Resource Allocation for Millimeter Wave Self-Backhaul Network Using Markov Approximation

Millimeter wave (mmW) self-backhaul has been regarded as a high-capacity and low-cost solution to deploy dense small cell networks but its performance depends on a resource allocation strategy, which can effectively reduce interference (including co-tier interference, cross-tier interference, and self-interference). Taking the use of beamforming and the advantage of mmW short-range communication into account, this paper formulates a resource allocation problem in which sub-channels can be shared among low-interference links while orthogonal sub-channels can be used at the links that suffer high-level interference among them. The objective is to maximize the sum data rates of all users while ensuring the data rate of backhaul link at each small cell base station is greater than or equal to the sum data rates of all its served users in the access links. Besides, the data rate of each user should achieve its minimum traffic demand. The optimization problem is a combinatorial integer programming problem with a series of inequality constraints, which is difficult to solve. By introducing penalty function and penalty factors into it, the problem is transferred to an equivalent problem without any inequality, and then it can be addressed by the Markov approximation method. First, by leveraging the log-sum-exp method to approximate the equivalent problem, we deduce the near optimal solution. However, it is difficult to calculate the deduced solution since that it needs all possible solution information, and thus a Markov chain is then utilized to converge to the near optimal solution. The numerical results are shown to verify the performance of the proposed algorithm.

[1]  Gang Chen,et al.  Relay Selection and Discrete Power Control for Cognitive Relay Networks via Potential Game , 2014, IEEE Transactions on Signal Processing.

[2]  Robert W. Heath,et al.  Spatially Sparse Precoding in Millimeter Wave MIMO Systems , 2013, IEEE Transactions on Wireless Communications.

[3]  Walid Saad,et al.  Offloading in HetNet: A Coordination of Interference Mitigation, User Association, and Resource Allocation , 2017, IEEE Transactions on Mobile Computing.

[4]  Taneli Riihonen,et al.  Sum-Rate Analysis and Optimization of Self-Backhauling Based Full-Duplex Radio Access System , 2016, ArXiv.

[5]  Walid Saad,et al.  Inter-Operator Resource Management for Millimeter Wave Multi-Hop Backhaul Networks , 2017, IEEE Transactions on Wireless Communications.

[6]  Ming Xiao,et al.  Millimeter Wave Communications for Future Mobile Networks , 2017, IEEE Journal on Selected Areas in Communications.

[7]  Matti Latva-aho,et al.  Joint Load Balancing and Interference Mitigation in 5G Heterogeneous Networks , 2016, IEEE Transactions on Wireless Communications.

[8]  Shiwen Mao,et al.  Minimum Time Length Scheduling under Blockage and Interference in Multi-Hop mmWave Networks , 2014, GLOBECOM 2014.

[9]  Ekram Hossain,et al.  Downlink Spectrum Allocation for In-Band and Out-Band Wireless Backhauling of Full-Duplex Small Cells , 2017, IEEE Transactions on Communications.

[10]  Ming Xiao,et al.  Discrete Power Control and Transmission Duration Allocation for Self-Backhauling Dense mmWave Cellular Networks , 2018, IEEE Transactions on Communications.

[11]  Ming Xiao,et al.  Low-Latency Millimeter-Wave Communications: Traffic Dispersion or Network Densification? , 2017, IEEE Transactions on Communications.

[12]  Victor O. K. Li,et al.  Backhaul Resource Allocation for Existing and Newly Arrived Moving Small Cells , 2017, IEEE Transactions on Vehicular Technology.

[13]  Jeffrey G. Andrews,et al.  Performance of Dynamic and Static TDD in Self-Backhauled Millimeter Wave Cellular Networks , 2017, IEEE Transactions on Wireless Communications.

[14]  Giuseppe Caire,et al.  A Joint Scheduling and Resource Allocation Scheme for Millimeter Wave Heterogeneous Networks , 2017, 2017 IEEE Wireless Communications and Networking Conference (WCNC).

[15]  Giuseppe Caire,et al.  Radio Resource Management Considerations for 5G Millimeter Wave Backhaul and Access Networks , 2017, IEEE Communications Magazine.

[16]  Akbar M. Sayeed,et al.  Sublinear Capacity Scaling Laws for Sparse MIMO Channels , 2011, IEEE Transactions on Information Theory.

[17]  Victor C. M. Leung,et al.  Green Full-Duplex Self-Backhaul and Energy Harvesting Small Cell Networks With Massive MIMO , 2016, IEEE Journal on Selected Areas in Communications.

[18]  Jeffrey G. Andrews,et al.  Modeling and Analyzing Millimeter Wave Cellular Systems , 2016, IEEE Transactions on Communications.

[19]  Ming Xiao,et al.  Decentralized Beam Pair Selection in Multi-Beam Millimeter-Wave Networks , 2018, IEEE Transactions on Communications.

[20]  Shouyi Yang,et al.  Energy-Efficient Resource Allocation for mmWave Massive MIMO HetNets With Wireless Backhaul , 2018, IEEE Access.

[21]  Xu Yang,et al.  Spectrum Allocation for mmWave Backhaul Networks: An Approach Based on Matching Game , 2018, 2018 IEEE 87th Vehicular Technology Conference (VTC Spring).

[22]  Ning Wang,et al.  Joint Downlink Cell Association and Bandwidth Allocation for Wireless Backhauling in Two-Tier HetNets With Large-Scale Antenna Arrays , 2014, IEEE Transactions on Wireless Communications.

[23]  Matti Latva-aho,et al.  Joint In-Band Backhauling and Interference Mitigation in 5G Heterogeneous Networks , 2016, ArXiv.

[24]  Ashwin Sampath,et al.  Integrated Access Backhaul in Millimeter Wave Networks , 2017, 2017 IEEE Wireless Communications and Networking Conference (WCNC).

[25]  Minghua Chen,et al.  Markov Approximation for Combinatorial Network Optimization , 2013, IEEE Transactions on Information Theory.

[26]  Erik G. Larsson,et al.  Multipair Full-Duplex Relaying With Massive Arrays and Linear Processing , 2014, IEEE Journal on Selected Areas in Communications.

[27]  Minghua Chen,et al.  Optimal Distributed P2P Streaming Under Node Degree Bounds , 2010, IEEE/ACM Transactions on Networking.

[28]  Jeffrey G. Andrews,et al.  How Many Hops Can Self-Backhauled Millimeter Wave Cellular Networks Support? , 2018, ArXiv.

[29]  Theodore S. Rappaport,et al.  Millimeter-Wave Enhanced Local Area Systems: A High-Data-Rate Approach for Future Wireless Networks , 2014, IEEE Journal on Selected Areas in Communications.