Infrared sensing devices and methods

The invention claimed is: 1. An infrared sensor assembly for sensing infrared radiation from an object, the infrared sensor assembly comprising: a sensor array comprising a plurality of sensing elements, provided on or embedded in a substrate extending in a substrate plane, wherein the sensor array comprises: at least two infrared sensing elements, each infrared sensing element having a radiation responsive element providing a proportionate electrical signal in response to infrared radiation incident thereto; at least two blind sensing elements, at least one of said two blind sensing elements being interspersed among the at least two sensing elements, each of said two blind sensing elements being shielded from incident infrared radiation of the object and providing a proportionate electrical signal in response to parasitic thermal fluxes, wherein an output of the sensor array is a subtractive function of a sum of the signals of the plurality of infrared sensing elements and a sum of the signals of the plurality of blind sensing elements such that at least linear and/or non-linear parasitic thermal fluxes are at least partly compensated for. 2. The infrared sensor assembly according to claim 1 , wherein said subtractive function corresponds with a sum of the signals of the plurality of the infrared sensing elements minus a multiplication of a proportionality factor and a sum of the signals of the plurality of blind sensing elements and/or wherein said subtractive function is achieved by placing the sensors in circuit according to an anti-series schematic. 3. The infrared sensor assembly according to claim 1 , wherein any of said sum of the signals of the plurality of the infrared sensing elements and/or said sum of the signals of the plurality of blind sensing elements is a weighted sum wherein for each of the pixels a weighing factor is taken into account. 4. The infrared sensor assembly according to claim 1 , wherein each of the blind sensing elements and the infrared sensing elements have a full field of view that corresponds with the field of view of the infrared sensor assembly. 5. The infrared sensor assembly according to claim 1 , the infrared sensor assembly comprising a cap covering the sensor array, wherein the center of the sensor array is matched with the center of the cap covering the sensor array or the center of the sensor array is matched to an external environment that induces non-linear thermal gradients. 6. The infrared sensor assembly according to claim 1 , further comprising a processor for processing of the electrical signal output of the infrared sensing elements and of the blind sensing elements, thus cancelling the signal distortion caused by thermal gradients of the sensor array, and/or further comprising a processor programmed for subtractive processing of the electrical signal output of the plurality of the infrared sensor elements of the sensor array together with the output of the plurality of blind sensor elements of the sensor array, thus cancelling the signal distortion caused by thermal gradients of the sensor array. 7. The infrared sensor assembly according to claim 1 , further comprising means for sampling and digitizing the output of the plurality of infrared sensing elements of the sensor array together with the plurality of blind infrared sensing elements of the sensor array and/or wherein parasitic thermal fluxes include a convolution of thermal gradients over the sensor array and wherein for each infrared sensing elements a blind sensing element is positioned on an isotherm in the pixel array, the isotherm being corresponding with one of the thermal gradients in the convoluted thermal gradients. 8. The infrared sensor assembly according to claim 1 , wherein each row and/or each column of the sensor array comprises at least one blind sensing element. 9. The infrared sensor assembly according to claim 1 , wherein the sensor array comprises a same amount of infrared sensing elements and blind infrared sensing elements and/or wherein each row and/or each column of the sensor array comprises a same amount of infrared sensor elements and blind infrared sensor elements, and the sensor elements are arranged in a checkerboard arrangement. 10. The infrared sensor assembly according to claim 1 , wherein the sensor array is a 2×2 sensor array wherein the main diagonal elements of the sensor array only comprise blind sensing elements. 11. The infrared sensor assembly according to claim 1 , wherein each corner of the sensor array comprises a blind sensing element and whereby the sensor array further comprises at least one blind sensing element interspersed in between the at least two infrared sensing elements and/or wherein the sensor array comprises a same amount of rows and columns. 12. The infrared sensor assembly according to claim 1 , further comprising a scanning shift register for selecting a row of the sensor array to be read out. 13. The infrared sensor assembly according to claim 1 , wherein the infrared sensing elements and blind infrared sensing elements each have a same layout. 14. The infrared sensor assembly according to claim 1 , wherein channels are provided between the infrared sensor elements and blind infrared sensor elements of the sensor array. 15. An infrared sensor assembly comprising a sensor array for providing an image signal of a scene, the sensor array comprising a plurality of infrared sensing elements and blind infrared sensing elements, wherein the sensor array comprises channels which are provided between the plurality of infrared sensor elements and blind infrared sensor elements. 16. A method for sensing an infrared signal from an object using an array comprising a plurality of infrared sensing elements, the method comprising: sensing a signal using at least two infrared sensing elements comprising a radiation response element providing a proportionate electrical signal in response to infrared radiation incident thereto; sensing a signal using at least two blind sensing elements interspersed among the at least two sensing elements, each of said two blind sensing elements being shielded from incident infrared signal from the object, providing a proportionate electrical signal in response to parasitic thermal fluxes; and processing the signals such that the output of the sensor array is a subtractive function of a sum of signals of the plurality of infrared sensing elements and a sum of the signals of the plurality of blind sensing elements such that at least linear an/or non-linear parasitic thermal fluxes are at least partly compensated for. 17. The method according to claim 16 , wherein said processing comprises deriving the output as a subtractive function corresponding with a sum of the signals of the plurality of the infrared sensing elements minus a multiplication of a proportionality factor and a sum of the signals of the plurality of blind sensing elements. 18. The method according to claim 17 , wherein said processing comprises deriving the output as a subtractive function wherein any of said sum of the signals of the plurality of the infrared sensing elements and/or said sum of the signals of the plurality of blind sensing elements is a weighted sum wherein for each of the pixels a weighing factor is taken into account.