Spelling suggestions: "subject:"interference networks"" "subject:"lnterference networks""
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Capacity of interference networks : achievable regions and outer boundsSridharan, Sriram 28 October 2014 (has links)
In an interference network, multiple transmitters communicate with multiple receivers using the same communication channel. The capacity region of an interference network is defined as the set of data rates that can be simultaneously achieved by the users of the network. One of the most important example of an interference network is the wireless network, where the communication channel is the wireless channel. Wireless interference networks are known to be interference limited rather than noise limited since the interference power level at the receivers (caused by other user's transmissions) is much higher than the noise power level. Most wireless communication systems deployed today employ transmission strategies where the interfering signals are treated in the same manner as thermal noise. Such strategies are known to be suboptimal (in terms of achieving higher data rates), because the interfering signals generated by other transmitters have a structure to them that is very different from that of random thermal noise. Hence, there is a need to design transmission strategies that exploit this structure of the interfering signals to achieve higher data rates. However, determining optimal strategies for mitigating interference has been a long standing open problem. In fact, even for the simplest interference network with just two users, the capacity region is unknown. In this dissertation, we will investigate the capacity region of several models of interference channels. We will derive limits on achievable data rates and design effective transmission strategies that come close to achieving the limits. We will investigate two kinds of networks - "small" (usually characterized by two transmitters and two receivers) and "large" where the number of users is large. / text
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CSI Feedback and Power Control in Wireless NetworksKaramad, Ehsan 10 January 2014 (has links)
We investigate the effects of quantized channel state information (CSI) on the performance of
resource allocation algorithms in wireless networks. The thesis starts with a brief overview
of a specific type of quantizer, referred to as a conservative quantizer where we propose the
optimality and sufficiency conditions as well as practical methods to find such quantizers. We
apply this theory to the quantization of transmitter CSI in point-to-point Gaussian channels
and transmission under short-term power constraints. Next, we show that in a multiple-node
decode-and-forward (DF) cooperative network, the same structure for quantizer is close to op-
timal for the sum-rate objective function. Based on a proposed upper bound on the rate loss in
such scenarios, we also argue that the quantizer should assign uneven numbers of quantization
bits to different links in the network. The simulation results show that given a target rate loss
level, through quantization and bit allocation, there is, on average, 0.5−1 bits per link savings
in CSI feedback requirements compared to the uniform and equal bit allocation approaches.
Given the many benefits in non-uniform allocation of CSI rate in the network, we formulate a
generalized bit allocation scheme which is extensible to arbitrary classes of network resource
allocation problems.
In the last part of this thesis, we focus on power control in an interference network and then,
investigate the effects of CSI imperfections on the performance of power control algorithms.
First, we propose an iterative power control algorithm based on a fixed-point iteration and prove
its local convergence. Then, we show that for a centralized implementation of the power control
algorithm, a uniform in dB (geometric) quantizer of channel power is efficient. Based on this
choice of channel quantizer, we propose a bound on rate loss in terms of the resolution of the
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deployed quantizer, where a 3 dB in quantization error is shown to contribute to a maximum of
1 bit rate loss at each user. Similarly to the previous scenario, the upper bound suggests that an
uneven assignment of numbers of quantization levels leads to smaller distortion. Based on this
bound, we develop the corresponding bit allocation laws. We also investigate the effects of CSI
errors on the performance of distributed power control algorithms and show that, compared to
the centralized case, the distributed algorithm could lead to a further SINR loss of up to 3
dB for one or more transmitters. This error is due to the fact that because of CSI errors, the
estimated interference level at each receiver is different from the induced interference wireless
transmitters expect.
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CSI Feedback and Power Control in Wireless NetworksKaramad, Ehsan 10 January 2014 (has links)
We investigate the effects of quantized channel state information (CSI) on the performance of
resource allocation algorithms in wireless networks. The thesis starts with a brief overview
of a specific type of quantizer, referred to as a conservative quantizer where we propose the
optimality and sufficiency conditions as well as practical methods to find such quantizers. We
apply this theory to the quantization of transmitter CSI in point-to-point Gaussian channels
and transmission under short-term power constraints. Next, we show that in a multiple-node
decode-and-forward (DF) cooperative network, the same structure for quantizer is close to op-
timal for the sum-rate objective function. Based on a proposed upper bound on the rate loss in
such scenarios, we also argue that the quantizer should assign uneven numbers of quantization
bits to different links in the network. The simulation results show that given a target rate loss
level, through quantization and bit allocation, there is, on average, 0.5−1 bits per link savings
in CSI feedback requirements compared to the uniform and equal bit allocation approaches.
