Candidate: Michael Wright
Date: August 18, 2023
Time: 2:00pm
Location: EIT 3145
Supervisor(s): Peter Levine and Ahmet Camlica
Abstract
Digital X-ray imagers for clinical mammography and computed tomography (CT) have recently been taking advantage of the noise rejection provided by single-photon-counting (SPC) architectures. However, conventional SPC imagers are limited in spatial and energy resolution due to the substantial circuit area required to accommodate signal processing and digitization in each pixel. To enable higher spatial resolution using smaller pixels, while simultaneously increasing energy resolution for multi-spectral imaging, new circuit architectures are required for SPC X-ray imagers.
This thesis presents the design and experimental characterization of the first comple- mentary metal-oxide-semiconductor (CMOS) SPC X-ray imager readout integrated circuit (ROIC) to use frequency-division-multiplexed (FDM) readout for improved spatial and spectral resolution. FDM readout allows the pixels in our ROIC to share analog-to-digital converter (ADC) resources, so that fewer component blocks are integrated in each pixel. This enables us to shrink the pixel area, improving spatial resolution. Shared ADCs also have higher resolution than those in conventional implementations, enabling higher overall energy resolution.
Our proposed ROIC, designed in a 180-nm CMOS technology, includes an 8 × 16 pixel array and 16 ADCs. To achieve high spatial resolution and sufficient count rate for mam- mography and CT applications, we design our pixels with an area of only 35 × 35 μm2, approximately 50% smaller than commercial SPC imagers. Our ROIC uses FDM read- out to multiplex banks of eight pixels into a shared 8-bit 160-MHz-sample-rate pipelined ADC, enabling full digitization of pixel analog outputs. We achieve six bins of energy res- olution, which exceeds the resolution of recently-reported conventional SPC imagers that use larger-area pixels. Consequently, off-chip digital-signal processing for improved image construction can be applied. Our ROIC has a measured equivalent-noise charge (ENC) of 101e−rms, which is comparable to conventional imagers, and a maximum count-rate of 108 photons/mm2/s, suitable for mammography and CT.