22.7 4×25.78Gb/s定时器ic,用于0.13μm SiGe BiCMOS光链路

T. Shibasaki, Y. Tsunoda, H. Oku, S. Ide, Toshihiko Mori, Y. Koyanagi, Kazuhiro Tanaka, T. Ishihara, H. Tamura
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引用次数: 3

摘要

为了满足对服务器计算能力日益增长的需求,需要高密度、数据速率超过25Gb/s/lane的多通道链路。具有重定时能力的光收发器将通过扩展范围大大提高链路的可用性。这种光收发器应该在没有外部时钟源的情况下工作,因为小的外形是必不可少的。我们开发的光链路具有四通道配置,由电光(E/O)转换器和光电(O/E)转换器组成(图22.7.1)。E/O和O/E转换器都配备了一个逐通道无参考时钟和数据恢复(CDR)电路,使每个通道能够独立运行。收发器间距为250μm/lane,与链路中使用的光纤阵列的光纤间距相匹配。由于CDR增加的抖动在计时器应用中应该最小化,因此LC-VCO是时钟信号生成的较好选择。然而,在此收发器螺距下,LC罐之间通过互感产生的耦合对CDR特性有显著影响。为了解决这个问题,我们分析了vco间耦合的影响,并设计了CDR,使耦合不影响CDR性能。E/O转换器的每个通道由一个连续时间线性均衡器(CTLE)、一个CDR和一个带两个抽头前馈均衡器(FFE)的VCSEL驱动器组成(图22.7.1)。O/E转换器的每个通道都有一个跨阻抗放大器(TIA)级,然后是一个限制放大器(LA),一个CDR和一个带双抽头FFE的电线驱动器。所有cdr都具有相同的设计,包括用于数据判断的触发器,用于旁路模式操作的选择器,potbacker型相频检测器(PFD)[1],电荷泵(CP),滞后滤波器和正交LC-VCO (QVCO)。旁路模式时,话单环路设置为下电模式,使VCO不振荡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
22.7 4×25.78Gb/s retimer ICs for optical links in 0.13μm SiGe BiCMOS
To meet increasing demands for server computational power, high-density, multilane links with a data rate exceeding 25Gb/s/lane are needed. An optical transceiver with a retiming capability would significantly enhance the usability of the link by extending the reach. Such optical transceivers should operate without an external clock source since a small form factor is imperative. The optical link we develop has a four-lane configuration that consists of an electrical-to-optical (E/O) converter and an optical-to-electrical (O/E) convertor (Fig. 22.7.1). Both the E/O and O/E convertors are equipped with a per-lane reference-less clock-and-data recovery (CDR) circuit that enables independent operation of each lane. The transceiver pitch is 250μm/lane, which matches the fiber pitch of the optical-fiber array used in the link. Since the jitter added by the CDR should be minimized in retimer applications, an LC-VCO is a preferable choice for clock-signal generation. At this transceiver pitch, however, the coupling through mutual inductances between LC tanks has a significant impact on the CDR characteristics. To address this concern, we analyze the impact of inter-VCO coupling and design the CDR so that the coupling does not affect the CDR performance. Each lane of the E/O convertor consists of a continuous-time linear equalizer (CTLE), a CDR, and a VCSEL driver with a two-tap feed-forward equalizer (FFE) (Fig. 22.7.1). Each lane of the O/E convertor has a trans-impedance amplifier (TIA) stage followed by a limiting amplifier (LA), a CDR, and an electrical-line driver with a two-tap FFE. All the CDRs have an identical design consisting of a flip-flop for the data decision, a selector for bypass-mode operation, a Pottbacker type phase-frequency detector (PFD) [1], a charge pump (CP), a lag-lead filter, and a quadrature LC-VCO (QVCO). During the bypass mode, the CDR loop is set into a power-down mode where the VCO does not oscillate.
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