28.2 A 0.29mm2 frequency synthesizer in 40nm CMOS with 0.19psrms jitter and <-100dBc reference spur for 802.11ac

Conventional analog PLLs do not scale well with process when compared to all-digital PLLs due to several substantial building blocks such as the loop filter and charge pump (CP). To achieve the required phase noise, the in-band noise is typically suppressed by increasing CP current and loop filter s...

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Main Authors: Yu-Li Hsueh, Lan-Chou Cho, Chih-Hsien Shen, Yi-Chien Tsai, Tzu-Chan Chueh, Tao-Yao Chang, Jui-Lin Hsu, Zhan, Jing-Hong Conan
Format: Conference Proceeding
Language:English
Subjects:
Capacitors
Clocks
Delays
Inductors
Noise
Phase locked loops
Voltage-controlled oscillators
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creator Yu-Li Hsueh
Lan-Chou Cho
Chih-Hsien Shen
Yi-Chien Tsai
Tzu-Chan Chueh
Tao-Yao Chang
Jui-Lin Hsu
Zhan, Jing-Hong Conan
description Conventional analog PLLs do not scale well with process when compared to all-digital PLLs due to several substantial building blocks such as the loop filter and charge pump (CP). To achieve the required phase noise, the in-band noise is typically suppressed by increasing CP current and loop filter size, while the out-of-band noise is reduced by improving VCO tank Q; both lead to increased die area. This paper presents a fractional-N synthesizer targeting the relatively stringent phase noise requirement to support 256-QAM and MIMO in 802.11ac. It deploys the following techniques to simultaneously address requirements of compact area, low noise and fast calibration: reuse of VCO inductor area for the loop filter; a PFD and CP design that relaxes CP design constraints without sacrificing noise; inductor-less LO generation for 802.11bgn mode; and an area-efficient reference clock doubler and associated calibration scheme. The synthesizer block diagram is shown in Fig. 28.2.1. In 802.11ac/a mode a frequency tripler followed by I/Q dividers realizes the 3/2 frequency multiplication and I/Q generation. In 802.11bgn mode, an LO generation circuit performs the 2/3 frequency multiplication and I/Q generation. This frequency plan features overlapping VCO tuning ranges between 802.11ac/a (F LO =4915~5825MHz) and 802.11bgn (F LO =2412~2484MHz) modes, such that the VCO designed for 802.11ac/a can support 802.11bgn without additional tuning range.
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To achieve the required phase noise, the in-band noise is typically suppressed by increasing CP current and loop filter size, while the out-of-band noise is reduced by improving VCO tank Q; both lead to increased die area. This paper presents a fractional-N synthesizer targeting the relatively stringent phase noise requirement to support 256-QAM and MIMO in 802.11ac. It deploys the following techniques to simultaneously address requirements of compact area, low noise and fast calibration: reuse of VCO inductor area for the loop filter; a PFD and CP design that relaxes CP design constraints without sacrificing noise; inductor-less LO generation for 802.11bgn mode; and an area-efficient reference clock doubler and associated calibration scheme. The synthesizer block diagram is shown in Fig. 28.2.1. In 802.11ac/a mode a frequency tripler followed by I/Q dividers realizes the 3/2 frequency multiplication and I/Q generation. In 802.11bgn mode, an LO generation circuit performs the 2/3 frequency multiplication and I/Q generation. This frequency plan features overlapping VCO tuning ranges between 802.11ac/a (F LO =4915~5825MHz) and 802.11bgn (F LO =2412~2484MHz) modes, such that the VCO designed for 802.11ac/a can support 802.11bgn without additional tuning range.</abstract><pub>IEEE</pub><doi>10.1109/ISSCC.2014.6757518</doi></addata></record>
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source IEEE Xplore All Conference Series
subjects Capacitors
Clocks
Delays
Inductors
Noise
Phase locked loops
Voltage-controlled oscillators
title 28.2 A 0.29mm2 frequency synthesizer in 40nm CMOS with 0.19psrms jitter and <-100dBc reference spur for 802.11ac
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