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 Home &nbsp; &nbsp;/</a></li><li class="active list-inline-item">Highlights</li></ol></div></div></div></div></section><section id=blog-full-width><div class=container><div class=row><div class=col-md-12><article class="wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms><div class=blog-post-image><a href=https://qnlab-ustc.com/highlights/simqn/><img class=img-fluid src=https://qnlab-ustc.com/images/simqn-modules.png alt=post-image></a></div><div class=blog-content><h2 class=blogpost-title><a href=https://qnlab-ustc.com/highlights/simqn/>SimQN: a Network-layer Simulator for the Quantum Network Investigation</a></h2><div class=blog-meta><span>6 December 2022</span></div><p></p><a href=https://qnlab-ustc.com/highlights/simqn/ class="btn btn-dafault btn-details hvr-bounce-to-right">Continue
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 Reading</a></div></article><article class="wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms><div class=blog-post-image><a href=https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/><img class=img-fluid src=https://qnlab-ustc.com/images/IEEE-Commu-Surveys.png alt=post-image></a></div><div class=blog-content><h2 class=blogpost-title><a href=https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</a></h2><div class=blog-meta><span>6 January 0001</span></div><p>Quantum applications offer significant advantages over their classical counterparts primarily due to the fundamental principles of quantum mechanics, especially quantum entanglement. To harness the full potential and broaden the scope of quantum applications, it becomes imperative to establish entanglement-assisted quantum networks by connecting multiple quantum nodes through physical channels. Quantum networks have shown promise in terms of improving the overall functional benefits of the Internet and enabling applications with no counterpart in the classical world, which is a breakthrough technology towards the unimaginable future.</p><a href=https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/ class="btn btn-dafault btn-details hvr-bounce-to-right">Continue
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+Reading</a></div></article><article class="wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms><div class=blog-post-image><a href=https://qnlab-ustc.com/highlights/redp-jsac/><img class=img-fluid src=https://qnlab-ustc.com/images/Chen-JSAC.png alt=post-image></a></div><div class=blog-content><h2 class=blogpost-title><a href=https://qnlab-ustc.com/highlights/redp-jsac/>REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks</a></h2><div class=blog-meta><span>6 January 0001</span></div><p>Remote entanglement distribution in an efficient and reliable manner, especially in the context of a largescale quantum network with multiple requests, remains an unsolved challenge. The key difficulties lie in achieving spontaneous and precise control over the entanglement distribution procedure, as multiple nodes need to reach a consensus on how to perform it. From the network aspect, allocating link-layer entangled pairs as resources to achieve high efficiency is also challenging. To address these issues, we propose a decentralized Reliable Entanglement Distribution Protocol (REDP) for large-scale networks.</p><a href=https://qnlab-ustc.com/highlights/redp-jsac/ class="btn btn-dafault btn-details hvr-bounce-to-right">Continue
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 <link rel=icon href=https://qnlab-ustc.com/images/favicon.ico><link rel=stylesheet href=https://qnlab-ustc.com/plugins/bootstrap/bootstrap.min.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/ionicons/ionicons.min.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/animate-css/animate.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/slider/slider.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/slick/slick.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/facncybox/jquery.fancybox.css><link rel=stylesheet href=https://qnlab-ustc.com/plugins/hover/hover-min.css><link rel=stylesheet href=https://qnlab-ustc.com/css/style.min.css media=screen><link rel=stylesheet href=https://qnlab-ustc.com/css/custom.min.css media=screen></head><body><section class="top-bar animated-header"><div class=container><div class=row><div class=col-lg-12><nav class="navbar navbar-expand-lg navbar-light bg-light"><a class=navbar-brand href=https://qnlab-ustc.com/><h4>Research Group of Quantum Network, USTC</h4></a><button class=navbar-toggler type=button data-toggle=collapse data-target=#navigation aria-controls=navigation aria-expanded=false aria-label="Toggle navigation">
