• 한국산업정보학회논문지
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• 제19권3호
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• pp.9-15
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• 2014

In the ubiquitous computing environment, a ubiquitous vehicle will be a communication node in the vehicular network as well as the means of ground transportation. It will make humans and vehicles seamlessly and remotely connected. Especially, one of the prominent services in the ubiquitous vehicle is the vehicle remote operation. However, mutual-collaboration with the in-vehicle communication network, the vehicle-to-vehicle communication network and the vehicle-to-roadside communication network is required to provide vehicle remote operation services. In this paper, an Internet-based human-vehicle interfaces and a network architecture is presented to provide remote vehicle control and diagnosis services. The performance of the proposed system is evaluated through a design and implementation in terms of the round trip time taken to get a vehicle remote operation service.

• 한국정보통신학회:학술대회논문집
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• 한국정보통신학회 2015년도 추계학술대회
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• pp.224-227
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• 2015

일반적으로 자동차드라이버의 스마트폰을 통한 데이터전송은 자동차운전자의 핸드폰은 데이터를 실시간으로 원격데이터 센터에 전송하는 경우에 용량 의존적인 순위를 가지고 있다. 생성되는 진단보드 데이터들은 드라이버의 폰에서의 모바일 진단 어플리케이션에 임시적으로 저장하고, 인터넷에 연결 되었을 때 데이터 센터에 전송한다. 클라우드에서 실행에 방해하는 다른 태스크들이 없는 원격 자동차 어플리케이션 사용방법을 위한 node.js는 모바일 네트워크을 통한 클라우드에서 데이터 저장업무를 다루기 위하여 적합하다. 우리는 외부 어플리케이션으로부터 driver inputs and delivers output을 패스하는 원격 유저와 운용하는 스마트폰 어플리케이션에서 자동차와의 어플리케이션 interface 방법을 사용하는 실시간 분석 안드로이드 어플리케이션 반응을 시뮬레이션 통해 제안된 아키텍쳐의 유효성을 입증한다. 이 논문에서, 우리는 이벤트 루프 접근을 기반으로 하는 이것은 웹서버 구조를 특징으로 하는 원격 자동차 결함 진단 시스템 연구를 제안한다.

• 한국정보기술응용학회:학술대회논문집
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• 한국정보기술응용학회 2005년도 6th 2005 International Conference on Computers, Communications and System
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• pp.85-90
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• 2005

The advance of mobile and telematics technologies has produced vehicles with various convenient services for drivers. Specifically lots of researches and several technologies have been developed to provide services of a remote vehicle diagnosis and control. The existing and representative product for a vehicle control is a RCS (remote control system), but it has a problem of short control distance and fragile security. In this paper, a telematics terminal embedded with CDMA and GPS is designed, which can be connected to the Internet. It allows a driver with a cellular phone to remotely diagnosis and control a vehicle via wireless network and SMS.

• 전자공학회논문지 IE
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• 제45권4호
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• pp.33-41
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• 2008

텔레매틱스 시스템의 기능 중 현실적으로 상품성 있는 기능으로 "차량 원격 진단 기능", "운전 패턴 분석 기능"이 있으며 이를 구현하기 위한 기술로는 차량 신호 인터페이스 기술, 자가 진단 인터페이스 기술, 가속도/자이로 센서 인터페이스 기술, PS 신호 처리 기술, 운전 패턴 분석 기술, 무선통신(CDMA) 처리 기술 등이 사용된다. 이러한 기술을 기반으로 본 논문에서는 차량 주행 중에 자각의 EMS(Engine Management System), TMS(Transmission Management System), ABS/TCS, A/BAG 능에서 진단된 차량의 이상 유무를 실시간으로 분석하고, 운전자 주행 패턴 및 차량 관리에 대한 사항을 점검하여 무선통신(CDMA)을 통해 정보센터로 전송하여 이를 DB화함으로써 효율적 차량 관리 및 운전자 관리가 가능하다. 본 연구는 이러한 차량 원격진단 및 운전 패턴 분석기능을 구현하는 H/W와 S/W를 설계 및 제작하고 실차 시험을 통해 이를 검증한다.

• 시스템엔지니어링학술지
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• 제18권2호
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• pp.40-49
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• 2022

Remote-controlled and autonomous driving based on artificial intelligence are key elements required for unmanned combat vehicles. The required capability of such an unmanned combat vehicle should be expressed in reasonable required operational capability(ROC). To this end, in this paper, the requirements of an unmanned combat vehicle operated under a manned-unmanned teaming were analyzed. The functional requirements are remote operation and control, communication, sensor-based situational awareness, field environment recognition, autonomous return, vehicle tracking, collision prevention, fault diagnosis, and simultaneous localization and mapping. Remote-controlled and autonomous driving of unmanned combat vehicles could be achieved through the combination of these functional requirements. It is expected that the requirement analysis results presented in this study will be utilized to satisfy the military operational concept and provide reasonable technical indicators in the system development stage.

