Impacts of joint packet scheduling for heterogeneous component carriers in multi-carrier systems

2013 International Computer Science and Engineering Conference (ICSEC) Pub Date : 2013-09-01 DOI:10.1109/ICSEC.2013.6694812

Sangchul Oh, B. Ryu, Yeonseung Shin, Pyeongjung Song, Dongseung Kwon

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Abstract

Component carriers (CCs) in a Long Term Evolution - Advanced (LTE-A) system are limited by maximum 100 radio bearers (RBs) on a 20 MHz CC due to a fixed 15 KHz subcarrier bandwidth. However it is able to be changed in the future, so that a study regarding heterogeneous CCs which have diverse RBs above 100 on a CC is needed at this moment. To support non-contiguous carrier aggregation (CA) with the these conditions, a heterogeneous joint CC packet scheduling algorithm interacting with a radio resource control (RRC) is considered in this paper. The performance of the joint CC packet scheduling algorithm on heterogeneous CCs with different channel characteristics has been analyzed and compared through computer simulations as well. According to the results, we found that an 800 MHz CC exhibits approximately 4 dB better channel gains than a 2.1 GHz CC. We also obtained a capacity increase of about 15-40% for a joint CC maximum rate (MR) algorithm and about 2-28 % for a joint CC proportional fair (PF) algorithm when the number of users is increased. On the other hand, in a round-robin (RR) scenario, we were unable to notice any differences between the independent CC and joint CC packet scheduling policies. Furthermore, looking at the impacts of different amounts of RBs on 800 MHz + 2.1 GHz CCs, we can conclude that a one-to-one RB ratio with respect to the MR, PF, and RR algorithms has a better performance compared to other cases, and thus, owing to the better channel gain, the smaller the RBs of the 800 MHz CC, the better the performance achieved.

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多载波系统中异构组件载波联合分组调度的影响

长期演进-高级(LTE-A)系统中的分量载波(CC)由于固定的15 KHz子载波带宽，在20 MHz CC上最多受100个无线电承载(RBs)的限制。然而，这在未来是可以改变的，因此目前需要对CC上具有100以上不同RBs的异质CC进行研究。为了在这些条件下支持非连续载波聚合(CA)，本文考虑了一种与无线电资源控制(RRC)交互的异构联合CC包调度算法。通过计算机仿真，分析比较了联合CC包调度算法在不同信道特性的异构CC上的性能。根据结果，我们发现800 MHz CC比2.1 GHz CC具有约4 dB的信道增益，并且当用户数量增加时，联合CC最大速率(MR)算法的容量增加了约15-40%，联合CC比例公平(PF)算法的容量增加了约2- 28%。另一方面，在轮询(RR)场景中，我们无法注意到独立CC和联合CC包调度策略之间的任何差异。此外，通过观察不同数量的RBs对800 MHz + 2.1 GHz CC的影响，我们可以得出结论，与其他情况相比，MR、PF和RR算法的1:1 RB比具有更好的性能，因此，由于信道增益更好，800 MHz CC的RBs越小，性能越好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 International Computer Science and Engineering Conference (ICSEC)

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