E. Mensink scite author profile

Abstract-Global on-chip data communication is becoming a concern as the gap between transistor speed and interconnect bandwidth increases with CMOS process scaling. Repeaters can partly bridge this gap, but the classical repeater insertion approach requires a large number of repeaters while the intrinsic data capacity of each interconnect-segment is only partially used. In this paper we analyze interconnects and show how a combination of layout, termination and equalization techniques can significantly increase the data rate for a given length of uninterrupted interconnect. To validate these techniques, a bus-transceiver test chip in a 0.13-m, 1.2-V, 6-M copper CMOS process has been designed. The chip uses 10-mm-long differential interconnects with wire widths and spacing of only 0.4 m. Differential interconnects are insensitive to common-mode disturbances (e.g., non-neighbor crosstalk) and enable the use of twists to mitigate neighbor-to-neighbor crosstalk. With transceivers operating in conventional mode, the chip achieves only 0.55 Gb/s/ch. The achievable data rate increases to 3 Gb/s/ch (consuming 2 pJ/bit) with a pulse-width pre-emphasis technique, used in combination with resistive termination.

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Low-Power, High-Speed Transceivers for Network-on-Chip Communication

Schinkel¹,

Mensink²,

Klumperink

et al. 2009

IEEE Trans. VLSI Syst.

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Networks on chips (NoCs) are becoming popular as they provide a solution for the interconnection problems on large integrated circuits (ICs). But even in a NoC, link-power can become unacceptably high and data rates are limited when conventional data transceivers are used. In this paper, we present a low-power, high-speed source-synchronous link transceiver which enables a factor 3.3 reduction in link power together with an 80% increase in data-rate. A low-swing capacitive pre-emphasis transmitter in combination with a double-tail sense-amplifier enable speeds in excess of 9 Gb/s over a 2 mm twisted differential interconnect, while consuming only 130 fJ/transition without the need for an additional supply. Multiple transceivers can be connected back-to-back to create a source-synchronous transceiver-chain with a wave-pipelined clock, operating with 6 offset reliability at 5 Gb/s. Index Terms-Capacitive pre-emphasis transmitter, globally asynchronous, locally synchronous (GALS), interconnect, low-power design, low-swing, network on chip (NoC), on-chip communication, source synchronous, wave-pipelining. I. INTRODUCTION O N-CHIP communication has become an active research area in the past few years. This not only because on-chip interconnects are becoming a speed, power, and reliability bottleneck [1], but also because systems on chips (SoCs) start to become so complex that they require new interconnection approaches [2], [3]. Networks on chips (NoCs) have emerged as the seemingly best candidate to connect the many functional elements on present and future SoCs [2]-[7]. Most of the long (global) interconnects, which have the severest bandwidth limitations and crosstalk problems, are eliminated in a NoC, especially when mesh-like network configurations are used. An NoC also enables easier clock-distribution with alleviated skew requirements and less power consumption as the various processing elements can operate mesochronous [4]-[6] or asynchronous

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A 0.28pJ/b 2Gb/s/ch Transceiver in 90nm CMOS for 10mm On-Chip interconnects

Mensink

Schinkel

Klumperink

et al. 2007

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ISSCC 2007 / SESSION 22 / DIGITAL CIRCUIT INNOVATIONS / 22.9 22.9 A 0.28pJ/b 2Gb/s/ch Transceiver in 9Onm CMOS The schematic of the receiver implementation is shown in Fig. for 10mm On-Chip interconnects Fig. 22.9.2). TheThe bandwidth of global on-chip interconnects in modern CMOS total area of the receiver is 117 gm2 (324m2 for the DFE part) processes is limited by their high resistance and capacitance [1]. Repeaters that are used to speed up these interconnects consume The chip micrograph is shown in Fig. 22.9

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Distortion cancellation by polyphase multipath circuits

Mensink

Klumperink

Nauta

2005

IEEE Trans. Circuits Syst. I

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It is well known that in balanced (or differential) circuits, all even harmonics are canceled. This cancellation is achieved by using two paths and exploiting phase differences of 180 between the paths. The question addressed in this paper is: what distortion products (harmonics and intermodulation products) are canceled if more than two paths (and phases) are used? These circuits are called polyphase multipath circuits. It turns out that the more paths (and phases) are used, the more distortion products are canceled. Unfortunately, some intermodulation products cannot be canceled without also canceling the desired signal. An analysis of the impact of mismatch between the paths shows that the suppression of distortion products will be larger if more paths are used. As an application example, the design of an upconversion mixer with a clean output spectrum is presented.

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E. Mensink

A Double-Tail Latch-Type Voltage Sense Amplifier with 18ps Setup+Hold Time

A 3-Gb/s/ch Transceiver for 10-mm Uninterrupted RC-Limited Global On-Chip Interconnects

Low-Power, High-Speed Transceivers for Network-on-Chip Communication

A 0.28pJ/b 2Gb/s/ch Transceiver in 90nm CMOS for 10mm On-Chip interconnects

Distortion cancellation by polyphase multipath circuits

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