The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
차세대 인터넷 이니셔티브(Next Generation Internet Initiative)는 인터넷에서 새로운 애플리케이션 물결을 가능하게 하는 주요 네트워킹 기술을 발전시키기 위해 미국에서 시작되었습니다. 이제 XNUMX년차가 된 이 프로그램은 학계, 산업계, 정부 연구소와 협력하여 XNUMX개 이상의 새로운 연구 프로젝트를 시작하고 육성했습니다. 프로그램 내에서 강조된 핵심 연구 분야 중 하나는 차세대 광 네트워킹입니다. 네트워크 대역폭에 대한 수요가 계속 증가하고 최근 WDM 기술의 놀라운 발전을 고려할 때 차세대 인터넷은 IP 기반 광 WDM 네트워크가 될 것으로 예상됩니다. IP over WDM 네트워킹 기술이 발전함에 따라 여러 가지 중요한 아키텍처, 관리 및 제어 문제가 표면화되었습니다. 진정한 차세대 광인터넷이 등장하기 전에 이러한 문제를 해결해야 합니다. 이 문서에서는 DARPA NGI 프로그램의 전반적인 목표와 활동에 대한 간략한 소개를 제공하고 광 인터넷의 주요 아키텍처, 관리 및 제어 문제에 대해 설명합니다. 다양한 IP/WDM 네트워킹 아키텍처 모델과 그 장단점을 검토합니다. 동적 WDM 네트워크를 통한 IP의 구성, 오류 및 성능 관리와 관련된 여러 관리 및 제어 문제와 가능한 솔루션을 간략하게 설명하고 논의합니다. 우리는 WDM 네트워크에 비해 동적 IP의 잠재적 이점을 보여주는 분석 및 지원 시뮬레이션 결과를 제시합니다. 그런 다음 IP/WDM 트래픽 엔지니어링과 관련된 문제를 더 자세히 논의하고 DARPA가 자금을 지원하는 NGI SuperNet 네트워크 제어 및 관리 프로젝트에서 취한 접근 방식을 제시합니다. 특히, 우리는 재구성 가능한 IP/WDM 네트워크를 위한 혁신적인 통합 트래픽 엔지니어링 프레임워크에 대한 동기를 부여하고 제시합니다. 이는 세분화된 IP 로드 밸런싱을 위한 MPLS(Multi-Protocol Label Switching)의 강점과 IP 네트워크의 가중 홉 거리를 줄이고 병목 대역폭을 확장하기 위한 재구성 가능한 WDM 네트워킹의 강점을 기반으로 구축되었습니다.
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John Y. WEI, Chang-Dong LIU, Sung-Yong PARK, Kevin H. LIU, Ramu S. RAMAMURTHY, Hyogon KIM, Mari W. MAEDA, "Network Control and Management for the Next Generation Internet" in IEICE TRANSACTIONS on Communications,
vol. E83-B, no. 10, pp. 2191-2209, October 2000, doi: .
Abstract: The Next Generation Internet Initiative was launched in the U.S. to advance key networking technologies that will enable a new wave of applications on the Internet. Now, in its third year, the program has launched and fostered over one hundred new research projects in partnership with academic, industrial and government laboratories. One key research area that has been emphasized within the program is the next-generation optical networking. Given the ever increasing demand for network bandwidth, and the recent phenomenal advances in WDM technologies, the Next Generation Internet is expected to be an IP-based optical WDM network. As IP over WDM networking technologies mature, a number of important architectural, management and control issues have surfaced. These issues need to be addressed before a true Next Generation Optical Internet can emerge. This paper provides a brief introduction to the overall goals and activities of DARPA's NGI program and describes the key architectural, management, and control issues for the Optical Internet. We review the different IP/WDM networking architectural models and their tradeoffs. We outline and discuss several management and control issues and possible solutions related to the configuration, fault, and performance management of IP over dynamic WDM networks. We present an analysis and supporting simulation results demonstrating the potential benefits of dynamic IP over WDM networks. We then discuss the issues related to IP/WDM traffic engineering in more detail, and present the approach taken in the NGI SuperNet Network Control and Management Project funded by DARPA. In particular, we motivate and present an innovative integrated traffic-engineering framework for re-configurable IP/WDM networks. It builds on the strength of Multi-Protocol Label Switching (MPLS) for fine-grain IP load balancing, and on the strength of Re-configurable WDM networking for reducing the IP network's weighted-hop-distance, and for expanding the bottleneck bandwidth.
