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The partial scan design methodology has been recognized as a cost-efficient technique to improve the testability of sequential circuits. In this thesis, a flip-flop's value oriented partial scan approach is proposed. The main idea pursued here is to derive a flip-flop selection strategy just from the useful and easily accessed information in the test generation (TG) process. Parameters of UC, SR, TC, and RF are created and updated based on the value of flip-flop. In the end of TG, they are integrated to guide the decision making on flip- flop selection priority. Neither enormous arithmetic computation nor complicated processing is needed in our approach. Also experimental results show that higher fault coverage can be achieved by selecting less flip-flops and inputing less test patterns than those in ETD for most benchmaek circuits.
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