• Electronics and Telecommunications Trends
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• v.19 no.2 s.86
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• pp.138-146
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• 2004

시스템 연결에 사용되는 프로토콜이 고속, 직렬화 됨에 따라 CDR이 내장된 SERDES 칩의 사용이 늘어나고 있다. 이에 Xilinx 나 Altera 사 등 FPGA 업체들이 SERDES를 FPGA 내장시킨 제품을 출시하기 시작하였다. 이러한 SERDES 임베디드 FPGA는 PCB 설계의 단순화와 신호무결성의 큰 이점이 있다. 본 고에서는 Altera 사의 SERDES 임베디드 FPGA, Stratix-GX 디바이스의 기가비트 트랜시버 ALTGXB 블록의 테스트에 관해 살펴본다.

• 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.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.36 no.10B
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• pp.1150-1158
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• 2011

More than 100 Mbps rate is needed in the UBcN for a subscriber to receive broadband traffics with multi-channel like UDTV or 3DTV. Although the optical fiber is recently deployed for the FTTH, the UTP is the most widely used medium and will be used in UBcN age. Network providers may consider the 1000BASE-T or the vectorized VDSL if they adopts the UTP in the place where does not have optical fibers. But UTP should be expanded because 1000BASE-T and vectorized UTP needs 4 and 3 pairs cable, respectively while residential region has not exceeding 2 pair UTP cable. To solve the problem, we propose a 500BASE-T technology using 2 pairs UTP in this paper. The technology introduces a rate adaptation sublayer and a SERDES sublayer above and under the PCS, respectively. The rate adaptation sublayer is compatible for the GMII. Also, if we modify the SERDES sublayer, the technology can easily obtain 250BASE-T with 2 pairs UTP. We implement such functions with FPGA and analog board and verify the function of rate adaptation and symbol vector synchronization, and effective transmission rate by experiments. In particular, we show that link efficiency is increased by enable control in the rate adaptation sublayer.

• The Transactions of The Korean Institute of Electrical Engineers
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• v.60 no.2
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• pp.455-458
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• 2011

4:10 deserializer is proposed to recover 1:10 serial data using 1/4-rate clock. And then, 1/4-rate CDR(Clock and Data Recovery) circuit was designed for SERDES of high-speed serial display interface. The reduction of clock frequency using 1/4-rate clocking helps relax the speed limitation when higher data transfer is demanded. This circuit is composed of 1/4-rate sampler, PEL(Phase Error Logic), Majority Voting, Digital Filter, DPC(Digital to Phase Converter) and 4:10 deserializer. The designed CDR has been designed in a standard $0.18{\mu}m$ 1P6M CMOS technology and the recovered data jitter is 14ps in simulation.

• Journal of the Institute of Electronics Engineers of Korea SD
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• v.41 no.2
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• pp.39-45
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• 2004

This paper describes the design and implementation of Serial ATA physical layer and performance measurement. It is composed of tranceiver circuit that has the NRZ data stream with +/-250㎷ voltage level and 1.5Gbps data rate, transmission PLL circuit, clock ＆ data recovery circuit, serializer/deserializer circuit and OOB(Out Of Band) generation/detection circuit. We implement the verification of the silicon chip with 0.18${\mu}{\textrm}{m}$ Standard CMOS process. It can be seen that all of the blocks operate with no errors but the data transfer rate is limited to the 1.28Gbps even this should support 1.5Gbps data transfer rate.

• The Journal of the Institute of Internet, Broadcasting and Communication
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• v.12 no.2
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• pp.167-174
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• 2012

The circuits including with Optical transceiver and clock data recovery, in this paper, SERDES (SERializer-DESerializer) are implemented to construct a GE-PON burst-mode transceiver supporting IEEE 802.3ah and a jig for measuring the burst-mode characteristics, that is to say, PON upstream optical transmission environment are manufactured to evaluate the performance of transceiver. we verified that the limiting amplifier compensated the gap of max. 26dB optical power by experiments. The startup acquisition lock time is 670ns in case of using VSC7123 and 2300ns in case of S2060 and the data acquisition lock time were measured to be 400ns and 600ns, respectively, in the upstream channel transmission in this work. While on the other, VSC7123 is satisfied with IEEE802.3ah recommendations.