URL: https://global.ieice.org/en_transactions/communications/10.1587/e83-b_10_2191/_p
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@ARTICLE{e83-b_10_2191,
author={John Y. WEI, Chang-Dong LIU, Sung-Yong PARK, Kevin H. LIU, Ramu S. RAMAMURTHY, Hyogon KIM, Mari W. MAEDA, },
journal={IEICE TRANSACTIONS on Communications},
title={Network Control and Management for the Next Generation Internet},
year={2000},
volume={E83-B},
number={10},
pages={2191-2209},
abstract={The Next Generation Internet Initiative was launched in the U.S. to advance key networking technologies that will enable a new wave of applications on the Internet. Now, in its third year, the program has launched and fostered over one hundred new research projects in partnership with academic, industrial and government laboratories. One key research area that has been emphasized within the program is the next-generation optical networking. Given the ever increasing demand for network bandwidth, and the recent phenomenal advances in WDM technologies, the Next Generation Internet is expected to be an IP-based optical WDM network. As IP over WDM networking technologies mature, a number of important architectural, management and control issues have surfaced. These issues need to be addressed before a true Next Generation Optical Internet can emerge. This paper provides a brief introduction to the overall goals and activities of DARPA's NGI program and describes the key architectural, management, and control issues for the Optical Internet. We review the different IP/WDM networking architectural models and their tradeoffs. We outline and discuss several management and control issues and possible solutions related to the configuration, fault, and performance management of IP over dynamic WDM networks. We present an analysis and supporting simulation results demonstrating the potential benefits of dynamic IP over WDM networks. We then discuss the issues related to IP/WDM traffic engineering in more detail, and present the approach taken in the NGI SuperNet Network Control and Management Project funded by DARPA. In particular, we motivate and present an innovative integrated traffic-engineering framework for re-configurable IP/WDM networks. It builds on the strength of Multi-Protocol Label Switching (MPLS) for fine-grain IP load balancing, and on the strength of Re-configurable WDM networking for reducing the IP network's weighted-hop-distance, and for expanding the bottleneck bandwidth.},
keywords={},
doi={},
ISSN={},
month={October},}
부
TY - JOUR
TI - Network Control and Management for the Next Generation Internet
T2 - IEICE TRANSACTIONS on Communications
SP - 2191
EP - 2209
AU - John Y. WEI
AU - Chang-Dong LIU
AU - Sung-Yong PARK
AU - Kevin H. LIU
AU - Ramu S. RAMAMURTHY
AU - Hyogon KIM
AU - Mari W. MAEDA
PY - 2000
DO -
JO - IEICE TRANSACTIONS on Communications
SN -
VL - E83-B
IS - 10
JA - IEICE TRANSACTIONS on Communications
Y1 - October 2000
AB - The Next Generation Internet Initiative was launched in the U.S. to advance key networking technologies that will enable a new wave of applications on the Internet. Now, in its third year, the program has launched and fostered over one hundred new research projects in partnership with academic, industrial and government laboratories. One key research area that has been emphasized within the program is the next-generation optical networking. Given the ever increasing demand for network bandwidth, and the recent phenomenal advances in WDM technologies, the Next Generation Internet is expected to be an IP-based optical WDM network. As IP over WDM networking technologies mature, a number of important architectural, management and control issues have surfaced. These issues need to be addressed before a true Next Generation Optical Internet can emerge. This paper provides a brief introduction to the overall goals and activities of DARPA's NGI program and describes the key architectural, management, and control issues for the Optical Internet. We review the different IP/WDM networking architectural models and their tradeoffs. We outline and discuss several management and control issues and possible solutions related to the configuration, fault, and performance management of IP over dynamic WDM networks. We present an analysis and supporting simulation results demonstrating the potential benefits of dynamic IP over WDM networks. We then discuss the issues related to IP/WDM traffic engineering in more detail, and present the approach taken in the NGI SuperNet Network Control and Management Project funded by DARPA. In particular, we motivate and present an innovative integrated traffic-engineering framework for re-configurable IP/WDM networks. It builds on the strength of Multi-Protocol Label Switching (MPLS) for fine-grain IP load balancing, and on the strength of Re-configurable WDM networking for reducing the IP network's weighted-hop-distance, and for expanding the bottleneck bandwidth.
ER -