• 한국정보과학회논문지:컴퓨팅의 실제 및 레터
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• 제12권2호
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• pp.91-101
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• 2006

현재 까지 지능형 자동차의 서비스 형태는 주로 차량 운전자에 대한 유용한 정보제공과 엔터테인먼트를 중심으로 연구 되어 왔다. 그러나 유비쿼터스 환경에서의 지능형 자동차와 같이 시간과 장소의 구애됨 없이 언제 어디서든 자동차와 대화 및 제어가 가능한 서비스 제공에는 많은 제약 사항을 가진다. 본 논문에서는 CDMA 이동통신망을 기반으로 웹상에서 차량의 무선 원격진단과 관리 가능한 지능형 차량정보시스템을 설계 및 구현 하였다. 구현한 지능형차량정보시스템은 본 논문에서 제안하는 컷앤콜백 매커니즘을 사용하여 언제 어디서든 웹브라우져를 통하여 원격지 차량의 제어와 진단이 가능하며, 제어 조작자와 차량 간의 이동성을 제공하다. 본 논문에서는 CDMA 기반의 지능형 차량 정보시스템의 설계 기법을 설명한다. 또한, 제안한 시스템의 구현을 통한 시스템의 성능분석이 이루어진다. 실험결과, 웹 클라이언트의 요구에 의한 차량단말의 초기 접속 응답 시간은 평균 10.302초를 보였으며, 초기 접속 완료 후 646.44ms의 응답시간을 보였다. 또한 차량 단말에 의한 CAN 센서노드의 응답시간은 평균 6.669ms를 보였다.

• 한국철도학회:학술대회논문집
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• 한국철도학회 2011년도 정기총회 및 추계학술대회 논문집
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• pp.3073-3078
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• 2011

Driverless Train Control System has been recently introduced and commercialized in Korea. It is expected that the vehicle with driverless operation system will be used in new lines such as Sinbundang line soon. Therefore it is necessary to change the system operation and conception of the existing train operation system and the necessity of driverless vehicle monitoring system meeting a new paradigm is rising. In order to dispel concerning about safety issues caused by driverless train operation, the importance to establish vehicle error detection, useful fault diagnosis and rapid action plans is higher than ever. For this, efficient and higher level of vehicle supervision & control system should be essentially supported. In this study, remote driverless vehicle monitoring system using by radio communication is suggested to be used for monitoring and controlling important parts of the vehicle and diagnose and take quick actions when vehicles are in trouble at control tower at real time.

• 제어로봇시스템학회:학술대회논문집
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• 제어로봇시스템학회 2004년도 ICCAS
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• pp.132-137
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• 2004

On-Board Diagnostic(OBD) systems are in most cars and light trucks on the load today. During the 1970's and early 1980's manufacturers started using electronic means to control engine functions and diagnose engine problems. The CARB's diagnostic requirements to meet EPA emission standards have been designated as OBD with a goal of monitoring all of the emissions-related components, as well as the chassis, body, accessory devices and the diagnostic control network of the vehicle for proper operation. In this paper, we present a remote measurement system for the wireless monitoring of diagnosis signal and sensors output signals of ECU adopted KWP2000, united the OBD communication protocol, on OBD-compliant vehicle using the wirless communication technique of Bluetooth. In order to measure the ECU signals, the interface circuit is designed to communicate ECU and designed terminal wirelessly according to the ISO, SAE regulation of communication protocol standard. A microprocessor S3C3410X is used for communicating ECU signals. The embedded system's software is programmed to measure the ECU signals using the ARM compiler and ANCI C based on MicroC/OS kernel to communicate between bluetooth modules using bluetooth stack. The diagnostic system is developed using Visual C++ MFC and protocol stack of bluetooth for Windows environment. The self-diagnosis and sensor output signals of ECU is able to monitor using PC with bluetooth board connected in serial port of PC. The algorithms for measuring the ECU sensor output and self-diagnostic signals are verified to monitor ECU state. At the same time, the information to fix the vehicle's problem can be shown on the developed monitoring software. The possibility for remote measurement of self-diagnosis and sensor signals of ECU adopted KWP2000 in embedded system verified through the developed systems and algorithms.

• 한국정보기술응용학회:학술대회논문집
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• 한국정보기술응용학회 2005년도 6th 2005 International Conference on Computers, Communications and System
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• pp.73-76
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• 2005

The advanced information and communication technology gives vehicles another role of the third digital space, merging a physical space with a virtual space in a ubiquitous society. In the ubiquitous environment, the vehicle becomes a sensor node, which has a computing and communication capability in the digital space of wired and wireless network. An intelligent vehicle information system with a remote control and diagnosis is one of the future vehicle systems that we can expect in the ubiquitous environment. However, for the intelligent vehicle system, many issues such as vehicle mobility, in-vehicle communication, service platform and network convergence should be resolved. In this paper, an in-vehicle gateway is presented for an intelligent vehicle information system to make an access to heterogeneous networks. It gives an access to the server systems on the internet via CDMA-based hierarchical module architecture. Some experiments was made to find out how long it takes to communicate between a vehicle's intelligent information system and an external server in the various environment. The results show that the average response time amounts to 776ms at fixec place, 707ms at rural area and 910ms at urban area.

• 대한전자공학회:학술대회논문집
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• 대한전자공학회 2005년도 추계종합학술대회
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• pp.1023-1026
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• 2005

In the ubiquitous computing environment, an intelligent vehicle is defined as a sensor node with a capability of intelligence and communication in a wire and wireless network space. To make it real, a lot of problems should be addressed in the aspect of vehicle mobility, in-vehicle communication, common service platform and the connection of heterogeneous networks to provide a driver with several intelligent information services beyond the time and space. In this paper, we present an intelligent information system for managing in-vehicle sensor network and a vehicle gateway for connecting the external networks. The in-vehicle sensor network connected with several sensor nodes is used to collect sensor data and control the vehicle based on CAN protocol. Each sensor node is equipped with a reusable modular node architecture, which contains a common CAN stack, a message manager and an event handler. The vehicle gateway makes vehicle control and diagnosis from a remote host possible by connecting the in-vehicle sensor network with an external network. Specifically, it gives an access to the external mobile communication network such as CDMA. Some experiments was made to find out how long it takes to communicate between a vehicle's intelligent information system and an external server in the various environment. The results show that the average response time amounts to 776ms at fixed place, 707ms at rural area and 910ms at urban area.