X-ray Performance Evaluation of the Dexela CMOS APS X-ray Detector Using Monochromatic Synchrotron Radiation in the Mammographic Energy Range

Konstantinidis, Anastasios; Szafraniec, Magdalena B.; Rigon, Luigi; Tromba, Giuliana; Dreossi, Diego; Sodini, Nicola; Liaparinos, P.; Naday, Steve; Gunn, Spencer; McArthur, Alan; Speller, Robert; Olivo, Alessandro

doi:10.1109/tns.2013.2276123

Cited by 28 publications

(56 citation statements)

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“…A polished W edge plate was attached to the detector surface at a small tilted angle (1.5 -3°) with respect to the detector rows or columns (Konstantinidis et al 2013, Zhao et al 2015b. At oblique projection angles, partial transmission of x-ray photons through the edge may affect the MTF.…”

Section: Methodsmentioning

confidence: 99%

“…Then the averaged ESF was differentiated to obtain the line spread function (LSF). The 1D presampling MTF in either x (horizontal MTF(u)) or y direction (vertical MTF(v)) was calculated from the fast Fourier transform (FFT) of the oversampled LSF (Fujita et al 1992, Konstantinidis et al 2013, Zhao et al 2015b. The horizontal presampling MTF at θ i is given by…”

Section: Methodsmentioning

confidence: 99%

“…where I(x j , y j , θ i ) is the corrected flat-field image at θ i within a 256 × 256 region of interest (ROI), S(x j , y j , θ i ) is a 2D second order polynomial fit for I(x j , y j , θ i ) to remove the low frequency trends, ∆x and ∆y are the pixel pitches in x and y directions (∆x = ∆y = 50 μm), M is the number of ROIs (M = 243 to reach at least three million independent pixels (IEC 62220-1-2: 2007)), N x and N y are the number of columns and rows in each ROI (N x = N y = 256) (IEC 62220-1-2: 2007, Konstantinidis et al 2013, Zhao et al 2015b. The 1D horizontal (NPS(u)) and vertical NPS (NPS(v)) were extracted and averaged from seven lines on either side of zero spatial frequency.…”

Section: Methodsmentioning

confidence: 99%

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Three-dimensional cascaded system analysis of a 50µm pixel pitch wafer-scale CMOS active pixel sensor x-ray detector for digital breast tomosynthesis

et al. 2017

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Abstract. High-resolution, low-noise x-ray detectors based on the complementary metal-oxide-semiconductor (CMOS) active pixel sensor (APS) technology have been developed and proposed for digital breast tomosynthesis (DBT). In this study, we evaluated the three-dimensional (3D) imaging performance of a 50 μm pixel pitch CMOS APS x-ray detector named DynAMITe (Dynamic Range Adjustable for Medical Imaging Technology). The two-dimensional (2D) angle-dependent modulation transfer function (MTF), normalized noise power spectrum (NNPS), and detective quantum efficiency (DQE) were experimentally characterized and modeled using the cascaded system analysis at oblique incident angles up to 30°. The cascaded system model was extended to the 3D spatial frequency space in combination with the filtered back-projection (FBP) reconstruction method to calculate the 3D and in-plane MTF, NNPS and DQE parameters. The results demonstrate that the beam obliquity blurs the 2D MTF and DQE in the high spatial frequency range. However, this effect can be eliminated after FBP image reconstruction. In addition, impacts of the image acquisition geometry and detector parameters were evaluated using the 3D cascaded system analysis for DBT. The result shows that a wider projection angle range (e.g. ±30°) improves the low spatial frequency (below 5 mm -1 ) performance of the CMOS APS detector. In addition, to maintain a high spatial resolution for DBT, a focal spot size of smaller than 0.3 mm should be used.Theoretical analysis suggests that a pixelated scintillator in combination with the 50 μm pixel pitch CMOS APS detector could further improve the 3D image resolution. Finally, the 3D imaging performance of the CMOS APS and an indirect amorphous silicon (a-Si:H) thin-film A c c e p t e d M a n u s c r i p t transistor (TFT) passive pixel sensor (PPS) detector was simulated and compared.Keywords: CMOS active pixel sensor, x-ray detector, digital breast tomosynthesis, three-dimensional, cascaded system analysis, pixelated scintillator, detective quantum efficiency IntroductionHigh performance x-ray detectors based on the complementary metal-oxide-semiconductor ( Up to now, most studies focus on CMOS APS detector evaluation by measuring the one-dimensional (1D) or 2D modulation transfer function (MTF), noise power spectrum (NPS) and detective quantum efficiency (DQE) using a single x-ray projection at the zero-degree incident angle (perpendicular to the detector). Nevertheless, since DBT is a quasi-three-dimensional (3D) imaging technology, the DBT image quality is influenced by the system geometry and reconstruction algorithms (Sechopoulos 2013a(Sechopoulos , 2013b. Therefore, the 3D imaging performance should be evaluated for the CMOS APS detectors. However, it is difficult to empirically investigate the 3D image quality. To deal with this issue, the 3D cascaded system analysis for CMOS APS detectors was developed and is presented in this study.Cascaded system analysis can accurately model the signal and noise propagation and blurring within ...

