It is very crucial activities that Korean army have to detect and recognize enemy’s locations and types of weapon of their artillery firstly for effective operation of friendly force’s artillery weapons during wartime. For these activities, one of the most critical artillery weapon systems is the anti-artillery radar (hereafter; radars) for immediate counter-fire operations against the target. So, in early wartime these radar’s roles are very important for minimizing friendly force’s damage because arbiters have to recognize a several enemy’s artillery positions quickly and then to take an action right away. Up to date, Republic of Korea Army for tactical artillery operations only depends on individual commander’s intuition and capability. Therefore, we propose these radars allocation model based on integer programming that combines ArcGIS (Geographic Information System) analysis data and each radar’s performances which include allowable specific ranges of altitude, azimuth (FOV; field of view) and distances for target detection, and weapons types i.e., rocket, mortars and cannon ammo etc. And we demonstrate the effectiveness of their allocation’s solution of available various types of radar asset through several experimental scenarios. The proposed model can be ensured the optimal detection coverage, the enhancement of artillery radar’s operations and assisting a quick decision for commander finally.

Artillery fire power due to effectiveness which is hard to predict well-planned and surprising attack can give a fear and shock to the personnel and is a very core weapon system and takes a critical role in wartime. Therefore in order to maximize operational effectiveness, Army required protecting artillery and takes a quick attack action through rapid construction of artillery’s positions. The artillery use artillery’s position to prevent exposure by moving to other position frequently. They have to move and construct at new artillery’s positions quickly against exposing existed place by foe’s recognition. These positions should be built by not manpower but engineering construction equipment. Because artillery positions have to protect human and artillery equipment well and build quickly. Military engineering battalion have lots of construction equipment which include excavator, loader, dozer, combat multi-purposed excavator, armored combat earthmover dump truck and so on. So they have to decide to optimal number of Team combining these equipments and determine construction sequence of artillery’s position in operational plan. In this research, we propose to decide number of Team efficiently and allocate required construction’s positions for each Team under constraints of limited equipments and time. To do so, we develop efficient heuristic method which can give near optimal solution and be applied to various situation including commander’s intention, artillery position’s priority or grouping etc. This heuristic can support quick and flexible construction plan of artillery positions not only for using various composition’s equipment to organize Teams but also for changing quantity of positions.

A vendor selection problem consists of two different kinds of decision making. First one is to choose the best suppliers among all possible suppliers and the next is to allocate the optimal quantities of orders among the selected vendors. ln this study, a

본 연구는 롤러코스터 구조물의 구조적인 결함을 검출하기 위해서 요구되는 최적의 센서를 구성하기 위한 연구이다. 특수한 목적과 구조적인 형태의 롤러코스터를 3차원 FE 모델링을 통해 구조적 거동특성을 분석하고, 최적계측/센서 이론을 통해 합리적인 센서 위치 및 개수를 구성하였으며, 구성된 최적 센서 위치 및 개수를 바탕으로 손상 전․후에 따른 수치적인 모달 특성값을 추출해 손상평가에 활용될 기본 구조물에 대한 기초자료를 제공하였다. 본 연구의 대상구조물로 서울 어린이대공원에 위치한 롤러코스터 구조물을 선정하였고, 1/20 크기로 축소한 모형 구조물을 제작･활용하였다. 또한, 롤로코스트의 공간적인 구조의 특성으로 운동학(Kinetics)적 거둥에 따른 운동역학(Kinematics)적인 특성이 포함되도록 Spline 함수를 이용해 대상 모형 구조물을 정확히 3차원 FE 모델을 구성 후, 가이언 소거법에 근거한 모달 특성값을 추출하였고, 유효독립법(EIM) 및 최적운동에너지법(EOT) 이론을 바탕으로 최적계측/센서 위치 및 개수를 구성하였으며, 손상 전․후에 따른 모달 특성값을 추출해 크게 강성도, 유연도, 모드상관도의 관계로부터 손상(결함)을 평가하였다. 최종적으로, 본 논문에서 구성된 최적 계측/센서 이론이 타당함을 확인하였고, 강성도 및 유연도 변화를 통해 만족할 수준으로 손상이 규명되었다. 이 결과 롤러코스터 구조물의 건전도 모니터링에 필요한 거동특성 분석 및 결함검출기술 개발에 관한 최적 센서의 구성을 제시 하였다.

In this paper, we deal with an allocation model of vertical type container yard for minimizing the total ATC (Automated Transfer Crane) working time and the equivalence of ATC working load in each block on automated container terminal. Firstly, a layout of automated container terminal yard is shown The characteristic of equipment which work in the terminal and its basic assumption are given Next, an allocation model which concerns with minimizing the total working time and the equivalence of working load is proposed for effectiveness of ATC working in automated container terminal. Also, a weight values on critical function are suggested to adjust the critical values by evaluating the obtained allocation plan. For ATC allocation algorithm, we suggest a simple repeat algorithm for on-line terminal operation.

선박이 해상에서 조난을 당했을 경우 인명과 재산 및 해양 환경보호를 위하여 조난자 및 조난선박을 신속히 수색ㆍ구조 함으로써 해양사고로 인한 인적, 물적 피해 및 해양환경의 피해를 최소화 할 필요가 있다. IMO에서 채택한 SAR협약은 우리나라에서는 1995년 발효되었고 국세적으로는 해양경찰청이 SAR협약의 이행기관이 되었다. 해상에서 조난자나 조난선박의 구조 및 발견 가능성은 시간이 경과함에 따라 급속히 감소하기 때문에 SAR임무의 핵심은 효율적인 수색ㆍ구조 계획을 통해 신속하게 생존자를 수색ㆍ구조하는 것이라 할 수 있다. 본 연구에서는 해양사고가 발생한 경우 구조선이 최단시간 내에 조난현장에 도착 할 수 있는 해상 수색ㆍ구조선 최적배치 모델을 정식화 하였다. 또한 해양경찰청의 구조선의 운용과 기술적인 능력을 고려하여 우리나라 수색 구조 구역을 180개의 소구역으로 나누고 최적배치 위치 및 척수를 구하였으며, 구조선의 합리적인 운용을 위해 추가적으로 소요되는 척수를 산정하였다.

Nowaday all the countries of the world have studied the various problems caused in operating their own ports efficiently. Ship delay in the port is attributal to the inefficient operation in the navigation aids, the cargo handling, the storage and transfer facilities, and to the inefficient allocation of gangs or to a bad service for ships. Among these elements the allocation of gangs is the predominating factor in minimizing ship's turn round time. At present, in the case of Pusan Port. the labour union and stevedoring companies allocate gangs in every hatches of ships by a rule of thumb, just placing emphasis on minimizing ship's turn round time, without applying the principle of allocation during the cargo handling. Owing to this the efficiency of the cargo handling could not be expected to be maximized and this unsystematic operation result in supplying human resources of much unnecessary surplus gangs. Therefore in this paper the optimal size and allocation of gangs for minimizing the ship's turn round time is studied and formularized. For the determination of the priority for allocation the evaluation function, namely F=PHin×(W+H), can be obtained; where, PHI : Principal Hatch Index W : Total Cargo Weight represented in Gang-Shifts H : Total Number of Ship's hatches and also for the optimal size of gangs the average number of gang allocated per shift (Ng), namely Ng=W/PHI, is used. The proposed algorithm is applied to Pusan Port and its validity is verified.