Intelligent Large-Scale AP Control with Remarkable Energy Saving in Campus WiFi System

Full WiFi coverage is more and more prevalent in many places such as university, enterprise, big mall, etc. To achieve full WiFi coverage in a wide area is very costly. Not only extensive AP deployments are expensive, to operate and maintain such large-scale APs every day can also cost much, e.g., the huge power consumption. In this paper, we collect large-scale AP status data in our campus WiFi system, which contains over 8,000 APs and serves about 40,000 active end-users in the area of 3.0925 km2 • After conducting empirical studies on AP loads, we find Idle Phenomenon prevails throughout the trace. A large portion of APs are running without any user association, which will inevitably lead to unnecessary energy consumption. Inspired by this, we propose an intelligent large-scale AP control scheme, named as ACE (i.e., AP Control with Energy saving), to dynamically control large-scale APs (On or Off for energy saving meanwhile without loss of WiFi coverage. In ACE, the load of each AP is predicted first by the random forest algorithm, and those APs whose idle durations last for more than the length of the pre-defined sliding window will be turned off. We conduct extensive trace-driven simulations to demonstrate the efficiency of the ACE scheme; specifically, more than 70% of power energy can be saved with over 92 % of user WiFi coverage guaranteed in average.

[1]  Geoffrey M. Voelker,et al.  Usage Patterns in an Urban WiFi Network , 2010, IEEE/ACM Transactions on Networking.

[2]  Kang G. Shin,et al.  E-MiLi: Energy-Minimizing Idle Listening in Wireless Networks , 2012, IEEE Trans. Mob. Comput..

[3]  Dan Pei,et al.  Characterizing and Improving WiFi Latency in Large-Scale Operational Networks , 2016, MobiSys.

[4]  Marco Ajmone Marsan,et al.  Energy-performance trade-off in dense WLANs: A queuing study , 2012, Comput. Networks.

[5]  Kyu Ho Park,et al.  A Cooperative Clustering Protocol for Energy Saving of Mobile Devices with WLAN and Bluetooth Interfaces , 2011, IEEE Transactions on Mobile Computing.

[6]  Minglu Li,et al.  Intelligent Context-Aware Communication Paradigm Design for IoVs Based on Data Analytics , 2018, IEEE Network.

[7]  Shigeki Takeda,et al.  Energy Efficient Learning-Based Indoor Multi-Band WLAN for Smart Buildings , 2018, IEEE Access.

[8]  Xiang Zhang,et al.  Opportunistic WiFi Offloading in Vehicular Environment: A Game-Theory Approach , 2016, IEEE Transactions on Intelligent Transportation Systems.

[9]  Longfei Shangguan,et al.  Wi-Fi Goes to Town: Rapid Picocell Switching for Wireless Transit Networks , 2017, SIGCOMM.

[10]  Suman Banerjee,et al.  Observing home wireless experience through WiFi APs , 2013, MobiCom.

[11]  Prasant Mohapatra,et al.  Characterizing WiFi connection and its impact on mobile users: practical insights , 2013, WiNTECH '13.

[12]  Katia Obraczka,et al.  Characterizing User Activity in WiFi Networks: University Campus and Urban Area Case Studies , 2016, MSWiM.

[13]  Wenchao Xu,et al.  Big Data Driven Vehicular Networks , 2018, IEEE Network.

[14]  Kevin C. Almeroth,et al.  Green WLANs: On-Demand WLAN Infrastructures , 2009, Mob. Networks Appl..

[15]  Sadao Obana,et al.  A proposal of power saving scheme for wireless access networks with access point sharing , 2012, 2012 International Conference on Computing, Networking and Communications (ICNC).

[16]  Marco Ajmone Marsan,et al.  Queueing systems to study the energy consumption of a campus WLAN , 2014, Comput. Networks.

[17]  Li-Chun Wang,et al.  Achieving energy saving with QoS guarantee for WLAN using SDN , 2016, 2016 IEEE International Conference on Communications (ICC).

[18]  Kyunghan Lee,et al.  Mobile data offloading: how much can WiFi deliver? , 2010, SIGCOMM 2010.