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Three-dimensional cascaded system analysis of a 50µm pixel pitch wafer-scale CMOS active pixel sensor x-ray detector for digital breast tomosynthesis

et al. 2017

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“…The dexel pitch at native binning mode is 75×75 µm with a typical fill factor of 84%. 15 The x-ray source, specifically designed for breast scanning purposes, is a water-cooled, rotating anode x-ray tube with a nominal focal spot size of 0.3 mm coupled with a 14 kW rad/pulse-rad x-ray generator (CMP200SE, CPI, Ontario, Canada). The x-ray focal spot distribution was measured with a 0.030 mm pinhole camera made from a 90:10 goldplatinum alloy (07-613, Nuclear Associates, Carle Place, NY).…”

Section: A1 Hardwarementioning

confidence: 99%

Evolution of spatial resolution in breast CT at UC Davis

et al. 2015

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Purpose: Dedicated breast computed tomography (bCT) technology for the purpose of breast cancer screening has been a focus of research at UC Davis since the late 1990s. Previous studies have shown that improvement in spatial resolution characteristics of this modality correlates with greater microcalcification detection, a factor considered a potential limitation of bCT. The aim of this study is to improve spatial resolution as characterized by the modulation transfer function (MTF) via changes in the scanner hardware components and operational schema. Methods: Four prototypes of pendant-geometry, cone-beam breast CT scanners were designed and developed spanning three generations of design evolution. To improve the system MTF in each bCT generation, modifications were made to the imaging components (x-ray tube and flat-panel detector), system geometry (source-to-isocenter and detector distance), and image acquisition parameters (technique factors, number of projections, system synchronization scheme, and gantry rotational speed). Results: Characterization of different generations of bCT systems shows these modifications resulted in a 188% improvement of the limiting MTF properties from the first to second generation and an additional 110% from the second to third. The intrinsic resolution degradation in the azimuthal direction observed in the first generation was corrected by changing the acquisition from continuous to pulsed x-ray acquisition. Utilizing a high resolution detector in the third generation, along with modifications made in system geometry and scan protocol, resulted in a 125% improvement in limiting resolution. An additional 39% improvement was obtained by changing the detector binning mode from 2 × 2 to 1 × 1. Conclusions: These results underscore the advancement in spatial resolution characteristics of breast CT technology. The combined use of a pulsed x-ray system, higher resolution flat-panel detector and changing the scanner geometry and image acquisition logic resulted in a significant fourfold improvement in MTF. C 2015 American Association of Physicists in Medicine.

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“…The X-ray performance evaluation of the detector has been tested with monochromatic synchrotron radiation in the mammographic energy range and reported in Ref. [11]. The authors measured the detective quantum efficiency (DQE), which ranges from 0.79 to 0.85 at a frequency of 0.5 lp/mm and at 17 keV and 0.75 to 0.79 at 20 keV.…”

Section: Prototype Detector Developed By Dexela Ltd (A Perkinelmer Comentioning

confidence: 99%

Synchrotron based planar imaging and digital tomosynthesis of breast and biopsy phantoms using a CMOS active pixel sensor

Szafraniec¹,

Konstantinidis²,

Tromba

et al. 2015

Physica Medica

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X-ray Performance Evaluation of the Dexela CMOS APS X-ray Detector Using Monochromatic Synchrotron Radiation in the Mammographic Energy Range

Cited by 28 publications

References 74 publications

Three-dimensional cascaded system analysis of a 50µm pixel pitch wafer-scale CMOS active pixel sensor x-ray detector for digital breast tomosynthesis

Three-dimensional cascaded system analysis of a 50µm pixel pitch wafer-scale CMOS active pixel sensor x-ray detector for digital breast tomosynthesis

Evolution of spatial resolution in breast CT at UC Davis

Synchrotron based planar imaging and digital tomosynthesis of breast and biopsy phantoms using a CMOS active pixel sensor

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