합동전술정보분배체계는 미국, 북대서양조약기구 및 기타 연합군에서 운용하고 있는 Link-16의 통신 터미널로 사용된다. 최근 민간 항공분야에서의 교통량 증가로 인해 주파수 수요가 급증함에 따라 Link-16에서 사용 중인 주파수는 다른 시스템에 재할당될 예정이며, 이는 Link-16의 성능에 영향을 미칠 것으로 예상된다. 따라서 본 논문에서는 주파수 대역 감소에 따른 Link-16 성능의 영향을 모의실험과 수치 해석을 통해 기존 성능과 비교하였다. 성능 분석 결과, Nakagami 페이딩과 부분대역 잡음 재밍 환경에서 주파수가 재할당된 Link-16은 성능이 감소됨에도 불구하고 높은 항재밍 능력을 유지하였으며, 동일 시간슬롯에서 다수 사용자들을 지원할 수 있음을 확인하였다.
합동전술정보분배체계는 미국, 북대서양조약기구 및 기타 연합군에서 운용하고 있는 Link-16의 통신 터미널로 사용된다. 최근 민간 항공분야에서의 교통량 증가로 인해 주파수 수요가 급증함에 따라 Link-16에서 사용 중인 주파수는 다른 시스템에 재할당될 예정이며, 이는 Link-16의 성능에 영향을 미칠 것으로 예상된다. 따라서 본 논문에서는 주파수 대역 감소에 따른 Link-16 성능의 영향을 모의실험과 수치 해석을 통해 기존 성능과 비교하였다. 성능 분석 결과, Nakagami 페이딩과 부분대역 잡음 재밍 환경에서 주파수가 재할당된 Link-16은 성능이 감소됨에도 불구하고 높은 항재밍 능력을 유지하였으며, 동일 시간슬롯에서 다수 사용자들을 지원할 수 있음을 확인하였다.
The joint tactical information distribution system (JTIDS) is used as the communication terminal of Link-16 by the United States armed forces, north atlantic treaty organization (NATO), and other allied forces. A portion of Link-16 frequencies may be shortly remapped to other systems owing to the gr...
The joint tactical information distribution system (JTIDS) is used as the communication terminal of Link-16 by the United States armed forces, north atlantic treaty organization (NATO), and other allied forces. A portion of Link-16 frequencies may be shortly remapped to other systems owing to the growing demand for frequencies, especially in civil aviation, which is witnessing a constant increase in air traffic. This will affect the performance of Link-16. Therefore, in this paper, we analyze the effect of frequency band reduction on the performance of Link-16 waveform under partial-band noise jamming with Nakagami fading, via simulation and numerical analysis. The multi-net and anti-jamming performance of Link-16 with frequency remapping is compared with that of conventional Link-16 systems. The results show that the performance of Link-16 waveform is degraded with the reduction in frequencies. Nonetheless, Link-16 retains its jam resistance, and it can support multiple users in the same time slots.
The joint tactical information distribution system (JTIDS) is used as the communication terminal of Link-16 by the United States armed forces, north atlantic treaty organization (NATO), and other allied forces. A portion of Link-16 frequencies may be shortly remapped to other systems owing to the growing demand for frequencies, especially in civil aviation, which is witnessing a constant increase in air traffic. This will affect the performance of Link-16. Therefore, in this paper, we analyze the effect of frequency band reduction on the performance of Link-16 waveform under partial-band noise jamming with Nakagami fading, via simulation and numerical analysis. The multi-net and anti-jamming performance of Link-16 with frequency remapping is compared with that of conventional Link-16 systems. The results show that the performance of Link-16 waveform is degraded with the reduction in frequencies. Nonetheless, Link-16 retains its jam resistance, and it can support multiple users in the same time slots.
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문제 정의
) is the average fading power, m is the Nakagami fading parameter (m ≥ 1/2), and Γ(∙) is the Gamma function. The purpose of this paper is the comparison of performance when the frequency bands of Link-16 are remapped to other systems. Futhermore JTIDS is operated in the UHF band (LOS is required) [4].
가설 설정
1) Both signals do not undergo jamming.
2) One signal undergoes jamming, whereas the other does not.
3) Both signals undergo jamming independently.
제안 방법
; however, most studies focused on pulsed-noise interference (PNI), and they did not consider the frequency remapping of Link-16. In this paper, we analyze the effect of frequency band reduction on Link-16 performance when a portion of Link-16 frequencies is used by other systems. This is achieved via analysis of multi-net and anti-jamming performance under Nakagami fading with partial-band noise (PBN) jamming.
In the double-pulse structure, diversity gain can be achieved in the frequency domain because two symbols are transmitted through different frequencies. In this study, the received signal is decoded by using the selection combining (SC) for multi-net performance analysis and maximum ratio combining (MRC) techniques for anti-jamming performance analysis. The SC technique selects the strongest received signal, whereas the gain of each channel is made proportional to the rms signal level and inversely proportional to the mean square noise level of the channel in the MRC technique.
In this study, we investigated the probability of symbol error and the number of available multi-nets for Link-16 by considering frequency remapping. Through the numerical analysis and extensive simulation, we arrived at the following conclusions.
We evaluated the multi-net performance of Link-16 waveform by using a MATLAB simulator. The simulation parameters are listed in Table 1.
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