A. James Clark School of Engineering

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The collections in this community comprise faculty research works, as well as graduate theses and dissertations.

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    Precoder Detection for Cooperative Decode-and-Forward Relaying in OFDMA Systems
    (2016) Valluri, Abhijit Kiran; La, Richard J; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    We consider an LTE network where a secondary user acts as a relay, transmitting data to the primary user using a decode-and-forward mechanism, transparent to the base-station (eNodeB). Clearly, the relay can decode symbols more reliably if the employed precoder matrix indicators (PMIs) are known. However, for closed loop spatial multiplexing (CLSM) transmit mode, this information is not always embedded in the downlink signal, leading to a need for effective methods to determine the PMI. In this thesis, we consider 2x2 MIMO and 4x4 MIMO downlink channels corresponding to CLSM and formulate two techniques to estimate the PMI at the relay using a hypothesis testing framework. We evaluate their performance via simulations for various ITU channel models over a range of SNR and for different channel quality indicators (CQIs). We compare them to the case when the true PMI is known at the relay and show that the performance of the proposed schemes are within 2 dB at 10% block error rate (BLER) in almost all scenarios. Furthermore, the techniques add minimal computational overhead over existent receiver structure. Finally, we also identify scenarios when using the proposed precoder detection algorithms in conjunction with the cooperative decode-and-forward relaying mechanism benefits the PUE and improves the BLER performance for the PUE. Therefore, we conclude from this that the proposed algorithms as well as the cooperative relaying mechanism at the CMR can be gainfully employed in a variety of real-life scenarios in LTE networks.
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    Dynamic Resource Allocation in Wireless Heterogeneous Networks
    (2015) Singh, Vaibhav; Shayman, Prof. Mark; La, Prof. Richard; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Deployment of low power basestations within cellular networks can potentially increase both capacity and coverage. However, such deployments require efficient resource allocation schemes for managing interference from the low power and macro basestations that are located within each other’s transmission range. In this dissertation, we propose novel and efficient dynamic resource allocation algorithms in the frequency, time and space domains. We show that the proposed algorithms perform better than the current state-of-art resource management algorithms. In the first part of the dissertation, we propose an interference management solution in the frequency domain. We introduce a distributed frequency allocation scheme that shares frequencies between macro and low power pico basestations, and guarantees a minimum average throughput to users. The scheme seeks to minimize the total number of frequencies needed to honor the minimum throughput requirements. We evaluate our scheme using detailed simulations and show that it performs on par with the centralized optimum allocation. Moreover, our proposed scheme outperforms a static frequency reuse scheme and the centralized optimal partitioning between the macro and picos. In the second part of the dissertation, we propose a time domain solution to the interference problem. We consider the problem of maximizing the alpha-fairness utility over heterogeneous wireless networks (HetNets) by jointly optimizing user association, wherein each user is associated to any one transmission point (TP) in the network, and activation fractions of all TPs. Activation fraction of a TP is the fraction of the frame duration for which it is active, and together these fractions influence the interference seen in the network. To address this joint optimization problem which we show is NP-hard, we propose an alternating optimization based approach wherein the activation fractions and the user association are optimized in an alternating manner. The subproblem of determining the optimal activation fractions is solved using a provably convergent auxiliary function method. On the other hand, the subproblem of determining the user association is solved via a simple combinatorial algorithm. Meaningful performance guarantees are derived in either case. Simulation results over a practical HetNet topology reveal the superior performance of the proposed algorithms and underscore the significant benefits of the joint optimization. In the final part of the dissertation, we propose a space domain solution to the interference problem. We consider the problem of maximizing system utility by optimizing over the set of user and TP pairs in each subframe, where each user can be served by multiple TPs. To address this optimization problem which is NP-hard, we propose a solution scheme based on difference of submodular function optimization approach. We evaluate our scheme using detailed simulations and show that it performs on par with a much more computationally demanding difference of convex function optimization scheme. Moreover, the proposed scheme performs within a reasonable percentage of the optimal solution. We further demonstrate the advantage of the proposed scheme by studying its performance with variation in different network topology parameters.
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    Radio Resource Management in Heterogeneous Cellular Networks
    (2014) Sung, Doohyun; Baras, John S.; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Heterogeneous cellular networks (HetNets) have been considered as one of enabling technologies not only to increase the cell coverage and capacity, but to improve the user experience. In this dissertation, we address two research challenges in HetNets: one is the cross-tier interference problem where cell range expansion (CRE) is applied for user offloading in cell association so that pico mobile stations located in expanded range (ER-PMSs), which are connected to macrocells unless CRE is enabled, are severely interfered. The other is the load-aware cell association which tries to overcome the drawback of the received signal strength-based cell association including CRE, i.e., the degradation of network performance by user load imbalance. In the first part, we present the frequency-domain transmit power reduction scheme for the cross-tier interference mitigation. Inspired by the fact that a macrocell accommodates more users than its underlaid picocells, we focus on minimizing the macrocell's performance degradation while improving the throughput of ER-PMSs by the transmit power reduction. Due to the discreteness of frequency resource block scheduling, we also propose a greedy-based heuristic algorithm to solve the binary integer programming problem. In the following part, we present a different approach for the cross-tier interference mitigation, which is the time-domain transmit power nulling scheme utilizing the almost blank subframes (ABSs) in 3GPP standards. We turn our attention to a network-wide performance enhancement through configuring a certain number of ABSs while improving the performance of ER-PMSs as in the first part. A new scheduling policy for pico mobile stations is proposed and the optimal ER-PMS scheduling onto ABSs/non-ABSs is solved by decomposing the problem into multiple independent problems for pico base stations. In the last part, we study the load-aware cell association problem. Due to the combinatorial nature of the cell association problem and the cross-tier interference between macrocells and picocells, we propose an online heuristic algorithm where the cell association and the number of ABSs for cross-tier interference mitigation are jointly optimized. Through approximation of the required condition for load balancing and ABS control from the network-wide utility point of view, the proposed online algorithm not only requires simple feedback messages, but also be applicable to any state of cell association/ABSs in HetNets.