Thermal sensor array device, method of measuring a temperature gradient and method of measuring a temperature

What is claimed is: 1 . A thermal sensor element device comprising: a substrate having a cavity formed therein; and an infrared absorbing membrane suspended over the cavity from a first beam and a second beam, the first beam being thermally coupled at one end thereof to the substrate at a first substrate cold junction and the second beam being thermally coupled at one end thereof to the substrate at a second substrate cold junction; and a plurality of thermocouples disposed over the first and second beams and the infrared absorbing membrane; wherein the plurality of thermocouples is arranged on the first and second beams and the infrared absorbing membrane as a first thermopile and a second thermopile; the first and second thermopiles are arranged on the infrared absorbing membrane to measure, when in use, a sum of first temperature differentials and second temperature differentials, the first temperature differentials being between the first substrate cold junction and a hot junction on the infrared absorbing membrane, and the second temperature differentials being between the second substrate cold junction and the hot junction on the infrared absorbing membrane; and the first thermopile is configured to connect selectively to the second thermopile in series and anti-series. 2 . The device according to claim 1 , wherein the infrared absorbing membrane comprises hot junctions of the plurality of thermocouples. 3 . The device according to claim 1 , wherein each of the first thermopile and the second thermopile is respectively configured to measure, when in use, a summation of temperature differentials in respect of a first region of the infrared absorbing membrane and a second region of the infrared absorbing membrane. 4 . The device according to claim 2 , wherein a number of the hot junctions and a number of cold junctions of the plurality of thermocouples are configured so as to provide the first thermopile between the plurality of hot junctions and the number of cold junctions; another number of the hot junctions and another number of cold junctions of the plurality of thermocouples are configured so as to provide the second thermopile between the plurality of hot junctions and the another number of cold junctions; at least one of the number of cold junctions is located at a first end of the first beam distal from the infrared absorbing membrane; and at least one of the another number of cold junctions is located at a second end of the second beam distal from the infrared absorbing membrane. 5 . The method according to claim 4 , wherein the summation of the first and second temperature differentials is measured between the number of cold junctions and the number of hot junctions. 6 . The device according to claim 1 , wherein at least a portion of each of the hot junctions is configured to converge within a predetermined hot end region of the infrared absorbing membrane. 7 . The device according to claim 6 , wherein the hot junctions of the thermocouples comprise interconnections in the predetermined hot end region of the infrared absorbing membrane. 8 . The device according to claim 1 , wherein the first beam comprises a narrow track portion that extends towards the infrared absorbing membrane and integrally forms a portion of the infrared absorbing membrane; and the second beam comprises a narrow track portion that extends towards the infrared absorbing membrane and integrally forms another portion of the infrared absorbing membrane. 9 . The device according to claim 1 , wherein neighbouring thermocouples of the first thermopile are separated by a number of separating channels narrower than the thermocouples. 10 . The device according to claim 1 , wherein the plurality of thermocouples is an even number of thermocouples. 11 . The device according to claim 1 , wherein the first beam bridges the substrate and a first side of the infrared absorbing membrane; and the second beam bridges the substrate and a second side of the infrared absorbing membrane. 12 . The device according to claim 4 , wherein a first number of thermocouples of the first thermopile between the hot junction on the infrared absorbing membrane and the at least one of the number of cold junctions of the first beam is greater than a second number of thermocouples of the first thermopile between the hot junction on infrared absorbing membrane and the at least one of the another number of cold junctions of the second beam. 13 . The device according to claim 1 , wherein a first number of thermocouples of the second thermopile between the hot junction on the infrared absorbing membrane and the at least one of the another number of cold junctions of the second beam is greater than a second number of thermocouples of the second thermopile between the hot junction on the infrared absorbing membrane and the at least one of the number of cold junctions of the first beam. 14 . A thermal sensor array device comprising the thermal sensor element device according to claim 1 . 15 . A method of measuring a temperature gradient over a thermal sensor device of an array of thermal sensor devices, the method comprising: providing an array of thermal sensor devices comprising the thermal sensor device according to claim 1 ; receiving infrared electromagnetic radiation incident upon the thermal sensor device; connecting the first thermopile to the second thermopile in anti-series; measuring a difference value in respect of the received infrared electromagnetic radiation constituting the temperature gradient; and storing the temperature gradient measured. 16 . A method of measuring a temperature, the method comprising: measuring the temperature gradient according to claim 15 ; connecting the first thermopile to the second thermopile in series; measuring a summation value in respect of the received infrared electromagnetic radiation; and calculating a temperature by using the temperature gradient to compensate the summation value.