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클록 손실 측정 기법을 이용한 DDI용 연속 시간 이퀄라이저
김규영(Kyu-Young Kim),김길수(Gil-Su Kim),손관수(Kwansu Shon),김수원(Soo-Won Kim) 대한전자공학회 2008 電子工學會論文誌-SD (Semiconductor and devices) Vol.45 No.2
본 논문에서는 클록 손실 측정 기법을 이용한 디지털 디스플레이 인터페이스(Digital Display Interface: DDI)용 이퀄라이저를 제안한다. 제안하는 클록 손실 측정 기법은 최저 전압 유지 회로를 사용하여서 채널의 손실 정보를 추출한다. 추출된 손실정보는 이퀄라이저 필터에 인가되며, 시스템의 안정도를 증가시키기 위해 제안된 이퀄라이저는 피드포워드 구조 (Feedforward Loop)로 구현된다. 제안된 이퀄라이저는 0.18um CMOS 공정으로 제작되었으며, 실험 결과 채널 손실이 -33dB인 경우에 1.65Gbps의 신호들이 최소 0.7UI의 Eye Width를 가지게 된다. 또한 최대 10mW 이하의 전력을 소모하며, 0.127㎟ 의 유효면적을 차지한다. This paper presents a continuous-time equalizer adopting a clock loss tracking technique for digital display interface. This technique uses bottom hold circuit to detect the incoming clock loss. The generated loss signal is directly fed to equalizer filters, building adaptive feed-forward loops which contribute the stability of the system. The design was done in 0.18μm CMOS technology. Experimental results summarize that eye-width of minimum 0.7UI is achieved until -33dB channel loss at 1.65Gbps. The average power consumption of the equalizer is a maximum 10mW, a very low value in comparison to those of previous researches, and the effective area is 0.127㎟.
인자 분석을 통한 플라즈마 디스플레이 패널(Plasma Display Panel) 텔레비전에서의 냉각 홴 시스템 소음 저감
김규영(Kim, Kyu-Young),최민구(Choi, Min-Goo),이덕주(Lee, Duck-Joo) 한국소음진동공학회 2006 한국소음진동공학회 논문집 Vol.16 No.2
The present experimental study deals with noise reduction and improvements in cooling performance in a plasma display panel (PDP) television (TV). The main ideas of the fan system noise reduction are maintenance of uniform inflow condition and reduction of the system loss, ${\Delta}P.$ The discrete noise is mainly related with the inflow condition therefore removing the structure which distorts inflow makes the discrete noise reduction. The broadband noise in PDP TV is related with the system losses which result from the presence of the fan downstream obstacle, PDP rear case. Through the modification of the distance and preventing the leakage flow between the fan and rear case, we can obtain the system loss and broadband noise reduction. Additionally we can reduce fan rotating speed because of increased flow rate which obtains from the reduction of system loss (resistance). Finally, 4.2 dB(A) noise reduction and $10\%$ increase in flow rate are achieved. From these results, we show that the reduction of system loss is the most effective way of the fan system noise reduction.