• Journal of the Institute of Electronics Engineers of Korea SD
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• v.43 no.9 s.351
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• pp.1-9
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• 2006

In the System-on-Chip(SoC) design, the global wires are critical parts for the performance. Therefore, the global wires need to be pipelined using flip-flops or latches. Since the timing constraint of the latch is more flexible than it of the flip-flop, the latch-based design can provide a better solution for the clock period. Retiming is an optimizing technique which repositions memory elements in the circuits to reduce the clock period. Traditionally, retiming is used on gate-level netlist, but retiming for SoC is used on macro-level netlist. In this paper, we extend the previous work of retiming for SoC using flip-flops to retiming for SoC using single-phase clocked latches. In this paper we propose a MILP for retiming for SoC using single-phase clocked latches, and apply the fixpoint computation to solve it. Experimental results show that retiming for SoC using latches reduces the clock period of circuits by average 10 percent compared with retiming for SoC using flip-flops.

• Journal of the Korean Institute of Intelligent Systems
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• v.10 no.5
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• pp.478-486
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• 2000

This paper proposes a design method that can minimize the power dissipation of CMOS digital circuits without affecting their optimal operation speeds. The proposed method is based on genetic algorithms(GAs) combined to the retiming technique, a circuit transformation technique of repositioning flip-flops. The proposed design method consists of two phases: the phase of retiming for optimizing clock periods and the phase of GA retiming for minimizing power dissipation. Experimental results using Synopsys Design Analyzer show that the proposed design method can reduce the critical path delay of example circuits by about 30-50% and improve the dynamic power performance of the circuits by about 1.4~18.4%.

• JSTS:Journal of Semiconductor Technology and Science
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• v.14 no.4
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• pp.407-418
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• 2014

As the high-throughput requirement in the next generation communication system increases, it becomes essential to implement high-throughput SISO (Soft-Input Soft-Output) decoder with minimal hardware resources. In this paper, we present the comparison results between cascaded radix-4 ACS (Add-Compare-Select) and LUT (Look-Up Table)-based radix-4 ACS in terms of delay, area, and power consumption. The hardware overhead incurred from the retiming technique used for high speed radix-4 ACS operation is also analyzed. According to the various analysis results, high-throughput radix-4 SISO decoding architecture based on simple path metric recovery circuit is proposed to minimize the hardware resources. The proposed architecture is implemented in 65 nm CMOS process and memory requirement and power consumption can be reduced up to 78% and 32%, respectively, while achieving high-throughput requirement.

• The Transactions of the Korea Information Processing Society
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• v.7 no.8
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• pp.2528-2535
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• 2000

Technology mapping is a part of VLSI CAD system, where circuits in logical level are mapped into circuits in physical level. The performance of technology mapping system is evaluatecJ by the delay and area of the resulting circuits. In the sequential circuits, the delay of the circuit is decided by the maximal delay between registers. In this work, we introduce an FPGA mapping algorithm improved by retiming technique used in constructive level and iterative level, and by fuzzy logic technique. Initial circuit is mapped into an FPGA circuit by constructive manner and improved by iterative retiming. Criteria given to the initial circuit are structured hierarchically by decision-making functions of fuzzy logic. The proposed system shows better results than previous systems by the experiments with MCNC benchmarkers.

• The Transactions of the Korea Information Processing Society
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• v.6 no.6
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• pp.1635-1645
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• 1999

In this paper, an intelligent resynthesis technique for timing optimization at the architecture-level has been studied. The proposed technique can remedy the problem which may occur in combinational timing optimization techniques applied to circuits which have the hierarchical subblock structure at the architectural-level. The approach first tries to maintain the original hierarchical subblock while minimizing the longest delay of whole circuit. This paper tries to find a new approach to timing optimization for circuits which have hierarchical structure at architectural-level, and has verified its effectiveness experimentally. We claim its usefulness from the fact that most designers design the circuits hierarchically due to the increase of design complexity.

• Proceedings of the KIEE Conference
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• 1999.07g
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• pp.3181-3183
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• 1999

A CMOS two-stage oscillator applicable to requiring in- and quadrature-phase components such as RF and data retiming applications are presented using phase-look-ahead technique. This paper clearly describes the operation principle of the presented two-stage oscillator and the principle can be also applicable to the high speed high speed divide-by-two is usually used for prescaler of the frequency synthesizer. Also, the sucessful oscillation of the proposed oscillator using PLA is confirmed through the experiment. The test vehicle is designed using 0.8 ${\mu}m$ N-well CMOS process and it has a maximum 914MHz oscillation showing -75dBclHz phase noise at 100kHz offset with single 2V supply.

• Journal of the Korean Institute of Telematics and Electronics D
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• v.36D no.1
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• pp.63-73
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• 1999

This paper presents new pipeline architecure for low power and high speed digital FIR filters. The proposed architecture based on retiming technique achieves enhancement on speed by sharing the input delay stage with multiplication of input data and on power combined with supply voltage scaling down technique. An 8-tap digital FIR filter for PRML disk-drive read channels adopting the proposed pipeline architecture has been designed and fabricated with 0.8${\mu}m$ CMOS double metal process technology. Measured results show that the designed FIR filter operates to 192 MHz in average and dissipates 1.22 mW/MHz at 3.3.V power supply. As a result, the proposed architecture improves speed by about 16% and reduces power dissipation by about 23% when operating at the same throughput.