• 융합신호처리학회논문지
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• 제9권3호
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• pp.230-237
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• 2008

최근 국내외에서 무인 자동차용 로봇 개발에 관한 많은 관심과 개발 경쟁이 한층 더해가고 있다. 그러나 무인 자동차용 로봇을 효과적으로 제어하기 위한 표준화된 아키텍쳐의 부재로 개발 기간의 장기화 되고, 다른 무인 자동차용 로봇과 호환성이 저하되는 어려움이 많았다. 따라서 본 논문에서는 무인 자동차용 로봇 표준 아키텍쳐인 JAUS 기반으로 모바일 로봇을 원격 제어하는 시스템을 구현하였다. 구현된 모바일 로봇은 무선 LAN UDP/IP 프로토콜 기반으로 JAUS 명령 메시지를 사용해서 원격제어시스템과 통신한다. 본 연구의 유효성은 구현 로봇의 주행 및 장애물인식 성능에 대한 실험적 결과를 통해 보여진다.

• 제어로봇시스템학회논문지
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• 제14권9호
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• pp.873-880
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• 2008

This paper deals with the peer-to-peer data communication to connect each distributed levels of developed unmanned system according to the JAUS. The JAUS is to support the acquisition of unmanned system by providing a mechanism for reducing system life-cycle costs. Each of distributed levels of the JAUS protocol divides into a system, some of subsystems, nodes and components/instances, each of which may be independent or interdependence. We have to distribute each of the levels because high performance is supported in order to create several sub-processor computing data in one processor with high CPU speed performance. To complement such disadvantage, we must think the concept that a distributed processing agrees with separating each of levels from the JAUS protocol. Therefore, each of distributed independent levels send data to another level and then it has to be able to process the received data in other levels. So, peer-to-peer communication has to control a data flow of distributed levels. In this research, we explain each of levels of the JAUS and peer-to-peer communication structure among the levels using our developed unmanned ground vehicle.

• 제어로봇시스템학회논문지
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• 제18권6호
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• pp.584-593
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• 2012

This paper introduces an AVP (Automated Valet Parking) system which applies an autonomous driving concept into the current PAS (Parking Assistant System). The present commercial PAS technology is limited into vehicle. It means vehicle only senses and controls by and for itself to assist the parking. Therefore, the present PAS is restricted to simple parking events. But AVP includes wider parking events and planning because it uses infra-sensor network as well as vehicle sensor. For the realization of AVP, the commercial steering system of a compact vehicle was modified into steer-by-wire structure and various sensors like LRF (Long Range Finder) and camera were installed in a parking area. And local & global server decides where and when the vehicle can go and park in the testing area after recognized the status of environment and vehicle from those sensors. GPS solution was used to validate the AVP performance. More various parking situations, vehicles and obstacles will be considered in the next research stages based on these results. And we expect this AVP solution with more intelligent vehicles can be applied in a big parking lot like a market, an amusement park, etc.