All-digital fast-locking pulsewidth-control circuit with programmable duty cycle

Jun Ren Su; Te Wen Liao; Chung-Chih Hung

doi:10.1109/TVLSI.2012.2205168

All-digital fast-locking pulsewidth-control circuit with programmable duty cycle

Jun Ren Su, Te Wen Liao, Chung-Chih Hung

Department of Electrical and Computer Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This paper proposes an all-digital fast-locking pulsewidth-control circuit with programmable duty cycle. In comparison with prior state-of-the-art methods, our use of two delay lines and a time-to-digital detector allows the pulsewidth-control circuit to operate over a wide frequency range with fewer delay cells, while maintaining the same level of accuracy. This paper presents a new duty-cycle setting circuit that calculates the desired output duty cycle without the need for a look-up table. The circuit was fabricated under the two-stage matrix converter 0.18-μrm m CMOS process. Results show that the proposed circuit performs well for an input operating frequency ranging from 200 to 600 MHz, and an input duty cycle ranging from 30% to 70%. It achieves a programmable output duty cycle ranging from 31.25% to 68.75% in increments of 6.25%.

Original language	English
Article number	6239644
Pages (from-to)	1154-1164
Number of pages	11
Journal	IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Volume	21
Issue number	6
DOIs	https://doi.org/10.1109/TVLSI.2012.2205168
State	Published - 3 Jun 2013

Keywords

Duty-cycle setting circuit
fast-locking
programmable duty cycle
pulsewidth-control circuit

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10.1109/TVLSI.2012.2205168

Cite this

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title = "All-digital fast-locking pulsewidth-control circuit with programmable duty cycle",

abstract = "This paper proposes an all-digital fast-locking pulsewidth-control circuit with programmable duty cycle. In comparison with prior state-of-the-art methods, our use of two delay lines and a time-to-digital detector allows the pulsewidth-control circuit to operate over a wide frequency range with fewer delay cells, while maintaining the same level of accuracy. This paper presents a new duty-cycle setting circuit that calculates the desired output duty cycle without the need for a look-up table. The circuit was fabricated under the two-stage matrix converter 0.18-μrm m CMOS process. Results show that the proposed circuit performs well for an input operating frequency ranging from 200 to 600 MHz, and an input duty cycle ranging from 30% to 70%. It achieves a programmable output duty cycle ranging from 31.25% to 68.75% in increments of 6.25%.",

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AB - This paper proposes an all-digital fast-locking pulsewidth-control circuit with programmable duty cycle. In comparison with prior state-of-the-art methods, our use of two delay lines and a time-to-digital detector allows the pulsewidth-control circuit to operate over a wide frequency range with fewer delay cells, while maintaining the same level of accuracy. This paper presents a new duty-cycle setting circuit that calculates the desired output duty cycle without the need for a look-up table. The circuit was fabricated under the two-stage matrix converter 0.18-μrm m CMOS process. Results show that the proposed circuit performs well for an input operating frequency ranging from 200 to 600 MHz, and an input duty cycle ranging from 30% to 70%. It achieves a programmable output duty cycle ranging from 31.25% to 68.75% in increments of 6.25%.

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All-digital fast-locking pulsewidth-control circuit with programmable duty cycle

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