본 논문에서는 표적의 레이다 반사면적 기여도 분석을 통한 전파흡수체 적용에 대한 레이다 반사면적 감소 효과와 최신 전파흡수체 기술인 메타물질을 적용한 레이다 반사면적 감소 효과를 고찰하였다. 레이다 반사면적 해석은 모형선 모델로 진행하였고, 레이다 반사면적 기여도 분석을 통하여 전파흡수체와 메타물질의 레이다 반사면적 평균값 감소 효과를 확인하였다.

레이다비콘(Racon)은 선박이 운항하면서 해상에 짙은 안개가 끼거나, 야간 등 시계가 불량할 때 위험한 암초 등 항행 장해물을 회피하거나, 지정된 항로를 레이다 화면에 표시하여 항해자가 안전하게 운항할 수 있도록 도와주는 항행장비이다. 기존 레이다비콘에 AIS(Automatic Identification System)기능을 부가한 차세대 레이콘 e-Racon(Enhanced Radar Beacon) 개발을 연구하면서 기존의 안테나를 IALA Rec. R-101 이 규정하는 안테나 요구사항에 적합한 e-Racon 안테나로 기능을 개선하는 연구를 하였다.

The coaxial sample holder with 20mm in diameter and the adaptor from type N connector-to-20mmΦ coaxial tube are designed and manufactured which have been used for designing and measuring the fabricated microwave absorber. In addition, the measure in method of material constants of the microwave absorbers is described, which is focused on minimizing the error due to the sample's shapes, the fitting conditions, etc. After describing the design method of a single-layed microwave absorber, the microwave absorbers for X-band, C-band and S-band RADARs are designed and fabricated, respectively, which are composed of ferrite, carborn, and binder and have good performance. Futhermore, we develop the high performance microwave absorber in extremely wide-band type for RADAR, which is composed of different material and its mixing ratio and which could cover nearly from 4 to 10 GHz.

Microwave absorbers for X-Band RADAR have been designed and fabricated trialy both in sheet and paint types, as a result of which the relative bandwidth of nearly 8% in both cases has been obtained under the tolerance limits of the reflection coefficients lower than -20dB. The matching thickness becomes 1.36 to 1.56mm which is significantly thinner than that of the conventional ones. Furthermore, it was shown that the microwave absorbing characteristics vary in accordance with the density and the mixing ratios of the materials constituting absorbs.

Many new radar techniques have appeared on the electronic scene in recent years, such as a variety of automatic computer processing. However, even with the advent of these sophisticated radar techniques, an old problem continues to plague all radars: the problem of transmission line losses. With the higher performance required today, the Waveguide testing and trouble-shooting techniques remain essentially unchanged in principle. This paper dealt with the rf pulse "Time-domain Reflectometry" to inspect radar wave-guide system and compared with the conventional methods. During the investigation, it was verified that the pulsed TDR for wave-guide is superior to the conventional methods; 1. Disassembling is not needed to locate the discontinity points and measure the reflections of trobled points. 2. The results of the data are more precise. 3. The condition of individual component is able to the photographed and recorded permanently. 4. Since rf pulse TDR is based on the well-known basic radar principle, such a test set requires the minimum of training to operate. With the level of transmission line problems, the prospect of increasing complexity of equipment, and no relief in sight, the benifits must be emphasizied to adopt such a testing procedure.procedure.

A large number of the set-nets are set in Namhaedo coast of Korea. The floats of these set-nets are not only small even in case of large floats but also they scarcely have distinguishable marks such as light buoys or flags, so that they are very hard to be recognized by naked eyes and thus became probable obstacles to navigation for the passing ships and the fishing vessels. In order to research the capability of detecting such nets with Radar, the author investigated a maximum detectable range of the ordinarly large floatsand of a floating corner reflectors of various size and shape by Radar. The results obtained are as follows; 1. A maximum detectable range of large floats at a close range can be calculated by the Radar equation in sufficient accuracy. 2. Large floats of the large set-nets are also detectable by Radar even though it's detectable range boundary was within 0.2-0.65 miles. And the Radar picture of large floats was easier to be found with somewhat higher setting of the gain control on shorter range scale of the 1 mile. 3. Floating corner reflector rather suitable for set-net floats of "S" type reflector proposed in this paper, of which the dimension must be above 17cm in diameter to be detectable by Radar at 2 miles.t 2 miles.