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Hauptverfasser: Li, Qicai, Liu, Hongbin, Jiang, Xingfen, Zhou, Jianrong, Zhou, Yujie, Guo, Haoran, Cai, Dongcheng, Gong, Weile, Yuan, Yimie, Zhang, Chengshuo, Wang, Shengxiang, Zhao, Yubin, Sun, Zhijia
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.09534
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author Li, Qicai
Liu, Hongbin
Jiang, Xingfen
Zhou, Jianrong
Zhou, Yujie
Guo, Haoran
Cai, Dongcheng
Gong, Weile
Yuan, Yimie
Zhang, Chengshuo
Wang, Shengxiang
Zhao, Yubin
Sun, Zhijia
author_facet Li, Qicai
Liu, Hongbin
Jiang, Xingfen
Zhou, Jianrong
Zhou, Yujie
Guo, Haoran
Cai, Dongcheng
Gong, Weile
Yuan, Yimie
Zhang, Chengshuo
Wang, Shengxiang
Zhao, Yubin
Sun, Zhijia
contents The upgrade of the China Spallation Neutron Source (CSNS-II) will raise the proton beam power to 500 kW. Consequently, the existing Timepix3-based detector systems, limited to a count rate of 80 Mhits/s, will encounter severe saturation challenges. To address the demand of the Energy-Resolved Neutron Imaging instrument (ERNI) for next-generation higher count-rate electronics, this paper presents CTPX1, a high-performance data-driven camera system based on the Timepix4 ASIC. The system adopts a compact modular architecture, integrating readout electronics, a precision high-voltage bias unit, and a TEC temperature control subsystem. To fully exploit the readout potential of the Timepix4 ASIC's 16 high-speed serial links, this paper proposes a two-stage parallel processing architecture. This architecture achieves real-time data aggregation with a total bandwidth of up to 81.92 Gbps. Over a continuous 12-hour operation period, temperature fluctuations were kept within 0.1 °C while the high-voltage output noise remained below 1 mV. High-flux X-ray testing indicates that the system achieves a peak event readout rate of 1.17 Ghits/s, approaching the limit of the configured link speed. In-beam neutron verification at CSNS confirms that the camera successfully resolves fine spatial structures, achieving an imaging performance consistent with the 55 μm pixel pitch of the sensor. Furthermore, the clear observation of spectral features in the Time of flight (TOF) spectrum of a γ-Fe sample validates the system's good time resolution. This camera effectively addresses the data readout saturation challenges, validates the feasibility of Timepix4 technology for neutron imaging, and provides a viable solution for next-generation high-performance neutron imaging instruments.
format Preprint
id arxiv_https___arxiv_org_abs_2603_09534
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CTPX1: A Highly Integrated and High-Throughput Data-Driven Camera Based on Timepix4
Li, Qicai
Liu, Hongbin
Jiang, Xingfen
Zhou, Jianrong
Zhou, Yujie
Guo, Haoran
Cai, Dongcheng
Gong, Weile
Yuan, Yimie
Zhang, Chengshuo
Wang, Shengxiang
Zhao, Yubin
Sun, Zhijia
Instrumentation and Detectors
The upgrade of the China Spallation Neutron Source (CSNS-II) will raise the proton beam power to 500 kW. Consequently, the existing Timepix3-based detector systems, limited to a count rate of 80 Mhits/s, will encounter severe saturation challenges. To address the demand of the Energy-Resolved Neutron Imaging instrument (ERNI) for next-generation higher count-rate electronics, this paper presents CTPX1, a high-performance data-driven camera system based on the Timepix4 ASIC. The system adopts a compact modular architecture, integrating readout electronics, a precision high-voltage bias unit, and a TEC temperature control subsystem. To fully exploit the readout potential of the Timepix4 ASIC's 16 high-speed serial links, this paper proposes a two-stage parallel processing architecture. This architecture achieves real-time data aggregation with a total bandwidth of up to 81.92 Gbps. Over a continuous 12-hour operation period, temperature fluctuations were kept within 0.1 °C while the high-voltage output noise remained below 1 mV. High-flux X-ray testing indicates that the system achieves a peak event readout rate of 1.17 Ghits/s, approaching the limit of the configured link speed. In-beam neutron verification at CSNS confirms that the camera successfully resolves fine spatial structures, achieving an imaging performance consistent with the 55 μm pixel pitch of the sensor. Furthermore, the clear observation of spectral features in the Time of flight (TOF) spectrum of a γ-Fe sample validates the system's good time resolution. This camera effectively addresses the data readout saturation challenges, validates the feasibility of Timepix4 technology for neutron imaging, and provides a viable solution for next-generation high-performance neutron imaging instruments.
title CTPX1: A Highly Integrated and High-Throughput Data-Driven Camera Based on Timepix4
topic Instrumentation and Detectors
url https://arxiv.org/abs/2603.09534