An experiment in reducing cellular base station power draw with virtual coverage

ACM DEV-4 '13 Pub Date : 2013-12-06 DOI:10.1145/2537052.2537058

Kurtis Heimerl, Shaddi Hasan, Kashif Ali, Tapan S. Parikh, E. Brewer

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引用次数: 9

Abstract

Lack of access to cellular service often goes hand-in-hand with lack of access to power. For example, the GSM Association estimates that 95% of people living without cellular access in East Africa also lack access to grid power. This situation forces cellular network operators to build out power infrastructure along with their network infrastructure, dramatically increasing costs. While numerous equipment providers offer "low-power" GSM Base Stations (BTS) for use with renewable energy sources, these have a power floor of roughly 70W, which still necessitates a large upfront expenditure. The naïve solution to this problem is duty-cycling---simply turning off the equipment for portions of the day, usually at night. This commonly-adopted approach prevents important use cases such as all-hours emergency calling. Recently, we proposed a technique called virtual coverage to provide on-demand cellular coverage by introducing a "sleep" mode for cellular equipment. The solution turns off the BTS during low-utilization periods, but allows users to power the system back on using specialized autonomous radios if they need to communicate. Incoming communications also wake the BTS, facilitating two-way correspondence. While a potential solution, no real-world deployments have yet validated virtual coverage. The core goal of this work is do just that; we utilize virtual coverage to provide both low power consumption and on-demand access in a real cellular network during a six-month deployment in rural Papua, Indonesia. We demonstrate that the system was used and understood by customers, with more than half of subscribers using the system during "night" (i.e., on-battery) hours, making 730 outbound and receiving 755 inbound communications. Our scheme also allowed the BTS to be in low-power mode for 87% of night hours, reducing night power draw by 56.6%. We believe these results demonstrate that virtual coverage is a viable solution for reducing power draw in rural cellular networks.

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虚拟覆盖降低蜂窝基站功耗的实验

缺乏手机服务往往与缺乏电力供应密切相关。例如，GSM协会估计东非95%没有手机接入的人也无法接入电网。这种情况迫使蜂窝网络运营商在建设网络基础设施的同时建设电力基础设施，从而大大增加了成本。虽然许多设备供应商提供“低功耗”GSM基站(BTS)，用于使用可再生能源，但这些基站的最低功率约为70W，这仍然需要大量的前期支出。naïve解决这个问题的方法是“责任循环”——只需要在一天的部分时间(通常是在晚上)关闭设备。这种普遍采用的方法可以防止重要的用例，例如全天紧急呼叫。最近，我们提出了一种称为虚拟覆盖的技术，通过为蜂窝设备引入“睡眠”模式来提供按需蜂窝覆盖。该解决方案在低利用率期间关闭BTS，但如果用户需要通信，则允许用户使用专门的自主无线电重新启动系统。传入的通信也会唤醒BTS，从而实现双向通信。虽然这是一个潜在的解决方案，但还没有实际部署验证虚拟覆盖。这项工作的核心目标就是做到这一点;在为期六个月的印度尼西亚巴布亚农村部署期间，我们利用虚拟覆盖在真实的蜂窝网络中提供低功耗和按需访问。我们证明了该系统被客户使用和理解，超过一半的用户在“夜间”(即未充电)时间使用该系统，发出730个出站通信，接收755个入站通信。我们的方案还允许BTS在87%的夜间时间处于低功耗模式，减少了56.6%的夜间功耗。我们相信这些结果表明，虚拟覆盖是减少农村蜂窝网络功耗的可行解决方案。

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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ACM DEV-4 '13

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