• Journal of Information Processing Systems
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• 제5권3호
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• pp.117-130
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• 2009

By providing ubiquitous Internet connectivity, wireless networks offer more convenient ways for users to surf the Internet. However, wireless networks encounter more technological challenges than wired networks, such as bandwidth, security problems, and handoff latency. Thus, this paper proposes new technologies to solve these problems. First, a Security Access Gateway (SAG) is proposed to solve the security issue. Originally, mobile terminals were unable to process high security calculations because of their low calculating power. SAG not only offers high calculating power to encrypt the encryption demand of SAG's domain, but also helps mobile terminals to establish a multiple safety tunnel to maintain a secure domain. Second, Robust Header Compression (RoHC) technology is adopted to increase the utilization of bandwidth. Instead of Access Point (AP), Access Gateway (AG) is used to deal with the packet header compression and de-compression from the wireless end. AG's high calculating power is able to reduce the load on AP. In the original architecture, AP has to deal with a large number of demands by header compression/de-compression from mobile terminals. Eventually, wireless networks must offer users "Mobility" and "Roaming". For wireless networks to achieve "Mobility" and "Roaming," we can use Mobile IPv6 (MIPv6) technology. Nevertheless, such technology might cause latency. Furthermore, how the security tunnel and header compression established before the handoff can be used by mobile terminals handoff will be another great challenge. Thus, this paper proposes to solve the problem by using Early Binding Updates (EBU) and Security Access Gateway (SAG) to offer a complete mechanism with low latency, low handoff mechanism calculation, and high security.

• 한국산학기술학회논문지
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• 제8권4호
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• pp.781-787
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• 2007

NEMO(Network Mobility) 기본 지원 프로토콜은 경로 최적화 과정을 수행하고 있지 않으며 MR(Mobile Router)과 HA(Home Agent) 사이의 양방향 터널 구간을 제외한 다른 구간에서는 특별한 보안 메커니즘을 제시하고 있지 않다. 따라서 본 논문에서는 MR과 MNN(Mobile Network Node) 사이의 양방향 터널을 통해 위임 권한 프로토콜을 수행하고 위임 권한을 획득한 MR과 CN (Correspondent Node) 사이에 인증된 바인딩 갱신 프로토콜을 통해 경로를 안전하게 최적화한다. 각 노드의 주소는 주소 소유권 증명을 위해 CGA(Cryptographically Generated Address)방식을 통해 생성한다. 끝으로 NEMO에서의 보안 요구사항과 기존에 알려진 공격을 통해 안전성을 분석하고 NEMO 지원 프로토콜과 연결성 복구력(connectivity recovery)과 종단간 패킷 전송 지연 시간율(end-to-end packet transmission delay time)을 비교하여 효율성을 분석한다.