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Hauptverfasser: Wei, Xiaomin, Xu, Zijun, Lu, Weiguo, Zhou, Yang, Shi, Zhan, Li, Leyi, Zhang, Xiaoxu, Li, Pengxu, Deng, Jianpeng, Chen, Yang, Wang, Yujie, Xiang, Zhiyu, Zhao, Mei, Zeng, Cheng, Cai, Mengke, Wang, Boxin, Cai, Yuman, Yan, Bingchen, Wang, Anqi, Zhao, Yu, Zhao, Zexuan, Wei, Zheng, Wu, Huimin, Zhao, Ruiguang, Zhu, Hongbo, Hu, Yongcai, Wang, Jianchun, Li, Yiming
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.17346
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author Wei, Xiaomin
Xu, Zijun
Lu, Weiguo
Zhou, Yang
Shi, Zhan
Li, Leyi
Zhang, Xiaoxu
Li, Pengxu
Deng, Jianpeng
Chen, Yang
Wang, Yujie
Xiang, Zhiyu
Zhao, Mei
Zeng, Cheng
Cai, Mengke
Wang, Boxin
Cai, Yuman
Yan, Bingchen
Wang, Anqi
Zhao, Yu
Zhao, Zexuan
Wei, Zheng
Wu, Huimin
Zhao, Ruiguang
Zhu, Hongbo
Hu, Yongcai
Wang, Jianchun
Li, Yiming
author_facet Wei, Xiaomin
Xu, Zijun
Lu, Weiguo
Zhou, Yang
Shi, Zhan
Li, Leyi
Zhang, Xiaoxu
Li, Pengxu
Deng, Jianpeng
Chen, Yang
Wang, Yujie
Xiang, Zhiyu
Zhao, Mei
Zeng, Cheng
Cai, Mengke
Wang, Boxin
Cai, Yuman
Yan, Bingchen
Wang, Anqi
Zhao, Yu
Zhao, Zexuan
Wei, Zheng
Wu, Huimin
Zhao, Ruiguang
Zhu, Hongbo
Hu, Yongcai
Wang, Jianchun
Li, Yiming
contents Motivated by the stringent requirements of the Upstream Pixel (UP) tracker in the LHCb Upgrade II and the Inner Tracking detector (ITK) of the Circular Electron Positron Collider, the COFFEE series of pixel sensor chips have been developed using a 55nm High-Voltage CMOS (HVCMOS) process. The primary objective is to achieve a time resolution of a few nanoseconds under a hit density of up to 100 MHz/cm$^2$, while maintaining fine spatial resolution ($\sim$10 $μ$m) and reasonable power consumption ($<$200 mW/cm$^2$). Building on the process validation of the COFFEE2 prototype, this work presents the design and preliminary test results of COFFEE3-a prototype integrating two distinct readout architectures. Architecture 1, tailored for the current triple-well process, adopts NMOS-only in-pixel circuitry and innovative column-level readout to handle high hit densities. The time walk of pixel-level signal is controlled within 10 ns, and the Time of Arrival (TOA) and Time over Threshold (TOT) are measured with a system clock with the period of 25 ns in peripheral circuits. Architecture 2, developed for future possible processes with p-type buried layer isolation, features pixel-level time measurement and storage. A chip-level Time-to-Digital Converter (TDC) is used and the part of Voltage-Controlled Delay Line (VCDL) is copied in each pixel to get a high time resolution. The TOA resolution is estimated to be 4.2 ns and the TOT resolution 8.4 ns. COFFEE3, with a layout size of 3$\times$4 mm$^2$, was manufactured and has undergone preliminary tests. Charge injection tests for analog circuits, and laser tests for full readout chains, confirm that both architectures operate as expected. Next step work will focus on characterizing key performance such as the timing resolution, radiation hardness, and tracking performance of minimum ionising particles.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17346
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Design and First Results of COFFEE3: A 55nm HVCMOS Pixel Sensor Prototype for High-Energy Physics Applications
Wei, Xiaomin
Xu, Zijun
Lu, Weiguo
Zhou, Yang
Shi, Zhan
Li, Leyi
Zhang, Xiaoxu
Li, Pengxu
Deng, Jianpeng
Chen, Yang
Wang, Yujie
Xiang, Zhiyu
Zhao, Mei
Zeng, Cheng
Cai, Mengke
Wang, Boxin
Cai, Yuman
Yan, Bingchen
Wang, Anqi
Zhao, Yu
Zhao, Zexuan
Wei, Zheng
Wu, Huimin
Zhao, Ruiguang
Zhu, Hongbo
Hu, Yongcai
Wang, Jianchun
Li, Yiming
Instrumentation and Detectors
Motivated by the stringent requirements of the Upstream Pixel (UP) tracker in the LHCb Upgrade II and the Inner Tracking detector (ITK) of the Circular Electron Positron Collider, the COFFEE series of pixel sensor chips have been developed using a 55nm High-Voltage CMOS (HVCMOS) process. The primary objective is to achieve a time resolution of a few nanoseconds under a hit density of up to 100 MHz/cm$^2$, while maintaining fine spatial resolution ($\sim$10 $μ$m) and reasonable power consumption ($<$200 mW/cm$^2$). Building on the process validation of the COFFEE2 prototype, this work presents the design and preliminary test results of COFFEE3-a prototype integrating two distinct readout architectures. Architecture 1, tailored for the current triple-well process, adopts NMOS-only in-pixel circuitry and innovative column-level readout to handle high hit densities. The time walk of pixel-level signal is controlled within 10 ns, and the Time of Arrival (TOA) and Time over Threshold (TOT) are measured with a system clock with the period of 25 ns in peripheral circuits. Architecture 2, developed for future possible processes with p-type buried layer isolation, features pixel-level time measurement and storage. A chip-level Time-to-Digital Converter (TDC) is used and the part of Voltage-Controlled Delay Line (VCDL) is copied in each pixel to get a high time resolution. The TOA resolution is estimated to be 4.2 ns and the TOT resolution 8.4 ns. COFFEE3, with a layout size of 3$\times$4 mm$^2$, was manufactured and has undergone preliminary tests. Charge injection tests for analog circuits, and laser tests for full readout chains, confirm that both architectures operate as expected. Next step work will focus on characterizing key performance such as the timing resolution, radiation hardness, and tracking performance of minimum ionising particles.
title Design and First Results of COFFEE3: A 55nm HVCMOS Pixel Sensor Prototype for High-Energy Physics Applications
topic Instrumentation and Detectors
url https://arxiv.org/abs/2603.17346