TY - JOUR
T1 - Energy conservation and interference mitigation
T2 - From decoupling property to win-win strategy
AU - Fu, Liqun
AU - Kim, Hongseok
AU - Huang, Jianwei
AU - Liew, Soung Chang
AU - Chiang, Mung
N1 - Funding Information:
This work is supported by AoE grant E-02/08 from the UGC of the Hong Kong SAR, China, the General Research Funds (Project Number 412509, 412511, 412710, and 414911) established under the University Grant Committee of the Hong Kong Special Administrative Region, China, the Sogang University Research Grant of 2011, Google, Princeton Grand Challenge grant, and NSF CNS-1011962. Digital Object Identifier 10.1109/TWC.2011.091411.110354
PY - 2011/11
Y1 - 2011/11
N2 - This paper studies the problem of energy conservation of mobile terminals in a multi-cell TDMA network supporting real-time sessions. The corresponding optimization problem involves joint scheduling, rate control, and power control, which is often highly complex to solve. To reduce the solution complexity, we decompose the overall problem into two sub-problems: intra-cell energy optimization and inter-cell interference control. The solution of the two subproblems results in a "win-win" situation: both the energy consumptions and inter-cell interference are reduced simultaneously. We simulate our decomposition method with the typical parameters in WiMAX system, and the simulation results show that our decomposition method can achieve an energy reduction of more than 70% compared with the simplistic maximum transmit power policy. Furthermore, the inter-cell interference power can be reduced by more than 35% compared with the maximum transmit power policy. We find that the interference power stays largely constant throughout a TDMA frame in our decomposition method. Based on this premise, we derive an interesting decoupling property: if the idle power consumption of terminals is no less than their circuit power consumption, or when both are negligible, then the energy-optimal transmission rates of the users are independent of the inter-cell interference power.
AB - This paper studies the problem of energy conservation of mobile terminals in a multi-cell TDMA network supporting real-time sessions. The corresponding optimization problem involves joint scheduling, rate control, and power control, which is often highly complex to solve. To reduce the solution complexity, we decompose the overall problem into two sub-problems: intra-cell energy optimization and inter-cell interference control. The solution of the two subproblems results in a "win-win" situation: both the energy consumptions and inter-cell interference are reduced simultaneously. We simulate our decomposition method with the typical parameters in WiMAX system, and the simulation results show that our decomposition method can achieve an energy reduction of more than 70% compared with the simplistic maximum transmit power policy. Furthermore, the inter-cell interference power can be reduced by more than 35% compared with the maximum transmit power policy. We find that the interference power stays largely constant throughout a TDMA frame in our decomposition method. Based on this premise, we derive an interesting decoupling property: if the idle power consumption of terminals is no less than their circuit power consumption, or when both are negligible, then the energy-optimal transmission rates of the users are independent of the inter-cell interference power.
KW - Energy-efficiency
KW - multi-cell wireless system
KW - power control
KW - rate control
KW - scheduling
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U2 - 10.1109/TWC.2011.091411.110354
DO - 10.1109/TWC.2011.091411.110354
M3 - Article
AN - SCOPUS:83555164686
SN - 1536-1276
VL - 10
SP - 3943
EP - 3955
JO - IEEE Transactions on Wireless Communications
JF - IEEE Transactions on Wireless Communications
IS - 11
M1 - 6025330
ER -