-<span class=navbar-toggler-icon></span></button><div class="collapse navbar-collapse" id=navigation><ul class="navbar-nav ml-auto"><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/>Home</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/publication>Publication</a></li><li class="nav-item dropdown"><a class="nav-link dropdown-toggle" href=# role=button data-toggle=dropdown aria-haspopup=true aria-expanded=false>Projects</a><div class=dropdown-menu><a class=dropdown-item href=https://qnlab-ustc.com/projects/simqn>SimQN</a></div></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/news/>News</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/team>Our Team</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/about>About Us</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/zh>中文</a></li></ul></div></nav></div></div></div></section><section class=global-page-header><div class=container><div class=row><div class=col-md-12><div class=block><h2>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</h2><div class=portfolio-meta><span>6 January 0001</span>|
-<span>Tags:</span></div></div></div></div></div></section><section class=single-post><div class=container><div class=row><div class=col-md-12><div class=post-img><img class=img-fluid alt src=https://qnlab-ustc.com/images/Chen-JSAC.png></div><div class=post-content><p>Quantum applications offer significant advantages over their classical counterparts primarily due to the fundamental principles of quantum mechanics, especially quantum entanglement. To harness the full potential and broaden the scope of quantum applications, it becomes imperative to establish entanglement-assisted quantum networks by connecting multiple quantum nodes through physical channels. Quantum networks have shown promise in terms of improving the overall functional benefits of the Internet and enabling applications with no counterpart in the classical world, which is a breakthrough technology towards the unimaginable future. However, entanglement-assisted quantum networks differ fundamentally from classical networks, encompassing various aspects including physical resources and top-level applications. Therefore, it is crucial to undertake fundamental yet essential endeavors in order to pave the way for building entanglement-assisted quantum networks.</p><p>The paper titled “Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions” by Zhonghui Li, Kaiping Xue, Jian Li, Lutong Chen, Ruidong Li, Zhaoying Wang, Nenghai Yu, David S.L. Wei, Qibin Sun, and Jun Lu serves a survey and tutorial in this field. It begins by offering an introduction to quantum mechanics and entanglement-based enabling technologies involved. Subsequently, the paper delves into the subject of entanglement-assisted quantum networks, covering aspects such as development stages, network elements, working principles, and so on. Additionally, the paper presents some challenges to build entanglement-assisted quantum networks. Lastly, the paper concludes by outlining a several research directions pertaining to network design.</p></div></div></div></div></section><section id=call-to-action><div class=container><div class=row><div class=col-md-12><div class=block><h2 class="title wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms>Welcome to contact us</h1><p class="wow fadeInDown" data-wow-delay=.5s data-wow-duration=500ms>We would be gald to hear your comments and suggestions. Click the following button to email us.</p><a href=mailto:kpxue@ustc.edu.cn class="btn btn-default btn-contact wow fadeInDown" data-wow-delay=.7s data-wow-duration=500ms>Contact Us</a></div></div></div></div></section><footer id=footer><div class=container><div class="row content-justify-between"><div class="col-md-8 col-12 text-center text-lg-left text-md-left"><p>Copyright 2018 - 2023 Infonet@USTC. All Rights Reserved.</p><p class=copyright>Theme Copyright:
