TY - GEN
T1 - A 1.68-23.2 Gb/s Reference-Less Half-Rate Receiver with an ISI-Tolerant Unlimited Range Frequency Detector
AU - Huang, Yu Ping
AU - Chang, Yi Wei
AU - Chen, Wei Zen
N1 - Publisher Copyright:
© 2021 IEEE.
PY - 2021
Y1 - 2021
N2 - The data rates of high speed serial link keep increasing in the past decades. To accommodate multi-standard and legacy mode operation, there is a need for a high speed receiver providing wide range and continuous rate operation, which is difficult to achieve. Limited by the frequency capture range of the CDR, an auxiliary frequency locked loop (FLL) is commonly used for a broad band operation. An FLL with a reference/crystal input is a common approach for a reliable operation. To provide the merits of low cost and small form factor for system integration, reference-less CDRs have drawn the attention of many researchers recently [1]-[5]. There are two conventional approaches to accomplish reference-less CDRs. One is based on a modified quadri-correlator architecture, which tries to detect the fast/slow frequency offset based on the sampling phase rotation [2][3], and blocks the inefficacious indicators when the sampling phases cross two quadrants. Under ISI channels where the data edge is smeared out, frequency detection based on sampling phase rotation becomes unreliable if the data edge is not properly equalized. Another approach to reference-less frequency detectors uses stochastic divider or fast/slow histograms to detect frequency offset[1][5]. A posteriori knowledge of the data pattern, transition density, and channel characteristics are required to properly setup the threshold and weighting coefficients of the frequency detectors. To overcome the aforementioned shortcomings and design challenges, this paper presents a pulse-width based frequency detector, which provides unlimited range frequency detection. To the author's best knowledge, the proposed high speed receiver, which consists of CTLE, DFE, and CDR, demonstrates the broadest operation range (13.8X) as are reported to date.
AB - The data rates of high speed serial link keep increasing in the past decades. To accommodate multi-standard and legacy mode operation, there is a need for a high speed receiver providing wide range and continuous rate operation, which is difficult to achieve. Limited by the frequency capture range of the CDR, an auxiliary frequency locked loop (FLL) is commonly used for a broad band operation. An FLL with a reference/crystal input is a common approach for a reliable operation. To provide the merits of low cost and small form factor for system integration, reference-less CDRs have drawn the attention of many researchers recently [1]-[5]. There are two conventional approaches to accomplish reference-less CDRs. One is based on a modified quadri-correlator architecture, which tries to detect the fast/slow frequency offset based on the sampling phase rotation [2][3], and blocks the inefficacious indicators when the sampling phases cross two quadrants. Under ISI channels where the data edge is smeared out, frequency detection based on sampling phase rotation becomes unreliable if the data edge is not properly equalized. Another approach to reference-less frequency detectors uses stochastic divider or fast/slow histograms to detect frequency offset[1][5]. A posteriori knowledge of the data pattern, transition density, and channel characteristics are required to properly setup the threshold and weighting coefficients of the frequency detectors. To overcome the aforementioned shortcomings and design challenges, this paper presents a pulse-width based frequency detector, which provides unlimited range frequency detection. To the author's best knowledge, the proposed high speed receiver, which consists of CTLE, DFE, and CDR, demonstrates the broadest operation range (13.8X) as are reported to date.
UR - http://www.scopus.com/inward/record.url?scp=85124050324&partnerID=8YFLogxK
U2 - 10.1109/A-SSCC53895.2021.9634752
DO - 10.1109/A-SSCC53895.2021.9634752
M3 - Conference contribution
AN - SCOPUS:85124050324
T3 - Proceedings - A-SSCC 2021: IEEE Asian Solid-State Circuits Conference
BT - Proceedings - A-SSCC 2021
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2021 IEEE Asian Solid-State Circuits Conference, A-SSCC 2021
Y2 - 7 November 2021 through 10 November 2021
ER -