Chih-Kong Ken Yang scite author profile

A dvances in IC fabrication technology, coupled with aggressive circuit design, have led to exponential growth of IC speed and integration levels. For these improvements to benefit overall system performance, the communication bandwidth between systems and ICs must scale accordingly. Currently, communication links in various applications approach Gbps data rates. These applications include computer-to-peripheral connections, 1 local area networks, 2 memory buses, 3 and multiprocessor interconnection networks. 4 Designers are concerned that these links will soon reach the fundamental limits of electrical signaling. In this article, we examine the limitations of CMOS implementations of highspeed links and show that the links' performance should continue to scale with technology. To handle the interconnects' finite bandwidth, however, requires more sophisticated signaling methods. CMOS circuits, typically slower than circuits implemented in nonmainstream technologies, are particularly attractive for common applications because of their lower cost. The overall system cost is further reduced when signaling components are implemented as macro cells, integrated on the same die with a microprocessor or signal processing block. For this reason, we do not address bipolar or GaAs Gbps links.

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Fast frequency acquisition phase-frequency detectors for Gsamples/s phase-locked loops

Mansuri¹,

Liu

Yang

2002

IEEE J. Solid-State Circuits

148

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A low-power adaptive bandwidth PLL and clock buffer with supply-noise compensation

Mansuri

Yang

2003

IEEE J. Solid-State Circuits

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This paper describes a fully integrated low-jitter CMOS phase-locked loop and clock buffer for low-power digital systems with a wide range of operating frequencies. The design uses static CMOS inverters as a building block of the voltage-controlled oscillator and clock buffering. To reduce supply-induced jitter, programmable circuits with opposite sensitivity compensate for the delay variations. Both elements have supply-induced delay sensitivity of 0 1% delay 1% DD. The design is fabricated in 0.25m CMOS technology and consumes 10 mW from a 2.5-V supply. The experimental results verify that the proposed methods significantly improve the jitter.

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Offset compensation in comparators with minimum input-referred supply noise

Wong

Yang

2004

IEEE J. Solid-State Circuits

100

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