Given the many benefits in non-uniform allocation of CSI rate in the network, we formulate a
generalized bit allocation scheme which is extensible to arbitrary classes of network resource
allocation problems.
In the last part of this thesis, we focus on power control in an interference network and then,
investigate the effects of CSI imperfections on the performance of power control algorithms.
First, we propose an iterative power control algorithm based on a fixed-point iteration and prove
its local convergence. Then, we show that for a centralized implementation of the power control
algorithm, a uniform in dB (geometric) quantizer of channel power is efficient. Based on this
choice of channel quantizer, we propose a bound on rate loss in terms of the resolution of the
ii
deployed quantizer, where a 3 dB in quantization error is shown to contribute to a maximum of
1 bit rate loss at each user. Similarly to the previous scenario, the upper bound suggests that an
uneven assignment of numbers of quantization levels leads to smaller distortion. Based on this
bound, we develop the corresponding bit allocation laws. We also investigate the effects of CSI
errors on the performance of distributed power control algorithms and show that, compared to
the centralized case, the distributed algorithm could lead to a further SINR loss of up to 3
dB for one or more transmitters. This error is due to the fact that because of CSI errors, the
estimated interference level at each receiver is different from the induced interference wireless
transmitters expect.
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Efficient Globally Optimal Resource Allocation in Wireless Interference NetworksMatthiesen, Bho 20 December 2019 (has links)
Radio resource allocation in communication networks is essential to achieve optimal performance and resource utilization. In modern interference networks the corresponding optimization problems are often nonconvex and their solution requires significant computational resources. Hence, practical systems usually use algorithms with no or only weak optimality guarantees for complexity reasons. Nevertheless, asserting the quality of these methods requires the knowledge of the globally optimal solution. State-of-the-art global optimization approaches mostly employ Tuy's monotonic optimization framework which has some major drawbacks, especially when dealing with fractional objectives or complicated feasible sets.
In this thesis, two novel global optimization frameworks are developed. The first is based on the successive incumbent transcending (SIT) scheme to avoid numerical problems with complicated feasible sets. It inherently differentiates between convex and nonconvex variables, preserving the low computational complexity in the number of convex variables without the need for cumbersome decomposition methods. It also treats fractional objectives directly without the need of Dinkelbach's algorithm. Benchmarks show that it is several orders of magnitude faster than state-of-the-art algorithms.
The second optimization framework is named mixed monotonic programming (MMP) and generalizes monotonic optimization. At its core is a novel bounding mechanism accompanied by an efficient BB implementation that helps exploit partial monotonicity without requiring a reformulation in terms of difference of increasing (DI) functions. While this often leads to better bounds and faster convergence, the main benefit is its versatility. Numerical experiments show that MMP can outperform monotonic programming by a few orders of magnitude, both in run time and memory consumption.
Both frameworks are applied to maximize throughput and energy efficiency (EE) in wireless interference networks. In the first application scenario, MMP is applied to evaluate the EE gain rate splitting might provide over point-to-point codes in Gaussian interference channels. In the second scenario, the SIT based algorithm is applied to study throughput and EE for multi-way relay channels with amplify-and-forward relaying. In both cases, rate splitting gains of up to 4.5% are observed, even though some limiting assumptions have been made.
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Precoding for Interference Management in Wireless and Wireline NetworksGanesan, Abhinav January 2014 (has links) (PDF)
Multiple users compete for a common resource like bandwidth to communicate
data in interference networks. Existing approaches in dealing with interference
limit the rate of communication due to paucity of shared resources. This limitation
in the rate gets more glaring as the number of users in the network increases.
For example, existing wireless systems either choose to orthogonalize the users
(for example, Frequency Division Multiple Access (FDMA) systems or Code Division
Multiple Access (CDMA) systems) or treat interference as Gaussian noise at
the receivers. It is well known that these approaches are sub-optimal in general.
Orthogonalization of users limit the number of available interference-free channels
(known as degrees of freedom, abbreviated as DoF) and treating interference as
noise means that the receiver cannot make use of the structure in the interfering
signals. This motivates the need to analyze alternate transmit and decoding
schemes in interference networks.
This thesis mainly analyzes transmit schemes that use linear precoding for
various configurations of interference networks with some practical constraints
imposed by the use of finite input constellations, propagation delays, and channel
state availability at the transmitters. The main contributions of this thesis are
listed below.