+<span class=navbar-toggler-icon></span></button><div class="collapse navbar-collapse" id=navigation><ul class="navbar-nav ml-auto"><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/>Home</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/publication>Publication</a></li><li class="nav-item dropdown"><a class="nav-link dropdown-toggle" href=# role=button data-toggle=dropdown aria-haspopup=true aria-expanded=false>Projects</a><div class=dropdown-menu><a class=dropdown-item href=https://qnlab-ustc.com/projects/simqn>SimQN</a></div></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/news/>News</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/team>Our Team</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/about>About Us</a></li><li class=nav-item><a class=nav-link href=https://qnlab-ustc.com/zh>中文</a></li></ul></div></nav></div></div></div></section><section class=global-page-header><div class=container><div class=row><div class=col-md-12><div class=block><h2>REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks</h2><div class=portfolio-meta><span>6 January 0001</span>|
+<span>Tags:</span></div></div></div></div></div></section><section class=single-post><div class=container><div class=row><div class=col-md-12><div class=post-img><img class=img-fluid alt src=https://qnlab-ustc.com/images/Chen-JSAC.png></div><div class=post-content><p>Remote entanglement distribution in an efficient and reliable manner, especially in the context of a largescale quantum network with multiple requests, remains an unsolved challenge. The key difficulties lie in achieving spontaneous and precise control over the entanglement distribution procedure, as multiple nodes need to reach a consensus on how to perform it. From the network aspect, allocating link-layer entangled pairs as resources to achieve high efficiency is also challenging. To address these issues, we propose a decentralized Reliable Entanglement Distribution Protocol (REDP) for large-scale networks. The protocol operates in a Forward-Backward Propagation (FBP) manner, where consensus is reached hop-by-hop and disseminated to all nodes on the path. We further use probabilistic analysis and quasi-static modeling to seek the fairness and efficiency of the network based on the above transmission model. Accordingly, we introduce a Source Window Strategy (SWS) and an Entanglement Allocation Strategy (EAS) to assign sending windows and allocate resources for multiple requests, ensuring a high level of fairness and efficiency from a network perspective. Through systematic simulations involving both classical and quantum communication protocols, we demonstrate that REDP outperforms existing approaches in terms of fairness, throughput, and fidelity performance.</p></div></div></div></div></section><section id=call-to-action><div class=container><div class=row><div class=col-md-12><div class=block><h2 class="title wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms>Welcome to contact us</h1><p class="wow fadeInDown" data-wow-delay=.5s data-wow-duration=500ms>We would be gald to hear your comments and suggestions. Click the following button to email us.</p><a href=mailto:kpxue@ustc.edu.cn class="btn btn-default btn-contact wow fadeInDown" data-wow-delay=.7s data-wow-duration=500ms>Contact Us</a></div></div></div></div></section><footer id=footer><div class=container><div class="row content-justify-between"><div class="col-md-8 col-12 text-center text-lg-left text-md-left"><p>Copyright 2018 - 2023 Infonet@USTC. All Rights Reserved.</p><p class=copyright>Theme Copyright:
 <span>2022 (c)
 </span>design and developed by
 <a href=http://www.Themefisher.com target=_blank>Themefisher</a>
diff --git a/index.html b/index.html
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 <a href=https://qnlab-ustc.com/highlights/simqn/>Details</a></div></div></div><figcaption><h4><a href=https://qnlab-ustc.com/highlights/simqn/>SimQN: a Network-layer Simulator for the Quantum Network Investigation</a></h4><p></p></figcaption></figure></div><div class="col-md-6 col-sm-6"><figure class="wow fadeInLeft animated portfolio-item" data-wow-duration=500ms data-wow-delay=300ms><div class=img-wrapper><img src=/images/china-communications.png class=img-fluid alt="this is a title"><div class=overlay><div class=buttons><a rel=gallery class=fancybox href=/images/china-communications.png>Image</a>
 <a href=https://qnlab-ustc.com/highlights/china-communication/>Details</a></div></div></div><figcaption><h4><a href=https://qnlab-ustc.com/highlights/china-communication/>Building a Large-Scale and Wide-Area Quantum Internet Based on an OSI-Alike Model</a></h4><p></p></figcaption></figure></div><div class="col-md-6 col-sm-6"><figure class="wow fadeInLeft animated portfolio-item" data-wow-duration=500ms data-wow-delay=600ms><div class=img-wrapper><img src=/images/IEEE-Commu-Surveys.png class=img-fluid alt="this is a title"><div class=overlay><div class=buttons><a rel=gallery class=fancybox href=/images/IEEE-Commu-Surveys.png>Image</a>
