带片上光电二极管的8.5Gb/s CMOS OEIC用于短距离光通信

Dongmyung Lee, Jung-Won Han, E. Chang, G. Han, Sung Min Park
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引用次数: 9

摘要

近年来,低成本的硅光电集成电路(OEICs)在短距离光通信中的应用越来越受到关注,如片对片互连、板对板互连、局域网、数据存储网络等[1-4]。特别是,带有片上硅光电二极管的单片oeic具有许多优点,包括低成本、减少地面反弹和键线诱导耦合。然而,在标准CMOS工艺中,硅光电二极管的慢响应是高速通信的主要瓶颈[1]。为了提高硅光电二极管的带宽,一些工艺改进或雪崩光电二极管的实现已经被开发出来。然而,前者导致成本增加,而后者则存在可靠性问题。虽然差分光电二极管配置最初被提出用于带宽扩展[2-4],但操作速度仍然限制在几百Mb/s。同时,利用均衡滤波器[1,3]可以扩大带宽。对于相对低gb /s的操作,固定的均衡滤波器就足够了,因为光电二极管的响应主要由扩散电流决定,而扩散电流对工艺和温度变化不敏感。对于更高的速度,响应性变得强烈依赖于工艺和温度的变化,因为它主要是由载流子迁移率决定的。因此,高gb /s光接收机的均衡器需要一种自适应算法来补偿显著的过程和温度变化。本文介绍了一种带有片上光电二极管的OEIC。带宽和响应由一个紧凑的自适应均衡器补偿,从而实现8.5Gb/s的操作。
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An 8.5Gb/s CMOS OEIC with on-chip photodiode for short-distance optical communications
Recently, low-cost silicon optoelectronic integrated circuits (OEICs) have been drawing attention for applications in short-distance optical communications such as chip-to-chip and board-to-board interconnects, LAN, data storage networks, etc [1–4]. Particularly, single-chip OEICs with on-chip silicon photodiodes provide a number of advantages including low cost, reduced ground-bounce, and bond-wire-induced coupling. Nevertheless, the slow response of silicon photodiodes in a standard CMOS process serves as a major bottleneck for high-speed communication [1]. To improve the bandwidth of silicon photodiodes, either some process modification or avalanche photodiode implementation has been developed. However, the former results in increased costs, whereas the latter has reliability issues. Although a differential photodiode configuration was originally proposed for bandwidth extension [2–4], the operation speed is still limited to several-hundred Mb/s. Meanwhile, the bandwidth can be extended by exploiting equalization filter [1, 3]. For relatively low-Gb/s operations, fixed equalization filter is sufficient, because photodiode responsivity is dominantly determined by diffusion currents which are not sensitive to process and temperature variations. For higher speeds, the responsivity becomes strongly dependent on the process and temperature variations, because it is mainly determined by the carrier mobility. Thereby, equalizers for high-Gb/s optical receivers require an adaptation algorithm to compensate the significant process and temperature variations. In this paper, an OEIC with on-chip photodiode is presented. Bandwidth and responsivity are compensated by a compact adaptive equalizer, thus achieving 8.5Gb/s operation.
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