Minyoung Song, Taeik Kim, Jihyun F. Kim, Wooseok Kim, Sung-Jin Kim, Hojin Park
{"title":"14.8 A 0.009mm2 2.06mW 32至2000mhz二阶ΔΣ模拟bang-bang数字锁相环,采用14nm FinFET技术,具有前馈锁相和锁相操作","authors":"Minyoung Song, Taeik Kim, Jihyun F. Kim, Wooseok Kim, Sung-Jin Kim, Hojin Park","doi":"10.1109/ISSCC.2015.7063028","DOIUrl":null,"url":null,"abstract":"The race to deep sub-micron CMOS technology has resulted in a change in device architectures, from a planar structure to a FinFET to achieve decreased leakage, further downscaling, and better sub-threshold slope, even under a lower power supply. Downscaling trends have forced the analog semiconductor industry to move to the digital domain to maintain functionality in light of increasing short-channel effects and device mismatch. Furthermore, the main goal of the new technology is to achieve faster speed and lower cost. In leading-edge processes and design environments, conventional analog PLLs in systems-on-chip (SoCs) are being replaced by digitally operated PLLs to meet clock requirements for optimal overall system performance. While a widely used time-to-digital converter (TDC)-based digital PLL (TDC-DPLL) has a linear loop characteristic, which is simple and analogous to well-known analog PLLs, it has to overcome noise issues from TDC quantization error and phase noise from the digitally-controlled oscillator (DCO). The in-band noise floor of a TDC-DPLL is determined by the TDC resolution. Thanks to noise shaping techniques with oversampling and a pipelined architecture, noise performance can be improved. However, significant area and power must be spent to meet noise requirements. A bang-bang-based digital PLL (BB-DPLL), as the alternative type of DPLL has advantages in terms of area and power over a TDC-DPLL. However, its non-linear operation implies a longer lock time, limit-cycle noise, and high sensitivity to DCO noise. In addition, the in-band noise floor of a BB-DPLL is dominated by the input-tracking jitter, which mainly arises from the DCO noise. This paper presents a BB-DPLL in 14nm FinFET technology, combining a feed-forward delay-locked part (FFDLP) and phase-locked part (PLP) to mitigate aforementioned weaknesses.","PeriodicalId":188403,"journal":{"name":"2015 IEEE International Solid-State Circuits Conference - (ISSCC) Digest of Technical Papers","volume":"35 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2015-03-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"7","resultStr":"{\"title\":\"14.8 A 0.009mm2 2.06mW 32-to-2000MHz 2nd-order ΔΣ analogous bang-bang digital PLL with feed-forward delay-locked and phase-locked operations in 14nm FinFET technology\",\"authors\":\"Minyoung Song, Taeik Kim, Jihyun F. Kim, Wooseok Kim, Sung-Jin Kim, Hojin Park\",\"doi\":\"10.1109/ISSCC.2015.7063028\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The race to deep sub-micron CMOS technology has resulted in a change in device architectures, from a planar structure to a FinFET to achieve decreased leakage, further downscaling, and better sub-threshold slope, even under a lower power supply. Downscaling trends have forced the analog semiconductor industry to move to the digital domain to maintain functionality in light of increasing short-channel effects and device mismatch. Furthermore, the main goal of the new technology is to achieve faster speed and lower cost. In leading-edge processes and design environments, conventional analog PLLs in systems-on-chip (SoCs) are being replaced by digitally operated PLLs to meet clock requirements for optimal overall system performance. While a widely used time-to-digital converter (TDC)-based digital PLL (TDC-DPLL) has a linear loop characteristic, which is simple and analogous to well-known analog PLLs, it has to overcome noise issues from TDC quantization error and phase noise from the digitally-controlled oscillator (DCO). The in-band noise floor of a TDC-DPLL is determined by the TDC resolution. Thanks to noise shaping techniques with oversampling and a pipelined architecture, noise performance can be improved. However, significant area and power must be spent to meet noise requirements. A bang-bang-based digital PLL (BB-DPLL), as the alternative type of DPLL has advantages in terms of area and power over a TDC-DPLL. However, its non-linear operation implies a longer lock time, limit-cycle noise, and high sensitivity to DCO noise. In addition, the in-band noise floor of a BB-DPLL is dominated by the input-tracking jitter, which mainly arises from the DCO noise. 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14.8 A 0.009mm2 2.06mW 32-to-2000MHz 2nd-order ΔΣ analogous bang-bang digital PLL with feed-forward delay-locked and phase-locked operations in 14nm FinFET technology
The race to deep sub-micron CMOS technology has resulted in a change in device architectures, from a planar structure to a FinFET to achieve decreased leakage, further downscaling, and better sub-threshold slope, even under a lower power supply. Downscaling trends have forced the analog semiconductor industry to move to the digital domain to maintain functionality in light of increasing short-channel effects and device mismatch. Furthermore, the main goal of the new technology is to achieve faster speed and lower cost. In leading-edge processes and design environments, conventional analog PLLs in systems-on-chip (SoCs) are being replaced by digitally operated PLLs to meet clock requirements for optimal overall system performance. While a widely used time-to-digital converter (TDC)-based digital PLL (TDC-DPLL) has a linear loop characteristic, which is simple and analogous to well-known analog PLLs, it has to overcome noise issues from TDC quantization error and phase noise from the digitally-controlled oscillator (DCO). The in-band noise floor of a TDC-DPLL is determined by the TDC resolution. Thanks to noise shaping techniques with oversampling and a pipelined architecture, noise performance can be improved. However, significant area and power must be spent to meet noise requirements. A bang-bang-based digital PLL (BB-DPLL), as the alternative type of DPLL has advantages in terms of area and power over a TDC-DPLL. However, its non-linear operation implies a longer lock time, limit-cycle noise, and high sensitivity to DCO noise. In addition, the in-band noise floor of a BB-DPLL is dominated by the input-tracking jitter, which mainly arises from the DCO noise. This paper presents a BB-DPLL in 14nm FinFET technology, combining a feed-forward delay-locked part (FFDLP) and phase-locked part (PLP) to mitigate aforementioned weaknesses.
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