalence checking require a state space traversal of th...
[[abstract]]In this paper, we address the problem of verifying the equivalence of two sequential cir...
Today's digital systems are at the forefront of modern technology. Electronic chips with a billion t...
[[abstract]]In this paper, we present a practical method for verifying the functional equivalence of...
Behavioral synthesis involves generating hardware design via compilation of its Electronic System Le...
Checking the functional equivalence of sequential circuits is an important practical problem. Becaus...
The paper explores several ways to improve the speed and capacity of combinational equivalence check...
Verifying the equivalence of sequential circuits is computationally expensive. Therefore it is inter...
128 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1998.We address the issue of trans...
Retiming combined with combinational optimization is a power-ful sequential synthesis method. Howeve...
Abstract — Combinational equivalence checking is an essential task in circuit design. In this paper ...
The rapidly increasing complexities of hardware designs are forcing design methodologies and tools t...