Quantum Performance Analysis of an EMCCD-based X-ray Detector Using Photon Transfer Technique.

Bin Qu, Andrew T Kuhls-Gilcrist, Ying Huang, Weiyuan Wang, Alexander N Cartwright, Albert H Titus, Daniel R Bednarek, Stephen Rudin
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引用次数: 3

Abstract

The low electronic noise, high resolution, and good temporal performance of electron-multiplying CCDs (EMCCDs) are ideally suited for applications traditionally served by x-ray image intensifiers. In order to improve an expandable clinical detector's field-of-view and have full control of the system performance, we have successfully built a solid-state x-ray detector. The photon transfer technique was used to quantify the EMCCD quantum performance in terms of sensitivity (or camera gain constant, K), read noise (RN), full-well capacity (FW), and dynamic range (DR). Measured results show the system maintains a K of 11.3 ± 0.9 e(-)/DN at unit gain, with a read noise of 71.5±6.0 e(-)rms at gain 1, which decreases proportionally with higher gains. The full well capacity was measured to be 31.3±2.7 ke(-), providing a dynamic range of 52.8±0.7 dB using the chip manufacturer specified clocking scheme. Similar performance was measured with other commercial camera systems. The manufacturer data sheet indicates a dynamic range of 66 dB is plausible with improved read noise and full well capacity. Different clocking schemes are under investigation to assess their impact on improving performance towards idealized values. EMCCD driver clock voltage levels were adjusted individually to check the influence on quantum performance. The clocks work to transfer charge from the image area to readout amplifier through the storage area, horizontal and multiplication registers. Results indicate that the clock that contributes to lateral overflow drain bias is essential to the system performance in terms of dynamic range and full well capacity. The serial register clocks used for transporting charge stored in the pixels of the memory lines to the output amplifier had the largest effect on RN, while others had less of an impact. Initial adjustment of these clocks resulted in a variability of 16% in the performance of dynamic range, 38% in read noise and 56% in full well capacity. Quantifying the quantum performance provides valuable insight into overall performance and enables optimal adjustment of the clocking scheme. Further improvements are expected.

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基于光子转移技术的emccd x射线探测器的量子性能分析。
电子倍增ccd (emccd)具有低电子噪声、高分辨率和良好的时间性能,非常适合传统的x射线图像增强器应用。为了提高可扩展的临床探测器的视场,并完全控制系统的性能,我们成功地构建了一个固态x射线探测器。利用光子转移技术,从灵敏度(或相机增益常数K)、读取噪声(RN)、全阱容量(FW)和动态范围(DR)等方面量化了EMCCD的量子性能。测量结果表明,该系统在单位增益下的K值为11.3±0.9 e(-)/DN,在增益1时的读噪声为71.5±6.0 e(-)rms,随增益的增加而成比例降低。全井容量测量为31.3±2.7 ke(-),使用芯片制造商指定的时钟方案,提供52.8±0.7 dB的动态范围。其他商用相机系统也测量了类似的性能。制造商数据表表明,在改善读取噪声和全井容量的情况下,66 dB的动态范围是可行的。目前正在调查不同的计时方案,以评估它们对提高性能、实现理想值的影响。分别调整EMCCD驱动时钟电压电平,检查对量子性能的影响。时钟通过存储区、水平寄存器和乘法寄存器将电荷从图像区转移到读出放大器。结果表明,从动态范围和满井容量的角度来看,导致横向溢流漏偏置的时钟对系统性能至关重要。用于将存储在存储器线像素中的电荷传输到输出放大器的串行寄存器时钟对RN的影响最大,而其他寄存器的影响较小。这些时钟的初始调整导致动态范围性能的变化为16%,读取噪声的变化为38%,满井容量的变化为56%。量化量子性能提供了对整体性能的有价值的见解,并使时钟方案的最佳调整成为可能。预计会有进一步的改进。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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