• JSTS:Journal of Semiconductor Technology and Science
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• v.13 no.4
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• pp.303-317
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• 2013

Two novel clocking strategies for a high-speed multi-channel serializer-deserializer (SERDES) are proposed in this paper. Both of the clocking strategies are based on groups, which facilitate flexibility and expansibility of the SERDES. One clocking strategy is applicable to moderate parallel I/O cases, such as high density, short distance, consistent media, high temperature variation, which is used for the serializer array. Each group within the strategy consists of a full-rate phase-locked loop (PLL), a full-rate delay-locked loop (DLL), and two fixed phase alignment (FPA) techniques. The other is applicable to more awful I/O cases such as higher speed, longer distance, inconsistent media, serious crosstalk, which is used for the deserializer array. Each group within the strategy is composed of a PLL and two DLLs. Moreover, a half-rate version is chosen to realize the desired function of 1:2 deserializer. Based on the proposed clocking strategies, two representative ICs for each group of SERDES are designed and fabricated in a standard $0.18{\mu}m$ CMOS technology. Measurement results indicate that the two SERDES ICs can work properly accompanied with their corresponding clocking strategies.

• Journal of the Institute of Electronics Engineers of Korea SD
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• v.39 no.12
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• pp.1055-1061
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• 2002

Conventional TSPC D flip-flop has the advantages of high speed, simple clock distribution, and no racing because of the single phase clocking strategy and its simple structure. But, it suffers from glitch, clock slope sensitivity and unbalanced propagation delay problems. Therefore, a new dynamic D flip-flop, which improves these disadvantages, is proposed. The main idea of this paper is DS(Discharge Suppression) scheme, which suppresses unnecessary discharge. As a result, the proposed structure is free from glitch problem and it improves maximum clock slope immunity from 0.25ns to Ins. Also, it uses only 8 transistors and it Is demonstrated that high speed operation is feasible by balancing propagation delay time.