• 한국산업융합학회 논문집
• /
• 제26권2_1호
• /
• pp.239-248
• /
• 2023

In this paper, we conduct a study on the design that can secure the safety of the EPLA system by performing safety activities based on the ISO 26262 standard for vehicle functional safety. In the case of a company developing a detailed system, it is responsible for verification through hardware design and safety analysis in the overall flow of safety activities, and safety analysis according to the ASIL safety level must be properly performed. At this time, there are cases where the safety goal quantitative metric value suggested by the ISO 26262 standard cannot be satisfied only by the hardware design of the basic function, so it is necessary to design and install the safety mechanism. Based on ISO 26262 safety activities, it is possible to derive an effective design plan through hardware safety analysis.

• 한국전자파학회논문지
• /
• 제25권10호
• /
• pp.1020-1027
• /
• 2014

자동차 전자 제어 장치의 확대 보급에 따라 관련 장치의 오동작으로 인해 발생하는 자동차 사고 및 인명 손실을 최소화하기 위해 ISO 26262가 제정되어 완성 차량 제작사는 물론 부품 공급사에 적용되고 있다. 이 규격에서는 자동차 전체 시스템을 대상으로 개발 초기부터 생산/폐기에 이르기까지 전체 생명주기에서의 안전 요구사항을 적용토록 요구하고 있으며, 전자파 적합성 분야도 중요한 검토 항목으로 규정되어 있다. 따라서 자동차의 설계, 제조, 검증, 사용, 유지보수기간 동안 각 단계별로 적용할 EFS(EMC for Functional Safety)에 대한 개발과 연구가 절실히 필요한 실정이다. 본 논문에서는 ISO26262의 적용에 따라 EFS를 어떻게 적용할 수 있는가를 검토하였다. 이러한 검토 결과를 적용하여 자동차의 기능 안전성 확보를 위해 EFS 평가를 강제 법규화하거나 또는 신차 안전도 평가(NCAP) 항목으로 확대 적용함으로써 제작사 스스로가 안전성 확보를 위한 절차를 수행하도록 규정할 필요가 있다.

• International Journal of Internet, Broadcasting and Communication
• /
• 제15권3호
• /
• pp.219-230
• /
• 2023

With the development of autonomous driving technology, as the use of software in vehicles increases, the complexity of the system increases and the difficulty of development increases. Developments that meet ISO 26262 must be carried out to reduce the malfunctions that may occur in vehicles where the system is becoming more complex. ISO 26262 for the functional safety of the vehicle industry proposes to consider functional safety from the design stage to all stages of development. Specifically at the software level, the requirements to be complied with during development and the requirements to be complied with during verification are defined. However, it is not clearly expressed about specific design methods or development methods, and it is necessary to supplement development guidelines. The importance of analysis and verification of requirements is increasing due to the development of technology and the increase of system complexity. The vehicle industry must carry out developments that meet functional safety requirements while carrying out various development activities. We propose a process that reflects the perspective of system engineering to meet the smooth application and developmentrequirements of ISO 26262. In addition, the safety analysis/verification FMEA processforthe safety of the proposed ISO 26262 function was conducted based on the FCAS (Forward Collision Avoidance Assist System) function applied to autonomous vehicles and the results were confirmed. In addition, the safety analysis/verification FMEA process for the safety of the proposed ISO 26262 function was conducted based on the FCAS (Forward Collision Avoidance Assist System) function applied to the advanced driver assistance system and the results were confirmed.

• International Journal of Reliability and Applications
• /
• 제15권2호
• /
• pp.151-161
• /
• 2014

Recently, the automotive industry has been introduced to ISO 26262 in November 2011 to address the necessity of safety risk from sensor to actuator by providing guidance in the form of requirements and processes. The malfunctioning behaviour of these systems could have significant impact on the safety of humans and/or the environment. Most of the modern automobiles are equipped with embedded electronic systems which include lots of Electronic Controller Units (ECUs), electronic sensors, signals, bus systems and coding. Due to the complex application in electrical, electronics and programmable electronics, the need to carry out detailed safety analyses which focuses on the potential risk of malfunction is crucial for automotive systems. In this paper, the international trends on pre and post introduction of ISO 26262 through publications will be analyzed as well as to take a glimpse in the activities for implementing this standard by the automotive manufacturers. The issues and challenges which have been occurring from implementing this standard also will be highlighted.

• 한국멀티미디어학회논문지
• /
• 제21권9호
• /
• pp.1099-1109
• /
• 2018

Most of the automotive electronic systems are equipped with control software. ISO 26262 standard has been published to prevent unreasonable risk due to E/E system malfunction. And many automotive companies apply ISO 26262 for safe series product. In ISO 26262 standard, the product quality improves through deductive and inductive safety analysis in all processes including system and software development phase. However, there are few studies on software safety analysis than systems. In the paper, we study the software FMEA(Failure Mode Effect Analysis) technique for product quality of vehicular embedded software. And we propose an effective guideline of software FMEA as EPB industrial practice.

