ENHANCING THE PERFORMANCE AND SECURITY OF ANONYMOUS COMMUNICATION NETWORKS
الملخص
With the increasing importance of the Internet in our daily lives, the private information
of millions of users is prone to more security risks. Users data are collected
either for commercial purposes and sold by service providers to marketeers or political
purposes and used to track people by governments, or even for personal purposes by
hackers. Protecting online users privacy has become a more pressing matter over the
years. To this end, anonymous communication networks were developed to serve this
purpose.
Tors anonymity network is one of the most widely used anonymity networks online; it
consists of thousands of routers run by volunteers. Tor preserves the anonymity of its
users by relaying the traffic through a number of routers (called onion routers) forming
a circuit. Tor was mainly developed as a low-latency network to support interactive
applications such as web browsing and messaging applications. However, due to some
deficiencies in the original design of Tors network, the performance is affected to the
point that interactive applications cannot tolerate it. In this thesis, we attempt to address
a number of the performance-limiting issues in Tor networks design.
Several researches proposed changes in the transport design to eliminate the effect of these problems and improve the performance of Tors network. In our work, we propose
"QuicTor," an improvement to the transport layer of Tors network by using Googles
protocol "QUIC" instead of TCP. QUIC was mainly developed to eliminate TCPs latency
introduced from the handshaking delays and the head-of-line blocking problem.
We provide an empirical evaluation of our proposed design and compare it to two other
proposed designs, IMUX and PCTCP.We show that QuicTor significantly enhances the
performance of Tors network.
Tor was mainly developed as a low-latency network to support interactive web browsing
and messaging applications. However, a considerable percentage of Tor traffic
is consumed by bandwidth acquisitive applications such as BitTorrent. This results
in an unfair allocation of the available bandwidth and significant degradation in the
Quality-of-service (QoS) delivered to users. In this thesis, we present a QoS-aware deep
reinforcement learning approach for Tors circuit scheduling (QDRL). We propose a
design that coalesces the two scheduling levels originally presented in Tor and addresses
it as a single resource allocation problem. We use the QoS requirements of different
applications to set the weight of active circuits passing through a relay. Furthermore,
we propose a set of approaches to achieve the optimal trade-off between system fairness
and efficiency. We designed and implemented a reinforcement-learning-based scheduling
approach (TRLS), a convex-optimization-based scheduling approach (CVX-OPT),
and an average-rate-based proportionally fair heuristic (AR-PF). We also compared the
proposed approaches with basic heuristics and with the implemented scheduler in Tor.
We show that our reinforcement-learning-based approach (TRLS) achieved the highest QoS-aware fairness level with a resilient performance to the changes in an environment
with a dynamic nature, such as the Tor network
DOI/handle
http://hdl.handle.net/10576/26364المجموعات
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