• Nuclear Engineering and Technology
• /
• 제41권5호
• /
• pp.747-752
• /
• 2009

A vulnerability assessment is essential for the efficient operation of a physical protection system (PPS). Previous assessment codes have used a simple model called an adversary sequence diagram. In this study, the use of a two-dimensional (2D) map of a facility as a model for a PPS is suggested as an alternative approach. The analysis of a 2D model, however, consumes a lot of time. Accordingly, a generalized heuristic algorithm has been applied to address this issue. The proposed assessment method was implemented to a computer code; Systematic Analysis of physical Protection Effectiveness (SAPE). This code was applied to a variety of facilities and evaluated for feasibility by applying it to various facilities. To help upgrade a PPS, a sensitivity analysis of all protection elements along a chosen path is proposed. SAPE will help to accurately and intuitively assess a PPS.

• Nuclear Engineering and Technology
• /
• 제52권8호
• /
• pp.1661-1668
• /
• 2020

A physical protection system (PPS) is used for the protection of critical facilities. This paper proposes a structure analytic hierarchy approach (SAHA) for the hierarchical evaluation of the PPS effectiveness in critical infrastructure. SAHA is based on the traditional analysis methods "estimate of adversary sequence interruption, EASI". A community algorithm is used in the building of the SAHA model. SAHA is applied to cluster the associated protection elements for the topological design of complicated PPS with graphical vertexes equivalent to protection elements.

• Nuclear Engineering and Technology
• /
• 제54권10호
• /
• pp.3604-3613
• /
• 2022

The Physical Protection System (PPS) plays an important role and must effectively deal with various adversary attacks in nuclear security. In specific single adversary path scenarios, we can calculate the PPS effectiveness by EASI (Estimated Adversary Sequence Interruption) through Probability of Interruption (P_I) calculation. EASI uses a single value of the probability of detection (P_D) and the probability of alarm communications (P_C) in the PPS. In this study, we develop a multi-path analysis code based on EASI to evaluate the effectiveness of PPS. Our quantification method for P_I considers the variability and uncertainty of P_D and P_C value by Monte Carlo simulation. We converted the 2-D scheme of the nuclear facility into an Adversary Sequence Diagram (ASD). We used ASD to find the adversary path with the lowest probability of interruption as the most vulnerable paths (MVP). We examined a hypothetical facility (Hypothetical National Nuclear Research Facility - HNNRF) to confirm our code compared with EASI. The results show that implementing the variability extension can estimate the P_I value and its associated uncertainty. The multi-path analysis code allows the analyst to make it easier to assess PPS with more extensive facilities with more complex adversary paths. However, the variability of the P_D value in each protection element allows a significant decrease in the PI value. The possibility of this decrease needs to be an important concern for PPS designers to determine the P_D value correctly or set a higher standard for PPS performance that remains reliable.

• Nuclear Engineering and Technology
• /
• 제54권6호
• /
• pp.2135-2146
• /
• 2022

A nuclear energy facility is one of the most critical facilities to be safely protected during and after operation because the physical destruction of its barriers by an external attack could release radioactivity into the environment and can cause harmful effects. The barrier walls of nuclear energy facilities should be sufficiently robust to protect essential facilities from external attack or sabotage. Physical protection system (PPS) vulnerability assessment of a typical small nuclear research reactor was carried out by simulating an external attack with a tri-nitro toluene (TNT) shaped charge and results are presented. The reinforced concrete (RC) barrier wall of the research reactor located at a distance of 50 m from a TNT-shaped charge was the target of external attack. For the purpose of the impact assessment of the RC barrier wall, a finite element method (FEM) is utilized to simulate the destruction condition. The study results showed that a hole-size of diameter 342 mm at the front side and 364 mm at the back side was created on the RC barrier wall as a result of a 143.35 kg TNT-shaped charge. This aperture would be large enough to let at least one person can pass through at a time. For the purpose of the PPS vulnerability assessment, an Estimate of Adversary Sequence Interruption (EASI) model was used, which enabled the determination of most vulnerable path to the target with a probability of interruption equal to 0.43. The study showed that the RC barrier wall is vulnerable to a TNT-shaped charge impact, which could in turn reduce the effectiveness of the PPS.

• 시큐리티연구
• /
• 제61호
• /
• pp.9-38
• /
• 2019

한국의 국가기반시설은 시설규모가 증가하고 밀집되어 강화된 북한의 국지도발, 테러공격을 위한 풍부하고 매력적인 잠재적 표적으로 식별될 것이다. 또한 드론위협, 주 52시간 근무제도에 따른 경비병력 부족 등의 보안환경 변화에 따라 현 물리적 방호체계에 대한 유효성과 적절성을 재평가하고 전환을 고려할 시점으로 사료된다. 본 연구에서는 국가기반시설 중 원자력발전소의 외곽 물리적 방호체계에 집중하여 국가 기반시설 외곽 물리적 방호체계의 전환 방향과 개선방안을 운영개념 및 설계 방법론 측면에서 연구하였다. 원자력발전소에 집중하는 이유는 원자력발전소는 피해 시 전기발전 중단의 단기적인 피해와 함께, 방사능 물질 유출과 오염에 따르는 광범위하고 장기적인 피해가 발생하므로 가장 높은 보안수준을 필요로 하기 때문이다. 개선방향 도출 목표로 국내 연구동향과 국내·해외 관련법을 종합 검토하고 한국의 특수성을 고려하여, 과학화, 기동화, 유연성으로 운영개념을 재설정하고 체계전환의 기준을 수립하였다. 새로운 외곽 물리적 방호체계의 기술적 성능개선을 위하여 개별설계에서 탈피, 고신뢰성·다방법론 기반의 통합설계 방법론 적용방안을 연구하고 구매제도 개선 및 해외 수출, 타(他)국가기반시설로의 확대적용을 제언한다.

• 사물인터넷융복합논문지
• /
• 제7권1호
• /
• pp.9-19
• /
• 2021

원자력 테러 예방을 위해 기존의 물리 보호 시스템(PPS)를 수정한 빅데이터 기반의 클라우드 컴퓨팅 시스템과 통합된 데이터 마이닝 디자인이 조사됩니다. 원자력 범죄사건에 대해 시뮬레이션 연구에 의해 테러 관련 기관의 네트워킹이 모델링됩니다. 불법 도청 없이 무고한 사람들을 공격하려는 시도와 테러리즘을 정부가 탐지할 필요가 있습니다. 이 연구의 수학적 알고리즘은 테러 사건의 정확한 결과를 제공할 수 없지만, 시뮬레이션을 통해 잠재적 가능성을 얻을 수 있습니다. 본 결과는 시간에 따른 모양 진동을 보여줍니다. 또한 각 값의 빈도를 통합하면 결과의 전환 정도를 알 수 있습니다. 값은 63.125 시간에 -2.61741로 증가합니다. 따라서 테러 가능성은 나중에 가장 높습니다.