• 시스템엔지니어링학술지
• /
• 제17권2호
• /
• pp.129-138
• /
• 2021

Today, as the number of vehicles equipped with autonomous driving functions increases, the use of various sensors increases, and the complexity of system configuration increases. The ISO 26262 standard was published to prevent caused by systematic errors. Recently, the issue of external environmental factors rather than mechanical failure has increased. This issue is a problem outside of the scope of ISO 26262, and the ISO/DIS 21448 standard was published to solve this problem. Also, Mobileye proposed the RSS model that defined safe distance for dangerous situations in order to secure the safety of autonomous vehicles and who is responsible in case of an accident. In this paper, integrated process of ISO 21448 and RSS model, and through these results, we expect that possible to contribute to securing the safety and reliability of autonomous vehicles in the future.

• ETRI Journal
• /
• 제42권4호
• /
• pp.468-479
• /
• 2020

The proposed AI processor architecture has high throughput for accelerating the neural network and reduces the external memory bandwidth required for processing the neural network. For achieving high throughput, the proposed super thread core (STC) includes 128 × 128 nano cores operating at the clock frequency of 1.2 GHz. The function-safe architecture is proposed for a fault-tolerance system such as an electronics system for autonomous cars. The general-purpose processor (GPP) core is integrated with STC for controlling the STC and processing the AI algorithm. It has a self-recovering cache and dynamic lockstep function. The function-safe design has proved the fault performance has ASIL D of ISO26262 standard fault tolerance levels. Therefore, the entire AI processor is fabricated via the 28-nm CMOS process as a prototype chip. Its peak computing performance is 40 TFLOPS at 1.2 GHz with the supply voltage of 1.1 V. The measured energy efficiency is 1.3 TOPS/W. A GPP for control with a function-safe design can have ISO26262 ASIL-D with the single-point fault-tolerance rate of 99.64%.

• 전기학회논문지
• /
• 제65권12호
• /
• pp.2030-2036
• /
• 2016

This paper presents a hardware development procedure of the ASB(Active Seat Belt) control system to comply with ISO 26262. The ASIL(Automotive Safety Integrity Level) of an ASB system is determined through the HARA(Hazard Analysis and Risk Assessment) and the safety mechanism is applied to meet the reqired ASIL. The hardware architecture of the controller consists of a microcontroller, H-bridge circuits, passive components, and current sensors which are used for the input comparison. The required ASIL for the control systems is shown to be satisfied with the safety mechanism by calculation of the SPFM(Single Point Fault Metric) and the LFM(Latent Fault Metric) for the design circuits.

• 정보처리학회논문지:소프트웨어 및 데이터공학
• /
• 제6권4호
• /
• pp.167-176
• /
• 2017

자동차 산업이 급격히 발달하면서 각종 인명손실을 예방하기 위한 정책 및 안전장치가 늘어나고 있다. 트렌드의 일환으로 2011년에 차량의 전기전자시스템의 기능안전성을 확보하기 위한 ISO26262 $1^{st}$ edition이 릴리즈 되었으며, 2016년 하반기에 $2^{nd}$ edition이 릴리즈 될 예정이다. ISO 26262에서는 안전 요구사항에 대해 Walk through, 인스펙션, 준정형 검증, 정형 검증을 통해 전기전자시스템 요구사항에 대한 검증을 요구하고 있다. 본 논문에서는 ASIL (Automotive Safety Integrity Level) D등급의 전자식 주차 브레이크 양산 프로젝트의 전기전자시스템 요구사항 검증에 모델검증을 적용함으로써 전기전자시스템 요구사항 검증 시 모델검증의 효율성을 기술한다.

• International Journal of Internet, Broadcasting and Communication
• /
• 제13권3호
• /
• pp.169-177
• /
• 2021

Recently, the use of electric and electronic control systems is increasing in the automobile industry. This increase in the electric and electronic control system greatly increases the complexity of designing a vehicle, which leads to an increase in the malfunction of the system, and a safety problem due to the malfunction is becoming an issue. Based on IEC 61508 relating to the functional safety of electrical/electronic/programmable electronics, the ISO 26262 standard specific to the automotive sector was first established in 2011, and a revision was published in 2018. Malfunctions due to system failure are covered by ISO 26262, but ISO/PAS 21448 is proposed to deal with unintended malfunctions caused by changes in the surrounding environment. ISO 26262 sets out safety-related requirements for the entire life cycle. Functional safety analysis includes FTA (Fault Tree Analysis), FMEA (Failure Mode and Effect Analysis), and HAZOP (Hazard and Operability). These analysis have limitations in dealing with failures or errors caused by complex interrelationships because it is assumed that a failure or error affecting the risk occurs by a specific component. In order to overcome this limitation, it is necessary to apply the STPA (System Theoretic Process Analysis) technique.