1.2Gb/s 3.9pJ/b mono-phase pulse-modulation inductive-coupling transceiver for mm-range board-to-board communication

Hyunwoo Cho, U. Ha, Taehwan Roh, Dongchurl Kim, Jeahyuck Lee, Y. Oh, H. Yoo
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引用次数: 13

Abstract

Recently, short distance board-to-board interconnections are widely employed in portable systems and wearable devices to accommodate many components into an extremely tight footprint. In particular, portable devices such as smart phone and tablet require over 1Gb/s data transfer through ~1mm distance between AP board and a high resolution wide screen display board. Most of display interfaces are implemented with wire-line F-PCB connector, but, they suffer from: 1) high manufacturing cost, 2) the large form factor of the connector and standard socket and 3) large capacitance values of the connector and socket degrading the channel characteristics. So far, various communication interfaces have been tried to realize low cost, small form factor and low energy operation, but with limited success. The bi-phase pule modulation was used in board-to-board communication rather than base-band transmission due to its low energy operation [1-5]. This method used the positive pulse current for data `1' and the negative pulse current for data `0', and the receiver recovered the data by sampling the data at the exact time, which requires an accurate delay control unit. However, the bi-phase pulse modulation consumes significant power because: 1) current pulses sampled at every data consume large current in TX, and 2) a power hungry delay control unit is required to exactly control the sampling time.
1.2Gb/s 3.9pJ/b单相脉冲调制电感耦合收发器,用于mm范围板对板通信
最近,短距离板对板互连被广泛应用于便携式系统和可穿戴设备中,以在极小的空间内容纳许多组件。特别是,智能手机、平板电脑等便携式设备需要在AP板和高分辨率宽屏显示板之间通过~1mm的距离传输1Gb/s以上的数据。大多数显示接口都是用线式F-PCB连接器实现的,但是,它们存在以下问题:1)制造成本高,2)连接器和标准插座的外形尺寸大,以及3)连接器和插座的大电容值降低了通道特性。到目前为止,各种通信接口都试图实现低成本、小尺寸和低能耗的运行,但收效甚微。双相脉冲调制由于其低能量运行,被用于板对板通信而不是基带传输[1-5]。该方法对数据“1”采用正脉冲电流,对数据“0”采用负脉冲电流,接收机在准确的时间对数据进行采样,从而恢复数据,这就需要精确的延时控制单元。然而,双相脉冲调制消耗了大量的功率,因为:1)在每个数据处采样的电流脉冲在TX中消耗大电流,2)需要耗电的延迟控制单元来精确控制采样时间。
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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