• Information and Communications Magazine
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• v.26 no.6
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• pp.37-44
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• 2009

오늘날 다수의 빔과 주파수를 사용하는 통신위성은 고속 디지털 신호 처리를 응용한 부채널 단위의 OBS(On-board Switching) 기술과 원하지 않는 간섭신호를 일정부분 제거하는 기능을 필요로 하게 될 전망이다. 본고에서는 위성통신 분야에서 현재 활발히 연구가 진행되고 있는 부채널 수준의 스위칭이 가능한 수동형 디지털 통신위성에 대하여 소개한다. 아울러 위성 선진국의 디지털 통신위성 개발 현황, 부채널 증폭 및 스위칭을 위한 소요기술, 그리고 간섭신호 제거가 가능한 디지털 통신위성 기술에 대하여 기술한다.

• Proceedings of the IEEK Conference
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• 2001.09a
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• pp.951-954
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• 2001

본 논문에서는 SDR (Software Defined Radio)시스템을 위한 디지털 IF (Intermediate Frequency)수신기를 구현하였다[1][2]. 구현된 수신기의 하드웨어 구조는 AD변환부, PDC(Programmable Down Converter)부, DSP (Digital Signal Processing)부분으로 이루어졌다. AD변환부는 Analog Devices사의 AD6644를 이용하여 아날로그 신호를14bit의 디지털 신호로 변환된다. PDC부분은 Intersil사의 HSP 50214B를 이용하여 14bit 샘플 된 IF(Intermediate Frequency)입력을 혼합기와 NCO(Numerically Controlled Oscillator)에 의해 기저대역으로 다운 시키는 역할을 한다. PDC는 CIC (Cascaded Integrator Comb)필터, Halfband 필터 그리고 프로그램할 수 있는 FIR필터로 구성되어 있다. 그리고 PDC부분을 제어하고 PDC부분에서 처리할 수 없는 캐리어, 심볼 트래킹을 위해 Texas Instrument사의 16비트의 고정소수점 DSP인 TMS320C5416과 Altera사의 FPGA를 사용하였다. 그러므로 중간주파수 대역과 기저대역 간의 신호변환을 디지털 신호처리를 수행함으로써 일반적인 아날로그 처리방식보다 고도의 유연성과 고성능 동작이 가능하고 시간과 환경 변화에 우수한 동작 특성을 제공한다.

• Proceedings of the Korea Institute of Convergence Signal Processing
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• 2001.06a
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• pp.101-104
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• 2001

In this paper, we propose the Digital Automatic Gain Controller for IEEE 802.11a High-speed Physical Layer in the 5 GHz Band. The input gain is estimated by calculating the energy of the training symbol that is a synchronizing signal. The renewal gain is calculated by comparing the estimated gain with the ideal gain. The renewal gain is converted into the controlled voltage for GCA to reduce or amplify the input signals. We used a piecewise-linear approximation to reduce the hardware size. The gain control is performed seven times to provide more accurate gain control. The proposed automatic gain controller is designed with VHDL and verified by using the Xilinx FPGA.

• Journal of the Institute of Convergence Signal Processing
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• v.2 no.4
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• pp.71-76
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• 2001

In this paper we propose the Digital Automatic Gain Controller for IEEE 802.11a-High-speed Physical Layer in the 5 GHz Band. The input gain it estimated by calculating the energy of the training symbol that it a synchronizing signal. The renewal gain is calculated by comparing the estimated gain with the ideal gain. The renewal gain is converted into the controlled voltage for GCA to reduce or amplify the input signals. We used a piecewise-linear approximation to reduce the hardware size. The gain control is performed seven times to provide more accurate gain control. The proposed automatic gain controller is designed with VHDL and verified by using the Xilinx FPGA.

• 한국지구물리탐사학회:학술대회논문집
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• 2005.05a
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• pp.187-194
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• 2005

A PC-based 8-channel seismic system has been developed and applied for bedrock mapping in near shore environment. The system is composed of an analog signal processor and an A/D converter installed on the computer, and a streamer with the group interval of 5 meters. The system is accomplished with a data acquisition program which controls the system and a data processing software. With the PC-based shallow marine seismic survey system high-resolution 2-D marine seismic profiles which have high S/N ratios can be obtained after appropriate data processing.

• Journal of the Institute of Convergence Signal Processing
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• v.8 no.3
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• pp.205-210
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• 2007

This paper presents a CMOS TIQ flash A/D converter which operates very fast compared to other types of A/D converters due to its parallel architecture. The output resolution of designed A/D converter is 6-bit. In order to reduce the power consumption and chip area of conventional flash A/D converter, TIQ based flash A/D converter is proposed, which uses the advantage of the structure of CMOS transistors. The length and width of transistors of TIQ were determined with HSPICE simulation. To speed up the ultra-high speed flash A/D converter, the Fat Tree Encoder technique is used. The TIQ A/D converter was designed with full custom method. The chip's maximum power consumption was 38.45mW at 1.8V, and the operating speed of simulation was 2.7 GSPS.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.24 no.8A
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• pp.1259-1264
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• 1999

In this paper, the High-speed, Low-power Analog-Digital Conversion Archecture is porposed using the Pipelined archecture for High-speed conversion rate and the Successive-Approximation archecture for Low-power consumption. This archecture is the Successive-Approximation archecture using Pipelined Comparator array to change reference voltage during Holding Time. The Analog-to-Digital Converter for video processing is designed using 0.8${\mu}{\textrm}{m}$ CMOS tchnology. When an 6-bit 10MS/s Analog-to-Digital Converter is simulatined, the INL/DNL errors are $\pm$0.5/$\pm$1, respectively. The SNR is 37dB at a sampling rate of 10MHz with 100KHz sine input signal. The power consumption is 1.46mW at 10MS/s. When an 8-bit 10MS/s Analog-to Digital Converter is simulatined, the INL/DNL errors are $\pm$0.5/$\pm$1, respectively. The SNR is 41dB at a sampling rate of 100MHz with 100KHz sine input signal. The power consumption is 4.14m W at 10MS/s.

• The Magazine of the IEIE
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• v.15 no.2
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• pp.88-101
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• 1988

• Journal of Advanced Navigation Technology
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• v.3 no.1
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• pp.52-59
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• 1999

Digital microwave wideband receiver including linear amplifier, analog-to-digital converter(ADC) and digital signal processor is able to analyze its performance using sensitivity and dynamic range of system. Determination of gain, third-order intermodulation products and ADC characteristics and design criteria for the linear amplifier chain is essential problem for sensitive and dynamic range. Also, if there are two signals with frequencies very close, digital signal processor must be able to separate the two signals. In this paper, we measured dynamic range as gain was changed and determined gain value for the proper sensitivity and dynamic range and high resolution spectrum estimation was used to separate two close signals.

• Korean Journal of Optics and Photonics
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• v.13 no.5
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• pp.377-383
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• 2002

An all-digital closed-loop (ADCL) signal processor for an open-loop FOG was developed to replace the analog circuitry of a Digital Phase Tracking (DPT) signal processor with new digital circuitry. When the ADCL signal processor without a stabilizer for fiber phase modulator (FPM) was attached to the FOG, temperature drift of FOG was about 0.26$\mu$rad/$^{\circ}C$, which makes the FOG unusable in medium or higher-grade applications. This drift was due to variations of phase modulation amplitude and phase delay of the FPM. The stabilizer controls its phase modulation amplitude and phase delay by regulating the ratio of harmonics of the FOG output. Thus, the stabilizer reduces the drift of the FOG to negligible.