 <a href=https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/>Details</a></div></div></div><figcaption><h4><a href=https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</a></h4><p></p></figcaption></figure></div><div class="col-md-6 col-sm-6"><figure class="wow fadeInLeft animated portfolio-item" data-wow-duration=500ms data-wow-delay=900ms><div class=img-wrapper><img src=/images/Chen-JSAC.png class=img-fluid alt="this is a title"><div class=overlay><div class=buttons><a rel=gallery class=fancybox href=/images/Chen-JSAC.png>Image</a>
-<a href=https://qnlab-ustc.com/highlights/redp-jsac/>Details</a></div></div></div><figcaption><h4><a href=https://qnlab-ustc.com/highlights/redp-jsac/>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</a></h4><p></p></figcaption></figure></div></div></div></section><section id=call-to-action><div class=container><div class=row><div class=col-md-12><div class=block><h2 class="title wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms>Welcome to contact us</h1><p class="wow fadeInDown" data-wow-delay=.5s data-wow-duration=500ms>We would be gald to hear your comments and suggestions. Click the following button to email us.</p><a href=mailto:kpxue@ustc.edu.cn class="btn btn-default btn-contact wow fadeInDown" data-wow-delay=.7s data-wow-duration=500ms>Contact Us</a></div></div></div></div></section><footer id=footer><div class=container><div class="row content-justify-between"><div class="col-md-8 col-12 text-center text-lg-left text-md-left"><p>Copyright 2018 - 2023 Infonet@USTC. All Rights Reserved.</p><p class=copyright>Theme Copyright:
+<a href=https://qnlab-ustc.com/highlights/redp-jsac/>Details</a></div></div></div><figcaption><h4><a href=https://qnlab-ustc.com/highlights/redp-jsac/>REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks</a></h4><p></p></figcaption></figure></div></div></div></section><section id=call-to-action><div class=container><div class=row><div class=col-md-12><div class=block><h2 class="title wow fadeInDown" data-wow-delay=.3s data-wow-duration=500ms>Welcome to contact us</h1><p class="wow fadeInDown" data-wow-delay=.5s data-wow-duration=500ms>We would be gald to hear your comments and suggestions. Click the following button to email us.</p><a href=mailto:kpxue@ustc.edu.cn class="btn btn-default btn-contact wow fadeInDown" data-wow-delay=.7s data-wow-duration=500ms>Contact Us</a></div></div></div></div></section><footer id=footer><div class=container><div class="row content-justify-between"><div class="col-md-8 col-12 text-center text-lg-left text-md-left"><p>Copyright 2018 - 2023 Infonet@USTC. All Rights Reserved.</p><p class=copyright>Theme Copyright:
 <span>2022 (c)
 </span>design and developed by
 <a href=http://www.Themefisher.com target=_blank>Themefisher</a>
diff --git a/index.xml b/index.xml
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 <?xml version="1.0" encoding="utf-8" standalone="yes"?><rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom"><channel><title>Research Group of Quantum Network, USTC</title><link>https://qnlab-ustc.com/</link><description>Recent content on Research Group of Quantum Network, USTC</description><generator>Hugo -- gohugo.io</generator><language>en</language><lastBuildDate>Mon, 19 Dec 2022 11:39:58 +0800</lastBuildDate><atom:link href="https://qnlab-ustc.com/index.xml" rel="self" type="application/rss+xml"/><item><title>SimQN: a Network-layer Simulator for the Quantum Network Investigation</title><link>https://qnlab-ustc.com/highlights/simqn/</link><pubDate>Mon, 19 Dec 2022 11:39:58 +0800</pubDate><guid>https://qnlab-ustc.com/highlights/simqn/</guid><description/></item><item><title>SimQN: a Network-layer Simulator for the Quantum Network Investigation</title><link>https://qnlab-ustc.com/projects/simqn/</link><pubDate>Fri, 16 Dec 2022 13:40:06 +0800</pubDate><guid>https://qnlab-ustc.com/projects/simqn/</guid><description>Welcome to SimQN&amp;rsquo;s documentation. SimQN is a discrete-event based network simulation platform for quantum networks. SimQN enables large-scale investigations, including QKD protocols, entanglement distributions protocols, and routing algorithms, resource allocation schemas in quantum networks. For example, users can use SimQN to design routing algorithms for better QKD performance. For more information, please refer to the Documents.
