Title :
A new dynamic circuit design technique for high performance TSC checker implementations [totally self checking circuits]
Author :
Rao, A. ; Haniotakis, Th ; Tsiatouhas, Y. ; Kaky, V.
Author_Institution :
Dept. of Electr. & Comput. Eng., Southern Illinois Univ., Carbondale, IL, USA
Abstract :
The use of a fault model that handles transistor level faults like transistor stuck-open and transistor stuck-on is highly desirable in modern designs. Unfortunately, in the case of self-checking checkers, exploited for on-line testing, the requirements of using pairs of test vectors or special circuits for IDDQ monitoring may not be applicable. A variation of the dynamic circuit design technique, which uses multiple clocks to construct three phase logic structures, is presented which is capable of covering the above fault models. The proposed technique results in checker designs that combine high operating frequency and reduced area requirements while are capable of satisfying the required self-checking and fault-secure properties. Two-rail code checker designs are presented to demonstrate the proposed technique.
Keywords :
built-in self test; error detection; logic design; logic testing; dynamic three-phase logic; error detection; fault model; fault-secure properties; high performance TSC checker; multiple clocks; self-checking checkers; stuck-on faults; stuck-open faults; totally self-checking circuits; transistor level faults; two-rail code checker; Automatic testing; Circuit faults; Circuit synthesis; Circuit testing; Clocks; Degradation; Frequency; Logic design; Logic testing; Monitoring;
Conference_Titel :
On-Line Testing Symposium, 2004. IOLTS 2004. Proceedings. 10th IEEE International
Print_ISBN :
0-7695-2180-0
DOI :
10.1109/OLT.2004.1319659
