Characteristics analysis at prefix granularity: A case study in an IPv6 network

Li, Fuliang; Yang, Jiahai; Wang, Xingwei; Pan, Tian; An, Changqing; Wu, Jianping

doi:10.1016/j.jnca.2016.02.022

Cited by 7 publications

(6 citation statements)

References 54 publications

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“…CAIDA has shown that, from January 2014 to January 2015, the number of IPv6 ASes increased by 23% and the number of links between them increased by 29% [9]. Existing studies have addressed that IPv6-centric next generation networks are widely deployed and applied [10][11][12]. With the development of IPv6, applications such as video conference, IPTV, VoIP, and online games will become more and more prevalent in IPv6 networks, so keeping network availability as well as good performance is crucial.…”

Section: Introductionmentioning

confidence: 99%

A Case Study of IPv6 Network Performance: Packet Delay, Loss, and Reordering

Wang

Pan

et al. 2017

Mathematical Problems in Engineering

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Internet Protocol (IP) is used to identify and locate computers on the Internet. Currently, IPv4 still routes most Internet traffic. However, with the exhausting of IPv4 addresses, the transition to IPv6 is imminent, because, as the successor of IPv4, IPv6 can provide a larger available address space. Existing studies have addressed the notion that IPv6-centric next generation networks are widely deployed and applied. In order to gain a deep understanding of IPv6, this paper revisits several critical IPv6 performance metrics. Our extensive measurement shows that packet delay and loss rate of IPv6 are similar to IPv4 when the AS-level paths are roughly the same. Specifically, when the link utilization exceeds a threshold, for example, 0.83 in our study, variation of packet delay presents a similar pattern with the variation of link utilization. If packet delay of a path is large, packet-loss rate of that path is more likely to fluctuate. In addition, we conduct a first-ever analysis of packet reordering in IPv6 world. Few IPv6 probe packets are out-of-order and the reordering rate is 2.3 * 10 −6 , which is much lower than that of 0.79% in IPv4 world. Our analysis consolidates an experimental basis for operators and researchers of IPv6 networks.

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Section: Introductionmentioning

confidence: 99%

A Case Study of IPv6 Network Performance: Packet Delay, Loss, and Reordering

Wang

Pan

et al. 2017

Mathematical Problems in Engineering

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“…Plonka et al [54] analyze the temporal and spatial characteristics of active IPv6 addresses. Li et al [55] describe the distribution characteristics of Internet IPv6 prefixes. These works demonstrate how the IPv6 addresses are actually used thus objectively shows the security status of the IPv6 address space.…”

Section: Ipv6 Address Space Securitymentioning

confidence: 99%

Addressless: A new internet server model to prevent network scanning

et al. 2021

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Eliminating unnecessary exposure is a principle of server security. The huge IPv6 address space enhances security by making scanning infeasible, however, with recent advances of IPv6 scanning technologies, network scanning is again threatening server security. In this paper, we propose a new model named addressless server, which separates the server into an entrance module and a main service module, and assigns an IPv6 prefix instead of an IPv6 address to the main service module. The entrance module generates a legitimate IPv6 address under this prefix by encrypting the client address, so that the client can access the main server on a destination address that is different in each connection. In this way, the model provides isolation to the main server, prevents network scanning, and minimizes exposure. Moreover it provides a novel framework that supports flexible load balancing, high-availability, and other desirable features. The model is simple and does not require any modification to the client or the network. We implement a prototype and experiments show that our model can prevent the main server from being scanned at a slight performance cost.

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“…A lot of works have been proposed to tell us how people use the IPv6 address in the past few years. Plonka and Berger [31] describe the temporal and spatial characteristics of active IPv6 addresses, and Li et al [32] show us the prefix distribution of IPv6 Internet.…”

Section: B Ipv6 Address Securitymentioning

confidence: 99%

“…Considering that the attacker can only launch the attack through the Internet environment, the efficiency will be less than that of scanning the address space using Zmap [5]. We use Zmap's scanning efficiency (2 32 addresses in 45 minutes at most) for estimation, the total traversal time for the suffix space is T hours as (4)…”

Section: Prefix Length Considerationmentioning

confidence: 99%

Addressless: Enhancing IoT Server Security Using IPv6

et al. 2020

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Nowadays more and more IoT devices, including a large number of IoT servers, have been deployed on the Internet. The security of IoT servers has always been a challenge. In this paper, a new model named addressless IoT server is proposed, which allows people to use the large IPv6 address space to protect IoT server security. The server is allocated an IPv6 prefix instead of an address. When the authenticated client initiates communication, it uses an encryption mechanism to generate a specific destination address under the prefix. The server verifies the destination address when receiving the packet, and discards the packet if the verification fails. In this way, the model can prevent attackers from perceiving the server and launching scans or attacks, while remains compatible with the current Internet. The prototype is implemented and an extensive set of experiments are conducted in this paper. The results demonstrate that the model can better protect server security. INDEX TERMS IPv6, IPv6 address space, Internet of Things, network security, prefix delegation.

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Characteristics analysis at prefix granularity: A case study in an IPv6 network

Cited by 7 publications

References 54 publications

A Case Study of IPv6 Network Performance: Packet Delay, Loss, and Reordering

A Case Study of IPv6 Network Performance: Packet Delay, Loss, and Reordering

Addressless: A new internet server model to prevent network scanning

Addressless: Enhancing IoT Server Security Using IPv6

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