-SimQN is a Python3 library for quantum networking simulation. It is designed to be general propose.</description></item><item><title>About Us</title><link>https://qnlab-ustc.com/about/</link><pubDate>Fri, 16 Dec 2022 13:27:40 +0800</pubDate><guid>https://qnlab-ustc.com/about/</guid><description>To the future of quantum era Nowadays, we are on the cusp of a new age of technology that promises to revolutionize the way we compute, communicate, and secure information. Quantum mechanics, which describes the behavior of particles at the subatomic level, has long been recognized as a powerful tool for information processing. The advancements of quantum mechanics have the potential to solve problems that were previously impossible to solve with classical networks and computers, to provide unprecedented levels of security for our communications, and to create entirely new industries and fields of study.</description></item><item><title>Building a Large-Scale and Wide-Area Quantum Internet Based on an OSI-Alike Model</title><link>https://qnlab-ustc.com/highlights/china-communication/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/china-communication/</guid><description>The theory and experiment of quantum information have been studied extensively in recent years, and the feasibility of quantum communication has been proved. Although the fundamental technology is not yet mature, research on quantum internet should be conducted. To implement quantum internet, an architecture that describes how quantum nodes are linked to form networks and how protocol functions are vertically composed need to be developed urgently. In this paper, we present a novel design of a cluster-based structure to describe how quantum nodes are interconnected, and how the structure can improve the performance of qubit transmission and reduce the network complexity.</description></item><item><title>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</title><link>https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/</guid><description>Quantum applications offer significant advantages over their classical counterparts primarily due to the fundamental principles of quantum mechanics, especially quantum entanglement. To harness the full potential and broaden the scope of quantum applications, it becomes imperative to establish entanglement-assisted quantum networks by connecting multiple quantum nodes through physical channels. Quantum networks have shown promise in terms of improving the overall functional benefits of the Internet and enabling applications with no counterpart in the classical world, which is a breakthrough technology towards the unimaginable future.</description></item><item><title>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</title><link>https://qnlab-ustc.com/highlights/redp-jsac/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/redp-jsac/</guid><description>Quantum applications offer significant advantages over their classical counterparts primarily due to the fundamental principles of quantum mechanics, especially quantum entanglement. To harness the full potential and broaden the scope of quantum applications, it becomes imperative to establish entanglement-assisted quantum networks by connecting multiple quantum nodes through physical channels. Quantum networks have shown promise in terms of improving the overall functional benefits of the Internet and enabling applications with no counterpart in the classical world, which is a breakthrough technology towards the unimaginable future.</description></item><item><title>News</title><link>https://qnlab-ustc.com/news/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/news/</guid><description>2023.12, our paper &amp;ldquo;REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks&amp;rdquo; is accepted by IEEE Journal on Seclected Areas in Communications!
