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장부철,조길석,신진범,구봉주,Jang, Bu-Cheol,Cho, Kil-Seok,Shin, Jin-Beom,Koo, Bong-Joo 한국군사과학기술학회 2014 한국군사과학기술학회지 Vol.17 No.4
We proposed a design method for squib current supply & interlock circuits in guided-missile fire control systems. In order to design squib current supply circuits, various missile squib loads including line resistance and squib devices have to be considered in advance minimizing probability of redesign of circuits and reducing the development cost by implementing the most proper squib current supply circuit. Also, we presented a hardware interlock logic instead of the commonly used software safety logic to improve the safety of guided-missile fire control systems. The proposed squib interlock circuit enhances safety requirements of guided-missile fire control systems. We confirmed that simulation and measurement results of the proposed design method are the same as theoretical analysis results.
배정호,장부철,구봉주,Bae, Jung Ho,Jang, Bucheol,Koo, Bongjoo 한국군사과학기술학회 2017 한국군사과학기술학회지 Vol.20 No.5
Model-based test, a well-known method of the black box tests, is consisted of the following four steps : model construction using requirement, test case generation from the model, execution of a SUT (software under test) and detection failures. Among models constructed in the first step, state-based models such as UML standard State Machine are commonly used to design event-based embedded systems (e.g., weapon control systems). To generate test cases from state-based models in the next step, coverage-based techniques such as state coverage and transition coverage are used. Round-trip path coverage technique using W-Method, one of coverage-based techniques, is known as more effective method than others. However it has a limitation of low failure observability because the W-Method technique terminates a testing process when arrivals meet states already visited and it is hard to decide the current state is completely same or not with the previous in the case like the GUI environment. In other words, there can exist unrevealed faults. Therefore, this study suggests a Extended W-Method. The Extended W-Method extends the round-trip path to a final state to improve failure observability. In this paper, we compare effectiveness and efficiency with requirement-item-based technique, W-Method and our Extended W-Method. The result shows that our technique can detect five and two more faults respectively and has the performance of 28 % and 42 % higher failure detection probability than the requirement-item-based and W-Method techniques, respectively.
고신뢰성 발사통제시스템을 위한 고장허용 통신 미들웨어 설계 및 구현
송대기(Dae-Ki Song),장부철(Bu-Cheol Jang),이철훈(Cheol-Hoon Lee) 한국콘텐츠학회 2008 한국콘텐츠학회논문지 Vol.8 No.8
발사통제시스템(Launch Control System)은 유도무기체계에서 유도탄의 발사와 관련된 일련의 절차들을 제어하는 시스템이다. 이 시스템은 지정된 시간 안에 목표물에 대한 교전계획을 생성하고 이 정보를 탄에 장입하며 탄의 발사 제어를 수행해야 한다. 이 때문에 시스템의 하드웨어, 소프트웨어 고장뿐만 아니라 정해진 수행 시간의 초과 때문에도 임무가 실패될 수 있다. 본 논문에서 제안한 것은 발사통제시스템과 같은 내장형 실시간 시스템을 위한 고장허용 이더넷으로 별도의 하드웨어나 소프트웨어 없이 기존 상용의 이더넷 디바이스를 이중화하여 네트워크에 고장허용 기능을 제공하는 방법이다. 이를 위해 시스템의 각 구성 노드들을 이중의 네트워크 채널로 중복 시키고, 네트워크 트래픽에 대한 고장탐지 및 복구를 위해 통신 미들웨어를 설계하고 개발하였다. 이중채널 기반의 통신 미들웨어를 통해 처리 시간이 중요한 시스템 에 네트워크 고장으로 인한 시스템 중지를 방지하고 노드에 통신 손실이 발생하지 않도록 하였다. Launch control system controls the sequence for launching missile in weapon systems. This system have to generate the engagement plan, input information and launch the missile in timeliness requirement. Such a system may fail to operate correctly either due to errors in hardware and software or due to violation of timing constraints. We presented fault-tolerant ethernet for embedded real-time system like launch control system. This approach is designed to handle network faults using dual commercial-off-the-shelf(COTS) network devices. To support fault-tolerant ethernet each node is composed dual channel ethernet and designed the communication middleware for network fault detect and recovery. Especially for time-critical system, the middleware is being developed to achieve that no single point of network failure shall take down or cause loss of communication to network nodes.