WidePIX 5X5

Large area industrial x-ray spectral imaging camera with edge-less sensor technology with speed up to 10 fps and a size of 1.6M pixels. Can be used for non-destructive testing, small animal spectral imaging and x-ray diffraction.

Description

WidePIX 5X5 consists of 5×5 Timepix tiles. Each Timepix tile is consists of an edgeless silicon sensor. The edgeless sensor technology allows placing all tiles tightly together from all sides. Thus the whole imaging area of the camera is fully sensitive to the radiation – there are no gaps between the tiles in the image. The robust design of the camera addresses industrial users.

The minimum detectable is typically 5 keV in case of X-ray photons. The pixel size, which is 55 µm, defines the intrinsic spatial resolution. The pixels situated on the border of tiles are 2.5 times larger in one direction. The corner pixels of tiles are 2.5 times larger in both directions.

The camera is connected to the controlling computer via USB 2.0 cable with readout time of 0.65 seconds per frame. The thermal stabilization of the camera is in dependence on environment provided by an active water cooling system with chiller. The power consumption is 25 W.

Key Features of WidePIX 5X5 :

  • Sensor Material: Silicon, CdTe
  • Sensor Thickness: 300 μm, 500 μm Si and 1000 μm CdTe
  • Sensitive Area: 71 mm x 57 mm
  • Number of Pixels: 1280 x 1280
  • Pixel Pitch: 55 μm
  • Resolution: 9 lp/mm
  • Readout Speed: 10 frames/s
  • Threshold Step Resolution: 0.1 keV
  • Energy Resolution: 0.8 keV (THL) and 2 keV (ToT)
  • Min Detectable Energy: 5 keV for X-rays
  • Photon Counting Speed: up to 3 x 106 photons/s/pixel
  • Readout Chip: Timepix
  • Pixel Mode of Operation: Counting, Time-over-Threshold, Time-of -Arrival
  • Connectivity: USB 2.0
  • Dimensions: 130 mm x 103 mm x 54 mm (L x W x H)
  • Weight: 3.3 kg
  • Software: Pixet PRO

View/download the datasheet here.

Non-Destructive Testing

Non-Destructive Testing (NDT) is inspection, test, or evaluation of materials, components or assemblies for discontinuities, or differences in characteristics without destroying the serviceability of the sample. Standard radiographic X-ray imaging provides a black and white intensity or density image of the inspected sample where defects, impurities or cracks are observed if the resolution and the signal over the noise of the image is appropriate. The spectral NDT X-ray imaging provides based on photon counting provides additional material information of the samples together with a superior contrast and high spatial resolution. The spectral material information is used to discriminate different materials that can be used to identify the materials of interest or to calculate their amount in the sample. Find out more about this application here.

Small Animal Spectral Imaging

Cancer research, bio-mechanics, and drug testing are just a few examples of where X-ray imaging contributes to research in biology and medicine. New photon counting detectors represent a serious advancement for these applications, compared to previously used synchrotrons. The energy sensitivity of modern cameras opens better possibilities to identify individual types of tissue. That has important consequences in various industries, for example cancer research, where the tumour tissue can be better distinguished from the healthy one. Find out more about this application here.

X-ray Diffraction

X-ray diffraction is analytical method based on inspection of crystalline structure of samples used in applications, such as metallurgy, mineralogy, powders, pigments, polymers, surface layers and strain mapping. The traditional X-ray diffraction uses monochromatic X-rays which make the apparatus large and slow. ADVACAM’s spectral detectors based on Timepix3 chip with high resolution makes the diffraction system fast and compact. The sample analysis can be performed 100 times faster compared to the conventional systems. Due to fast speed of the analysis large areas of the sample can be analysed by scanning. Find out more about this application here.

Advacam Technology

The leading detector technology, which Advacam uses for its products and solutions is based on Medipix hybrid pixel detectors. These devices were developed within international collaboration of universities and research laboratories lead by team at CERN during past 20 years. Advacam team’s members have been part of the Medipix Collaboration from it inception and have been contributing to the technology.

Photon Counting Technology

Advacam’s imaging cameras are direct conversion single photon counting pixel detectors that represent the cutting edge of current radiation imaging technology. The term “single photon counting” means that every single photon of X-ray radiation detected in individual pixel is processed and counted. The technology brings two major advantages in comparison to the conventional X-ray imaging – high contrast together with sharp images and spectral information of X-rays that allows material specific information to be displayed in colors.

In the direct conversion cameras each pixel of the semiconductor crystal is directly connected to the complex CMOS circuit using a conductive solder bump. In the indirect conversion cameras a scintillation layer is attached on top of a photodiode. The photodiodes manufactured on a simple CMOS circuit that enables fine pixel sizes.

Illustrative comparison of a single pixel of a direct conversion and indirect conversion cameras.

The term direct conversion refers to immediate conversion of the X-rays into electric charge within the semiconductor crystal. The principle is contrary to the conventional indirect conversion where the X-rays are first converted into visible light in the scintillation layer that subsequently is converted into electric charge in the photodiodes.

Illustration of the operation principles in a single pixel between the direct and indirect conversion cameras.

The photon counting principle of detection eliminates all other sources of noise that are present in CCD or flat-panel based cameras. This leads to considerably better signal-to-noise ratio and therefore detectability of more details in images. The images sharpness or the actual spatial resolution of the captured image is defined by the electric charge in the CMOS readout. Even thought the pixel size of of the direct converting cameras is larger than that of the conventional indirect conversion cameras, the signal of the detected X-rays is better focused into the pixels. The typical size of a direct conversion pixel ranges from few millimeters to tens of micro meters where Advacam represents the highest pixel density of the current industrial X-ray cameras with 55 um pixel size. The video below describes the differences between conventional indirect conversion, direct conversion charge integrating and photon counting cameras. It summarises the major differences in the captured image quality in terms of spatial resolution, image noise and material discrimination.

The energy sensitivity is as important advancement of the imaging technology as was the colour photography and film. Contrary to regular X-ray imaging cameras, the photon counting cameras can discriminate or even directly measure energy (wavelength) of incoming photons. Since each element of the sample has different X-ray attenuating properties, it is possible to estimate material composition of the sample if the energy of the photons is measured. The spectral sensitivity offers major improvement over the conventional X-ray imaging cameras.

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