Ao Tang scite author profile

The problem of distributed learning and channel access is considered in a cognitive network with multiple secondary users. The availability statistics of the channels are initially unknown to the secondary users and are estimated using sensing decisions. There is no explicit information exchange or prior agreement among the secondary users. We propose policies for distributed learning and access which achieve order-optimal cognitive system throughput (number of successful secondary transmissions) under self play, i.e., when implemented at all the secondary users. Equivalently, our policies minimize the regret in distributed learning and access. We first consider the scenario when the number of secondary users is known to the policy, and prove that the total regret is logarithmic in the number of transmission slots. Our distributed learning and access policy achieves order-optimal regret by comparing to an asymptotic lower bound for regret under any uniformly-good learning and access policy. We then consider the case when the number of secondary users is fixed but unknown, and is estimated through feedback. We propose a policy in this scenario whose asymptotic sum regret which grows slightly faster than logarithmic in the number of transmission slots.Index Terms-Cognitive medium access control, multi-armed bandits, distributed algorithms, logarithmic regret. † Corresponding author.A. Anandkumar is with the

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Dynamic modelling of the effects of ion diffusion and side reactions on the capacity loss for vanadium redox flow battery

Tang

Bao

Skyllas‐Kazacos

2011

Journal of Power Sources

324

225

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Studies on pressure losses and flow rate optimization in vanadium redox flow battery

Tang

Bao

Skyllas‐Kazacos

2014

Journal of Power Sources

340

202

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Power-Aware Speed Scaling in Processor Sharing Systems

2009

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Abstract-Energy use of computer communication systems has quickly become a vital design consideration. One effective method for reducing energy consumption is dynamic speed scaling, which adapts the processing speed to the current load. This paper studies how to optimally scale speed to balance mean response time and mean energy consumption under processor sharing scheduling. Both bounds and asymptotics for the optimal speed scaling scheme are provided. These results show that a simple scheme that halts when the system is idle and uses a static rate while the system is busy provides nearly the same performance as the optimal dynamic speed scaling. However, the results also highlight that dynamic speed scaling provides at least one key benefit -significantly improved robustness to bursty traffic and mis-estimation of workload parameters.

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Opportunistic Spectrum Access with Multiple Users: Learning under Competition

2010

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The problem of cooperative allocation among multiple secondary users to maximize cognitive system throughput is considered. The channel availability statistics are initially unknown to the secondary users and are learnt via sensing samples. Two distributed learning and allocation schemes which maximize the cognitive system throughput or equivalently minimize the total regret in distributed learning and allocation are proposed. The first scheme assumes minimal prior information in terms of pre-allocated ranks for secondary users while the second scheme is fully distributed and assumes no such prior information. The two schemes have sum regret which is provably logarithmic in the number of sensing time slots. A lower bound is derived for any learning scheme which is asymptotically logarithmic in the number of slots. Hence, our schemes achieve asymptotic order optimality in terms of regret in distributed learning and allocation.

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Compressive sensing over graphs

Mallada

Tang

2011

110

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Abstract-In this paper, motivated by network inference and tomography applications, we study the problem of compressive sensing for sparse signal vectors over graphs. In particular, we are interested in recovering sparse vectors representing the properties of the edges from a graph. Unlike existing compressive sensing results, the collective additive measurements we are allowed to take must follow connected paths over the underlying graph. For a sufficiently connected graph with n nodes, it is shown that, using O(k log(n)) path measurements, we are able to recover any k-sparse link vector (with no more than k nonzero elements), even though the measurements have to follow the graph path constraints. We mainly show that the computationally efficient 1 minimization can provide theoretical guarantees for inferring such k-sparse vectors with O(k log(n)) path measurements from the graph.

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Thermal modelling of battery configuration and self-discharge reactions in vanadium redox flow battery

Tang

Bao

Skyllas‐Kazacos

2012

Journal of Power Sources

162

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Thermal modelling and simulation of the all-vanadium redox flow battery

Tang

Ting

Bao

et al. 2012

Journal of Power Sources

143

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Ao Tang

Distributed Algorithms for Learning and Cognitive Medium Access with Logarithmic Regret

Dynamic modelling of the effects of ion diffusion and side reactions on the capacity loss for vanadium redox flow battery

Studies on pressure losses and flow rate optimization in vanadium redox flow battery

Power-Aware Speed Scaling in Processor Sharing Systems

Opportunistic Spectrum Access with Multiple Users: Learning under Competition

Compressive sensing over graphs

Thermal modelling of battery configuration and self-discharge reactions in vanadium redox flow battery

Thermal modelling and simulation of the all-vanadium redox flow battery

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