+SimQN is a Python3 library for quantum networking simulation. It is designed to be general propose.</description></item><item><title>About Us</title><link>https://qnlab-ustc.com/about/</link><pubDate>Fri, 16 Dec 2022 13:27:40 +0800</pubDate><guid>https://qnlab-ustc.com/about/</guid><description>To the future of quantum era Nowadays, we are on the cusp of a new age of technology that promises to revolutionize the way we compute, communicate, and secure information. Quantum mechanics, which describes the behavior of particles at the subatomic level, has long been recognized as a powerful tool for information processing. The advancements of quantum mechanics have the potential to solve problems that were previously impossible to solve with classical networks and computers, to provide unprecedented levels of security for our communications, and to create entirely new industries and fields of study.</description></item><item><title>Building a Large-Scale and Wide-Area Quantum Internet Based on an OSI-Alike Model</title><link>https://qnlab-ustc.com/highlights/china-communication/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/china-communication/</guid><description>The theory and experiment of quantum information have been studied extensively in recent years, and the feasibility of quantum communication has been proved. Although the fundamental technology is not yet mature, research on quantum internet should be conducted. To implement quantum internet, an architecture that describes how quantum nodes are linked to form networks and how protocol functions are vertically composed need to be developed urgently. In this paper, we present a novel design of a cluster-based structure to describe how quantum nodes are interconnected, and how the structure can improve the performance of qubit transmission and reduce the network complexity.</description></item><item><title>Entanglement-Assisted Quantum Networks: Mechanics, Enabling Technologies, Challenges, and Research Directions</title><link>https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/ieee_commu_sur_tur/</guid><description>Quantum applications offer significant advantages over their classical counterparts primarily due to the fundamental principles of quantum mechanics, especially quantum entanglement. To harness the full potential and broaden the scope of quantum applications, it becomes imperative to establish entanglement-assisted quantum networks by connecting multiple quantum nodes through physical channels. Quantum networks have shown promise in terms of improving the overall functional benefits of the Internet and enabling applications with no counterpart in the classical world, which is a breakthrough technology towards the unimaginable future.</description></item><item><title>News</title><link>https://qnlab-ustc.com/news/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/news/</guid><description>2023.12, our paper &amp;ldquo;REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks&amp;rdquo; is accepted by IEEE Journal on Seclected Areas in Communications!
 2023.11, our paper &amp;ldquo;Security-Enhanced WireGuard Protocol Design using Quantum Key Distribution&amp;rdquo; is accepted by the International Conference on Computing, Networking and Communications (ICNC 2024)!
 2023.09, our paper &amp;ldquo;A Connectionless Entanglement Distribution Protocol Design in Quantum Networks&amp;rdquo; is accepted by IEEE Network!
 2023.09, Welcome two master students Jiaqi Wu and Xumin Gao to join our group!</description></item><item><title>Our Team</title><link>https://qnlab-ustc.com/team/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/team/</guid><description>Scientific Counselor Jun Lu Professor
@@ -22,4 +22,4 @@ Puli Li E-mail
 Peng Zheng E-mail
 Zirui Xiao E-mail</description></item><item><title>Publications</title><link>https://qnlab-ustc.com/publication/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/publication/</guid><description>Preprints arXiv
 2023 REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks Lutong Chen, Kaiping Xue*, Jian Li, Zhonghui Li, Ruidong Li, Nenghai Yu, Qibin Sun, Jun Lu IEEE Journal on Selected Areas in Communications, Early Accept. [Online] - [PDF]
-Security-Enhanced WireGuard Protocol Design using Quantum Key Distribution Lutong Chen, Kaiping Xue*, Jian Li, Zhonghui Li, Nenghai Yu International Conference on Computing, Networking and Communications (ICNC 2024), Early Accept. [Online] - [PDF]</description></item></channel></rss>
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+Security-Enhanced WireGuard Protocol Design using Quantum Key Distribution Lutong Chen, Kaiping Xue*, Jian Li, Zhonghui Li, Nenghai Yu International Conference on Computing, Networking and Communications (ICNC 2024), Early Accept. [Online] - [PDF]</description></item><item><title>REDP: Reliable Entanglement Distribution Protocol Design for Large-scale Quantum Networks</title><link>https://qnlab-ustc.com/highlights/redp-jsac/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://qnlab-ustc.com/highlights/redp-jsac/</guid><description>Remote entanglement distribution in an efficient and reliable manner, especially in the context of a largescale quantum network with multiple requests, remains an unsolved challenge. The key difficulties lie in achieving spontaneous and precise control over the entanglement distribution procedure, as multiple nodes need to reach a consensus on how to perform it. From the network aspect, allocating link-layer entangled pairs as resources to achieve high efficiency is also challenging. To address these issues, we propose a decentralized Reliable Entanglement Distribution Protocol (REDP) for large-scale networks.</description></item></channel></rss>
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