• International journal of advanced smart convergence
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• v.11 no.2
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• pp.108-117
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• 2022

The recent development of information and communication technology has a great impact on the audio/video industry. In particular, IP-based AoIP transmission technology and AVB technology are making changes in the audio/video market. Video signal transmission technology has been introduced to the market through a network, but it has not replaced the video switcher function. Video signals in the conference room or classroom are still controlled by the switching device. In order to switch input/output video devices, a cable that is not limited by distance must be connected to the switcher. In addition, the control of the switching device must be performed by a person who has received professional training. In this paper, it is a technology that can be operated even by non-experts by replacing complex video cables (RGB, DVI, HDMI, DP) with LAN cables and enabling IP-based video switching and transmission (Video Mirroring over IP: VMoIP) to replace video switcher equipment. We are going to do this study, I/O videos were controlled in the form of matrix and high-definition videos were transmitted without distortion, and VMoIP is expected to become the standard for video switching systems in the future.

• Korean Journal of Optics and Photonics
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• v.17 no.1
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• pp.7-17
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• 2006

In this paper, we proposed an optical true time-delay (TTD) for planar phased array antennas (PAAs), which is composed of a wavelength-dependent optical true time delay (WDOTTD) followed by a wavelength-independent optical true time delay (WIOTTD). The WDOTTD is a fiber Bragg gratings (FBGs) Prism and the WDOTTD is a fiber delay-lines matrix of which each component consists of a certain length of fiber connected to cross-ports of a 2${\times}$2 MEMS switch. A 10-GHz 2-bit${\times}$4-bit two-dimensional optical TTD has been fabricated by cascading a WDOTTD with a maximum time delay of 810 ps to a WIOTTD of $\pm$50 ps. Time delay and insertion loss for each radiation angle have been measured. Time delay error for the WIOTTD has been measured to be less than $\pm$1 ps. We have also designed a two-dimensional 10-GHz PAA composed of 8${\times}$8 microstrip patch antenna elements driven by the proposed TTD. The radiation patterns of this PAA have been obtained by simulation and analyzed.

• Journal of the Institute of Electronics Engineers of Korea SD
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• v.42 no.2 s.332
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• pp.65-72
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• 2005

We can integrate more IP blocks on a silicon die as the development of fabrication technologies and EDA tools. Consequently, we can design complicated SoC architecture including multi-processors. However, most of existing SoC buses have bottleneck in on-chip communication because of shared bus architectures, which result in the performance degradation of systems. In most cases, the performance of a multi-processor system is determined by efficient on-chip communication and the well-balanced distribution of computation rather than the performance of the processors. We propose an efficient SoC Network Architecture(SNA) using crossbar routers which provide a solution to ensure enough communication bandwidth. The SNA can significantly reduce the bottleneck of on-chip communication by providing multi-channels for multi-masters. According to the proposed architecture, we design a model system for the SNA. The proposed architecture has a better efficiency by $40\%$ than the AMBA AHB according to a simulation result.

• Proceedings of the Optical Society of Korea Conference
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• 1991.06a
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• pp.22-22
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• 1991

광의 병렬처리 능력을 잘 활용한 1$\times$4 매트릭스 스위치의 구조와 전극구조를 설계하고 스위치 특성을 조사하기 위하여 beam propagation method(BPM)를 이용하여 수치계산을 하였다. 기존의 매트릭스 스위치는 대부분의 경우 방향성 결합기를 스위치 element로 이용하여 왔으나 이 결합기는 소자의 길이가 길기 때문에 단일 LinBO3 웨이퍼상에 집적할 수 있는 매트릭스 스위치의 크기가 제한되는 단점이 있다. 본 연구에서는 두 도파로 사이에 세 번째 도파로를 삽입하여 두 도파로를 결합시키는 세 도파로 결합기를 스위치 element로 사용하여 세 개의 스위치 element를 LiNbO3기판위에 직렬로 집적시킨 1$\times$4 매트릭스 스위치를 구성하였다. 스위치 element와 1$\times$4 매트릭스 스위치를 구성하였다. 스위치 element와 1$\times$4 매트릭스 스위치의 특성을 BPM을 사용하여 수치계산할 때 단일 모드 도파로의 유효 굴절을 분포는 n(X) = nm + $\Delta$ncosh-2(2x/w)의 형태로 가정했으며, 사용된 파라미터의 값은 각각 nm=2.1455, $\Delta$n=0.003, W=5$mu extrm{m}$, d=5$\mu\textrm{m}$, λ=1.3$\mu\textrm{m}$ 이고 S-파라메터의 값은 0.95927이므로 단일 모드 도파로가 된다. 계산결과 스위치 element의 결합길이는 3810$\mu\textrm{m}$이며 도파로의 길이가 결합길이와 같을 때 전극에 인가된 전압에 의한 도파로의 굴절을 섭등의 함수로 출력광의 세기를 계산한 결과 스위칭 전압은 14.85volt이고 crosstalk는 -18.9dB였다. 이 스위치 element로 구성된 1$\times$4 매트릭스 스위치는 스위칭 전압을 세 개의 전극에 적절한 조합으로 인가함으로써 한 입력 도파로에 결합된 광이 내개의 출력 도파로중 한 도파로에 스위칭 된다. 한편 수치계산의 결과를 실험적으로 확인하기 위해 스위치 element와 1$\times$4 매트릭스 스위치를 z-cut의 LinbO3 결정에 Ti을 열확산시켜 제작한 소자의 스위칭 특성을 발표할 예정이다.

• Proceedings of the KSRS Conference
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• 2007.10a
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• pp.130-133
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• 2007

In order to get high quality and high resolution image data from the space-borne camera system, the image chain from the sensor to the user in the ground-station need to be designed and controlled with extreme care. The behavior of the camera system needs to be controlled by ground commands to support on-orbit calibration and to adjust imaging parameters and to perform early stage on-orbit image correction, like gain and offset control, non-uniformity correction, etc. The operation status including the temperature of the sensor needs to be transferred to the ground-station. The preparation time of the camera system for imaging with specific parameters should be minimized. The camera controller needs to synchronize the operation of cameras for every channel and for every spectral band. Detail timing information of the image data needs to be provided for image data correction at ground-station. In this paper, the design of the camera controller for the AEISS on KOMPSAT-3 will be introduced. It will be described how the image chain is controlled and which imaging parameters are to be adjusted The camera controller will have software for the flexible operation of the camera by the ground-station operators and it can be reconfigured by ground commands. A simple concept of the camera operations and the design of the camera controller, not only with hardware but also with controller software are to be introduced in this paper.

• The Journal of Korean Institute of Electromagnetic Engineering and Science
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• v.21 no.6
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• pp.573-582
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• 2010

In this paper, X-band transceiver for high resolution wideband SAR systems is designed and fabricated. Also as a technique for enhancing the performance, error compensation algorithm is presented. The transceiver for SAR system is composed of transmitter, receiver, switch matrix and frequency generator. The receiver especially has 2 channel mono-pulse structure for ground moving target indication. The transceiver is able to provide the deramping signal for high resolution mode and select the receive bandwidth for receiving according to the operation mode. The transceiver had over 300 MHz bandwidth in X-band and 13.3 dBm output power which is appropriate to drive the T/R module. The receiver gain and noise figure was 39 dB and 3.96 dB respectively. The receive dynamic range was 30 dB and amplitude imbalance and phase imbalance of I/Q channel was ${\pm}$0.38 dBm and ${\pm}$3.47 degree respectively. The transceiver meets the required electrical performances through the individual tests. This paper shows the pulse error term depending on SAR performance was analyzed and range IRF was enhanced by applying the compensation technique.