混合D2D蜂窝网络中基于模拟退火算法的资源调度策略

doi:10.11959/j.issn.1000-0801.2017093

Abstract

Abstract:

D2D communication is a short distance communication mode in the future 5G network.In the process of communication,the information is transmitted from the sender to the receiver directly,without the need to transmit through the base station.The introduction of D2D communication in the traditional cellular network can greatly improve the total throughput of the system,increase the utilization of spectrum resources and reduce the power consumption of the transmitter.A resource allocation method which was used in hybrid D2D cellular network was mainly introduced,spectrum resources was distributed by Lagrange multiplier method combined with simulated annealing algorithm,a consideration of channel capacity and energy consumption of the resource scheduling strategy based on simulated annealing algorithm was put forward.This algorithm was simulated by the simulation platform in Vienna,compared to the traditional greedy optimization algorithm,it can significantly increase the total system throughput and bandwidth utilization and reduce the power consumption.In addition,the distributed algorithm was adopted,that D2D users searched for a suitable target channel and calculated their transmit power according to the algorithm steps,which reduced the signaling overhead of the base station.

Key words: D2D communication, resource allocation, Lagrange multiplier method, simulated annealing algorithm, power control

CLC Number:

TN929.5

Xiang YU,Haibo ZHANG,Lu YANG. Resource scheduling strategy based on simulated annealing algorithm in hybrid D2D cellular networks[J]. Telecommunications Science, 2017, 33(4): 71-77.

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References 15

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参数	取值
小区半径/m	600
资源块数目/个	30
路径衰落模型	蜂窝模式：128.1+36.7lgd
	D2D模式：148+40lgd
阴影衰落标准差/dB	蜂窝模式： 10
	D2D模式： 12
D2D最大通信距离/m	60
用户的最大发射功率/dBm	14
蜂窝用户数/个	30
D2D链路数/个	15
接收信干比门限值/dB	-10
系统带宽/MHz	10
高斯噪声功率普密度/（dBm·Hz^-1）	-174
仿真次数/次	500
TTI/ms	200

Resource scheduling strategy based on simulated annealing algorithm in hybrid D2D cellular networks

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