Under display terahertz biometric imaging arrangement

The invention claimed is: 1. A terahertz biometric imaging arrangement operative in the terahertz range of radiation and configured to be arranged under an at least partially transparent display panel, and configured to capture an image of a biometric object located on an opposite side of the transparent display panel, the biometric imaging arrangement comprising: a transmitter element arranged to emit terahertz radiation towards the object for illuminating the biometric object; and an image sensor comprising an antenna pixel array configured to detect radiation in a terahertz range and arranged to detect terahertz radiation reflected from the illuminated biometric object, for capturing an image in which sub-dermal layers of the biometric object are detectable, wherein the transmitter element is arranged on a substrate spatially separated from the image sensor, wherein each of the antenna pixels comprises a power detector including an antenna structure configured to sense the terahertz radiation reflected from the illuminated object, and at least one on-chip frequency converting element connected to the antenna structure and configured to convert the sensed terahertz radiation to a signal at a lower frequency than the frequency of the sensed terahertz radiation, or to a DC signal. 2. The terahertz biometric imaging arrangement according to claim 1 , wherein the transmitter element is arranged vertically separated from the image sensor. 3. The terahertz biometric imaging arrangement according to claim 1 , wherein the transmitter element is stacked with the image sensor. 4. The terahertz biometric imaging arrangement according to claim 1 , comprising: an array of terahertz radiation redirecting elements arranged between the transmitter element and the image sensor, wherein each terahertz radiation redirecting element is configured to redirect terahertz radiation onto the antenna pixel array. 5. The terahertz biometric imaging arrangement according to claim 4 , wherein the array of terahertz radiation redirecting elements is an array of microlenses, wherein each microlens is configured to redirect terahertz radiation onto a subarray of pixels in the antenna pixel array. 6. The terahertz biometric imaging arrangement according to claim 5 , wherein the array of terahertz radiation redirecting elements is an array of vertical waveguides wherein each vertical waveguide is configured to redirect terahertz radiation onto a pixel in the antenna pixel array. 7. The terahertz biometric imaging arrangement according to claim 1 , wherein the substrate is at least partly transparent such that terahertz radiation can be propagate through the substrate. 8. The terahertz biometric imaging arrangement according to claim 1 , wherein the frequency converting element comprises at least one on-chip transistor structure connected to the antenna structure of the pixel. 9. The terahertz biometric imaging arrangement according to claim 1 , wherein the image sensor comprises a substrate supporting the antenna pixel array, wherein the substrate is at least partly transparent. 10. The terahertz biometric imaging arrangement according to claim 1 , wherein the image sensor comprises a substrate supporting the antenna pixel array, wherein the substrate is made from a flexible material. 11. The passive terahertz biometric imaging arrangement according to claim 1 , wherein the antenna pixels are made from an at least partly transparent material. 12. The terahertz biometric imaging arrangement according to claim 1 , wherein at least one of the array of antenna pixels and the transmitter element is laminated on a back side of the at least partly transparent display panel. 13. The terahertz biometric imaging arrangement according to claim 1 , wherein the image sensor is arranged under a display element comprising an array of color controllable light emitting units. 14. The terahertz biometric imaging arrangement according to claim 1 , wherein the image sensor is arranged interleaved between the transparent display panel and a display element comprising an array of color controllable light emitting units. 15. The terahertz biometric imaging arrangement according to claim 1 , wherein at least one of the array of antenna pixels and the transmitter element is laminated onto a display element comprising an array of color controllable light emitting units. 16. The terahertz biometric imaging arrangement according to claim 1 , wherein the transmitter element and the image sensor are configured to be arranged interleaved between the at least partly transparent display panel and a display element comprising an array of color controllable light emitting units. 17. The terahertz biometric imaging arrangement according to claim 1 , wherein the transmitter element and the image sensor are configured to be arranged under both the at least partly transparent display panel and a display element comprising an array of color controllable light emitting units. 18. The terahertz biometric imaging arrangement according to claim 1 , wherein the array of antenna pixels is manufactured on the display panel. 19. An electronic device ( 200 ) comprising: an at least partly transparent display panel; the terahertz biometric imaging arrangement according to claim 1 , and processing circuitry configured to: receive a signal from the terahertz biometric imaging arrangement indicative of a biometric object touching the transparent display panel, perform a biometric authentication procedure based on the detected fingerprint. 20. A method of manufacturing an image sensor for a terahertz biometric imaging arrangement, the method comprising: providing a cover glass configured to cover a display for an electronic device; providing a layer of a two-dimensional material on the cover glass; patterning the layer of two-dimensional material to form an array of antenna pixels, wherein each of the antenna pixels comprises a power detector including an antenna structure configured to sense the terahertz radiation reflected from the illuminated biometric object and at least one on-chip frequency converting element connected to the antenna structure and configured to convert the detected terahertz radiation to a signal at a lower frequency than the frequency of the detected terahertz radiation, or to a DC signal.