With extensive usage of radiography in medical diagnostics, achieving the lowest possible dose imaging is a driving force for the X-ray image sensor community. Furthermore, medical diagnostics would benefit greatly from true colour X-ray imaging.
A low-cost and low-power X-ray photon counting detector has been developed with the highest possible scalability and manufacturability. The sensor allows direct coupling with scintillators. It discriminates between two X-ray energy levels, allowing true colour interpretation of the data.
Standard CMOS and CIS technology are being used, which resulted in a USB camera demonstrator (92×90 pixels @ 1cm²) for true colour X-ray imaging. This demonstrator can be easily expanded to a wafer level device (e.g. 14x14cm2 area).
Beyond space and medical application, this technology could be usable in other X-ray applications such as non-destructive testing, µCT, healthcare, luggage inspections, etc. as it allows (proven) better interpretation of the images.
This company is a design house from Belgium for turnkey, high-end, high performance image sensors for space, medical and other application domains.
Innovations and advantages of the offer
The dual channel photon counting with scintillators incorporates the following concepts:
- High scalability, by stitching and minimal gap abutting
- High manufacturability (wafer scale devices of 14x14cm2)
- No heavy semiconductor hybridization, but rather using optically coupled scintillators (more economical)
- Use of 0.18µm standard CMOS Contact Image Sensor technology
- Front side illumination
- High yield is ensured by a low transistor count per pixel and fault tolerant design
- Low power consumption due to the CMOS technology
- Real-time evaluation on site on a variety of equipment is possible
- medical diagnostics
- bone densitometry
and other X-ray related applications including:
- non-destructive testing (µCT)
- healthcare (dentistry)
- luggage inspections
Description of Space Heritage
The heritage of this current project is the result of previous efforts of the technology provider in the development of radiation hard pixels for space application, and the development of an ASIC in the frame of an ESA project targeted at infrared sensor signal conditioning for space applications (ESA AO/1-6814/11/NL/AF, Prototype ASIC Development of Large Format NIR/SWIR Detector Array).
Both developments led to a collection of technology solutions for space applications including radiation hard pixels and a generic 0.18µm analogue and digital radiation hard library.
Starting from this expertise, X-ray imaging is a closely related field.