TY - GEN
T1 - Sequential circuits applicable for detecting different types of faults
AU - Levin, I.
AU - Sinelnikov, V.
AU - Karpovsky, M.
AU - Ostanin, S.
N1 - Publisher Copyright:
© 2002 IEEE.
PY - 2002
Y1 - 2002
N2 - This paper presents methods for designing totally self-checking Mealy type synchronous sequential circuits (SSCs). We use implementations of the output and next state functions that are monotonic in state variables. The monotony enables the SSC to react to permanent faults differently than it does to transient faults. If the fault is permanent, the SSC will produce a non-code output, which will be detected as error by the checker after a number of clock cycles. In the case of a transient fault, the SSC is able to survive and to return to normal operation after a number of clock cycles. A novel universal architecture of self-checking SSCs enabling to overcome the above contradiction is proposed. This architecture can be adopted both for reduction of the fault latency of a permanent fault and for increasing the SSC survivability with respect to a transient fault. A method for SSC synthesis for the proposed architecture is presented. This method is oriented to FPGA implementation.
AB - This paper presents methods for designing totally self-checking Mealy type synchronous sequential circuits (SSCs). We use implementations of the output and next state functions that are monotonic in state variables. The monotony enables the SSC to react to permanent faults differently than it does to transient faults. If the fault is permanent, the SSC will produce a non-code output, which will be detected as error by the checker after a number of clock cycles. In the case of a transient fault, the SSC is able to survive and to return to normal operation after a number of clock cycles. A novel universal architecture of self-checking SSCs enabling to overcome the above contradiction is proposed. This architecture can be adopted both for reduction of the fault latency of a permanent fault and for increasing the SSC survivability with respect to a transient fault. A method for SSC synthesis for the proposed architecture is presented. This method is oriented to FPGA implementation.
UR - http://www.scopus.com/inward/record.url?scp=84962656978&partnerID=8YFLogxK
U2 - 10.1109/OLT.2002.1030182
DO - 10.1109/OLT.2002.1030182
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AN - SCOPUS:84962656978
T3 - Proceedings of the 8th IEEE International On-Line Testing Workshop, IOLTW 2002
SP - 44
EP - 48
BT - Proceedings of the 8th IEEE International On-Line Testing Workshop, IOLTW 2002
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 8 July 2002 through 10 July 2002
ER -