A 6nW inductive-coupling wake-up transceiver for reducing standby power of non-contact memory card by 500×

N. Miura, Mitsuko Saito, M. Taguchi, T. Kuroda
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引用次数: 1

Abstract

Memory cards are widely used in electronic systems to expand internal storage area or are used as detachable media to carry data. Although cloud computing has recently drawn attention, data transfer consumes significant power (e.g., 1% battery charge of a smartphone when 10 pictures are transferred through WLAN), making local memory card storage still attractive in mobile devices. As storage capacity increases, the I/O speed should also increase accordingly. However, conventional memory cards require strong ESD protection, limiting high-speed data transfer. A non-contact memory card [1] is one of the solutions to this problem. No signal terminals are exposed for mechanical contact, which relaxes ESD constraints. A data transfer rate of 6Gb/s/ch by inductive coupling [1] and 12Gb/s/ch by transmission-line coupling [2] are reported. The post-UHS-II speed over 5Gb/s can be covered with around 10mW power consumption. Moreover, by supplying power wirelessly, mechanical connections can be completely removed, which could provide features such as waterproof capability or a new attach-remove user interface. A >50% high-efficient wireless power delivery has been reported [3]. However, it mainly supplies a large amount of active power, and the efficiency drops to ~10% in low-power standby mode. Shutting down the power delivery in standby would require a power-on sequence and an unacceptably long suspend (~10s) for each new command. For high-speed card access, the power delivery and the wireless data receiver (RX) should always be active, consuming about 2mW in RX and in total 20mW including loss in the wireless power delivery. This standby power is almost identical to that of typical smartphones, tablet-PCs, or camcorders and the battery life halves.
一种6nW电感耦合唤醒收发器,可将非接触式存储卡待机功率降低500x
存储卡广泛应用于电子系统中,以扩大内部存储空间或作为可拆卸的介质来携带数据。虽然云计算最近引起了人们的关注,但数据传输需要消耗大量的电力(例如,通过WLAN传输10张照片,智能手机的电池电量为1%),这使得本地存储卡存储在移动设备中仍然具有吸引力。随着存储容量的增加,I/O速度也应该相应提高。然而,传统的存储卡需要强大的ESD保护,限制了高速数据传输。非接触式存储卡[1]是解决这一问题的方法之一。没有机械接触的信号端子暴露,从而放松了ESD约束。电感耦合[1]和在线传输耦合[2]的数据传输率分别达到6Gb/s/ch和12Gb/s/ch。超过5Gb/s的后uhs - ii速度可以覆盖约10mW的功耗。此外,通过无线供电,机械连接可以完全去除,这可以提供防水功能或新的连接-拆卸用户界面。有报道称,无线电力传输效率可达50%以上[3]。然而,它主要提供大量的有功功率,在低功耗待机模式下效率下降到~10%。在待机状态下关闭电源传输将需要一个上电序列,并且每个新命令都需要一个不可接受的长挂起(~10s)。对于高速卡接入,电源传输和无线数据接收器(RX)应始终处于活动状态,RX消耗约2mW,包括无线电源传输的损耗在内,总共消耗20mW。这种待机电源几乎与典型的智能手机、平板电脑或便携式摄像机相同,电池寿命缩短了一半。
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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