Achievable rates using precoding with finite constellation inputs in Gaussian
Interference Channels (GIC) is analyzed. A metric for finding the approximate
angle of rotation to maximally enlarge the Constellation Constrained (CC) capacity
of two-user Gaussian Strong Interference Channel (GSIC) is proposed. Even as
the Gaussian alphabet FDMA rate curve touches the capacity curve of the GSIC,
with both the users using the same finite constellation, we show that the CC
FDMA rate curve lies strictly inside the CC capacity curve at high powers. For a
K-user MIMO GIC, a set of necessary and sufficient conditions on the precoders
under which the mutual information between between relevant transmit-receive
pairs saturate like in the single user case is derived. Gradient-ascent based algorithms
to optimize the sum-rate achieved by precoding with finite constellation
inputs and treating interference as noise are proposed.
For a class of Gaussian interference networks with general message demands,
identified as symmetrically connected interference networks, the expected sumspectral efficiency (in bits/sec/Hz) is shown to grow linearly with the number
of transmitters at finite SNR, using a time-domain Interference Alignment (IA)
scheme in the presence of line of sight (LOS) channels.
For a 2×2 MIMO X-Network with M antennas at each node, we identify spacetime
block codes that could be coupled with an appropriate precoding scheme to
achieve the maximum possible sum-DoF of 4M
3 , for M = 3, 4. The proposed
schemes are shown to achieve a diversity gain of M with SNR-independent finite
constellation inputs. The proposed schemes have lower CSIT requirements
compared to existing schemes.
This thesis also makes an attempt to guarantee a minimum throughput when
the zero-interference conditions cannot be satisfied in a wireline network with three
unicast sessions with delays, using Precoding Based Network Alignment (PBNA).
Three different PBNA schemes namely PBNA with time-varying local encoding
coefficients (LECs), PBNA using transform approach and time-invariant LECs,
and PBNA using transform approach and block time-varying LECs are proposed
and their feasibility conditions analyzed.
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Resource Allocation for Multiple-Input and Multiple-Output Interference NetworksCao, Pan 11 March 2015 (has links) (PDF)
To meet the exponentially increasing traffic data driven by the rapidly growing mobile subscriptions, both industry and academia are exploring the potential of a new genera- tion (5G) of wireless technologies. An important 5G goal is to achieve high data rate. Small cells with spectrum sharing and multiple-input multiple-output (MIMO) techniques are one of the most promising 5G technologies, since it enables to increase the aggregate data rate by improving the spectral efficiency, nodes density and transmission bandwidth, respectively. However, the increased interference in the densified networks will in return limit the achievable rate performance if not properly managed.
The considered setup can be modeled as MIMO interference networks, which can be classified into the K-user MIMO interference channel (IC) and the K-cell MIMO interfering broadcast channel/multiple access channel (MIMO-IBC/IMAC) according to the number of mobile stations (MSs) simultaneously served by each base station (BS). The thesis considers two physical layer (PHY) resource allocation problems that deal with the interference for both models: 1) Pareto boundary computation for the achiev- able rate region in a K-user single-stream MIMO IC and 2) grouping-based interference alignment (GIA) with optimized IA-Cell assignment in a MIMO-IMAC under limited feedback. In each problem, the thesis seeks to provide a deeper understanding of the system and novel mathematical results, along with supporting numerical examples. Some of the main contributions can be summarized as follows.
It is an open problem to compute the Pareto boundary of the achievable rate region for a K-user single-stream MIMO IC. The K-user single-stream MIMO IC models multiple transmitter-receiver pairs which operate over the same spectrum simultaneously. Each transmitter and each receiver is equipped with multiple antennas, and a single desired data stream is communicated in each transmitter-receiver link. The individual achievable rates of the K users form a K-dimensional achievable rate region. To find efficient operating points in the achievable rate region, the Pareto boundary computation problem, which can be formulated as a multi-objective optimization problem, needs to be solved. The thesis transforms the multi-objective optimization problem to two single-objective optimization problems–single constraint rate maximization problem and alternating rate profile optimization problem, based on the formulations of the ε-constraint optimization and the weighted Chebyshev optimization, respectively. The thesis proposes two alternating optimization algorithms to solve both single-objective optimization problems. The convergence of both algorithms is guaranteed. Also, a heuristic initialization scheme is provided for each algorithm to achieve a high-quality solution. By varying the weights in each single-objective optimization problem, numerical results show that both algorithms provide an inner bound very close to the Pareto boundary. Furthermore, the thesis also computes some key points exactly on the Pareto boundary in closed-form.
