@article{BhattacharyaDimitrievGoessel2000, author = {Bhattacharya, M. K. and Dimitriev, Alexej and G{\"o}ssel, Michael}, title = {Zero-aliasing space compresion using a single periodic output and its application to testing of embedded}, year = {2000}, language = {en} } @article{DimitrievSaposhnikovSaposhnikovetal.1999, author = {Dimitriev, Alexej and Saposhnikov, V. V. and Saposhnikov, Vl. V. and G{\"o}ssel, Michael}, title = {Concurrent checking of sequential circuits by alternating inputs}, year = {1999}, language = {en} } @article{KuentzerKrstić2020, author = {Kuentzer, Felipe A. and Krstić, Miloš}, title = {Soft error detection and correction architecture for asynchronous bundled data designs}, series = {IEEE transactions on circuits and systems}, volume = {67}, journal = {IEEE transactions on circuits and systems}, number = {12}, publisher = {Institute of Electrical and Electronics Engineers}, address = {New York}, issn = {1549-8328}, doi = {10.1109/TCSI.2020.2998911}, pages = {4883 -- 4894}, year = {2020}, abstract = {In this paper, an asynchronous design for soft error detection and correction in combinational and sequential circuits is presented. The proposed architecture is called Asynchronous Full Error Detection and Correction (AFEDC). A custom design flow with integrated commercial EDA tools generates the AFEDC using the asynchronous bundled-data design style. The AFEDC relies on an Error Detection Circuit (EDC) for protecting the combinational logic and fault-tolerant latches for protecting the sequential logic. The EDC can be implemented using different detection methods. For this work, two boundary variants are considered, the Full Duplication with Comparison (FDC) and the Partial Duplication with Parity Prediction (PDPP). The AFEDC architecture can handle single events and timing faults of arbitrarily long duration as well as the synchronous FEDC, but additionally can address known metastability issues of the FEDC and other similar synchronous architectures and provide a more practical solution for handling the error recovery process. Two case studies are developed, a carry look-ahead adder and a pipelined non-restoring array divider. Results show that the AFEDC provides equivalent fault coverage when compared to the FEDC while reducing area, ranging from 9.6\% to 17.6\%, and increasing energy efficiency, which can be up to 6.5\%.}, language = {en} } @article{SaposhnikovOtscheretnijSaposhnikovetal.1998, author = {Saposhnikov, Vl. V. and Otscheretnij, Vitalij and Saposhnikov, V. V. and G{\"o}ssel, Michael}, title = {Design of Fault-Tolerant Circuits by self-dual Duplication}, year = {1998}, language = {en} } @article{MoschaninSaposhnikovSaposhnikovetal.1996, author = {Moschanin, Wladimir and Saposhnikov, Vl. V. and Saposhnikov, Va. V. and G{\"o}ssel, Michael}, title = {Synthesis of self-dual multi-output combinational circuits for on-line Teting}, year = {1996}, language = {en} } @article{SeuringGoesselSogomonyan1998, author = {Seuring, Markus and G{\"o}ssel, Michael and Sogomonyan, Egor S.}, title = {Ein strukturelles Verfahren zur Kompaktierung von Schaltungsausgaben f{\"u}r online-Fehlererkennungen und Selbstests}, year = {1998}, language = {de} } @article{SogomonyanGoessel1996, author = {Sogomonyan, Egor S. and G{\"o}ssel, Michael}, title = {Concurrently self-testing embedded checkers for ultra-reliable fault-tolerant systems}, year = {1996}, language = {en} } @article{MorosovGoesselHartje1999, author = {Morosov, Andrej and G{\"o}ssel, Michael and Hartje, Hendrik}, title = {Reduced area overhead of the input party for code-disjoint circuits}, year = {1999}, language = {en} } @article{SeuringGoessel1999, author = {Seuring, Markus and G{\"o}ssel, Michael}, title = {A structural method for output compaction of sequential automata implemented as circuits}, year = {1999}, language = {en} } @article{HlawiczkaGoesselSogomonyan1997, author = {Hlawiczka, A. and G{\"o}ssel, Michael and Sogomonyan, Egor S.}, title = {A linear code-preserving signature analyzer COPMISR}, isbn = {0-8186-7810-0}, year = {1997}, language = {en} }