A framework for interference alignment (IA) under limited feedback is proposed for a MIMO-IMAC. The MIMO-IMAC well matches the uplink scenario in cellular system, where multiple cells share their spectrum and operate simultaneously. In each cell, a BS receives the desired signals from multiple MSs within its own cell and each BS and each MS is equipped with multi-antenna. By allowing the inter-cell coordination, the thesis develops a distributed IA framework under limited feedback from three aspects: the GIA, the IA-Cell assignment and dynamic feedback bit allocation (DBA), respec- tively. Firstly, the thesis provides a complete study along with some new improvements of the GIA, which enables to compute the exact IA precoders in closed-form, based on local channel state information at the receiver (CSIR). Secondly, the concept of IA-Cell assignment is introduced and its effect on the achievable rate and degrees of freedom (DoF) performance is analyzed. Two distributed matching approaches and one centralized assignment approach are proposed to find a good IA-Cell assignment in three scenrios with different backhaul overhead. Thirdly, under limited feedback, the thesis derives an upper bound of the residual interference to noise ratio (RINR), formulates and solves a corresponding DBA problem. Finally, numerical results show that the proposed GIA with optimized IA-Cell assignment and the DBA greatly outperforms the traditional GIA algorithm.
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Resource Allocation for Multiple-Input and Multiple-Output Interference NetworksCao, Pan 12 January 2015 (has links)
To meet the exponentially increasing traffic data driven by the rapidly growing mobile subscriptions, both industry and academia are exploring the potential of a new genera- tion (5G) of wireless technologies. An important 5G goal is to achieve high data rate. Small cells with spectrum sharing and multiple-input multiple-output (MIMO) techniques are one of the most promising 5G technologies, since it enables to increase the aggregate data rate by improving the spectral efficiency, nodes density and transmission bandwidth, respectively. However, the increased interference in the densified networks will in return limit the achievable rate performance if not properly managed.
The considered setup can be modeled as MIMO interference networks, which can be classified into the K-user MIMO interference channel (IC) and the K-cell MIMO interfering broadcast channel/multiple access channel (MIMO-IBC/IMAC) according to the number of mobile stations (MSs) simultaneously served by each base station (BS). The thesis considers two physical layer (PHY) resource allocation problems that deal with the interference for both models: 1) Pareto boundary computation for the achiev- able rate region in a K-user single-stream MIMO IC and 2) grouping-based interference alignment (GIA) with optimized IA-Cell assignment in a MIMO-IMAC under limited feedback. In each problem, the thesis seeks to provide a deeper understanding of the system and novel mathematical results, along with supporting numerical examples. Some of the main contributions can be summarized as follows.
It is an open problem to compute the Pareto boundary of the achievable rate region for a K-user single-stream MIMO IC. The K-user single-stream MIMO IC models multiple transmitter-receiver pairs which operate over the same spectrum simultaneously. Each transmitter and each receiver is equipped with multiple antennas, and a single desired data stream is communicated in each transmitter-receiver link. The individual achievable rates of the K users form a K-dimensional achievable rate region. To find efficient operating points in the achievable rate region, the Pareto boundary computation problem, which can be formulated as a multi-objective optimization problem, needs to be solved. The thesis transforms the multi-objective optimization problem to two single-objective optimization problems–single constraint rate maximization problem and alternating rate profile optimization problem, based on the formulations of the ε-constraint optimization and the weighted Chebyshev optimization, respectively. The thesis proposes two alternating optimization algorithms to solve both single-objective optimization problems. The convergence of both algorithms is guaranteed. Also, a heuristic initialization scheme is provided for each algorithm to achieve a high-quality solution. By varying the weights in each single-objective optimization problem, numerical results show that both algorithms provide an inner bound very close to the Pareto boundary. Furthermore, the thesis also computes some key points exactly on the Pareto boundary in closed-form.
A framework for interference alignment (IA) under limited feedback is proposed for a MIMO-IMAC. The MIMO-IMAC well matches the uplink scenario in cellular system, where multiple cells share their spectrum and operate simultaneously. In each cell, a BS receives the desired signals from multiple MSs within its own cell and each BS and each MS is equipped with multi-antenna. By allowing the inter-cell coordination, the thesis develops a distributed IA framework under limited feedback from three aspects: the GIA, the IA-Cell assignment and dynamic feedback bit allocation (DBA), respec- tively. Firstly, the thesis provides a complete study along with some new improvements of the GIA, which enables to compute the exact IA precoders in closed-form, based on local channel state information at the receiver (CSIR). Secondly, the concept of IA-Cell assignment is introduced and its effect on the achievable rate and degrees of freedom (DoF) performance is analyzed. Two distributed matching approaches and one centralized assignment approach are proposed to find a good IA-Cell assignment in three scenrios with different backhaul overhead. Thirdly, under limited feedback, the thesis derives an upper bound of the residual interference to noise ratio (RINR), formulates and solves a corresponding DBA problem. Finally, numerical results show that the proposed GIA with optimized IA-Cell assignment and the DBA greatly outperforms the traditional GIA algorithm.
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