A thermopile infrared sensor array, comprises a sensor chip with a number of thermopile sensor elements, made from a semiconductor substrate and corresponding electronic components. The sensor chip is mounted on a support circuit board and enclosed by a cap in which a lens is arranged. The aim is th
A thermopile infrared sensor array, comprises a sensor chip with a number of thermopile sensor elements, made from a semiconductor substrate and corresponding electronic components. The sensor chip is mounted on a support circuit board and enclosed by a cap in which a lens is arranged. The aim is the production of a monolithic infrared sensor array with a high thermal resolution capacity with a small chip size and which may be economically produced. The aim is achieved by arranging a thin membrane made from non-conducting material on the semiconductor substrate of the sensor chip on which the thermopile sensor elements are located in an array. Under each thermopile sensor element, the back side of the membrane is uncovered in a honeycomb pattern by etching and the electronic components are arranged in the boundary region of the sensor chip. An individual pre-amplifier with a subsequent low-pass filter may be provided for each column and each row of sensor elements.
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The invention claimed is: 1. Thermopile infrared sensor array comprising a sensor chip having a number of thermopile sensor elements constructed on a semiconductor substrate of the sensor chip and corresponding electronic components, the sensor chip being mounted on a support substrate and enclosed
The invention claimed is: 1. Thermopile infrared sensor array comprising a sensor chip having a number of thermopile sensor elements constructed on a semiconductor substrate of the sensor chip and corresponding electronic components, the sensor chip being mounted on a support substrate and enclosed with a cap, inlet optics being arranged in a center over the sensor chip, a thin membrane made of nonconducting material being arranged on the semiconductor substrate of the sensor chip, the thermopile sensor elements being situated in an array on the membrane, the substrate in back of the membrane being free etched beneath each thermopile sensor element, the electronic components being arranged in an edge area of the sensor chip, preamplifiers with low-pass filters being provided at least for every fourth, column or row of sensor elements. 2. Thermopile infrared sensor array according to claim 1, wherein the semiconductor substrate of the sensor chip is provided with recesses beneath the sensor elements so that in a boundary area between sensor elements, thin, vertical or almost vertical separation walls made of semiconductor material are situated in the membrane, the membrane covers the recesses, and the sensor chip has a solid peripheral support area. 3. Thermopile infrared sensor array according to claim 2, wherein the separation walls end above the support substrate. 4. Thermopile infrared sensor array according to claim 3, wherein the separation walls are shortened by overetching. 5. Thermopile infrared sensor array according to claim 2, wherein spacers are arranged between the solid peripheral support area and the support substrate. 6. Thermopile infrared sensor array according to claim 2, wherein the separation walls are provided with ventilation slits. 7. Thermopile infrared sensor array according to claim 2, wherein a bottom of the sensor chip is mounted at least beneath the peripheral support area with a joining material of very high heat conductivity on the support substrate. 8. Thermopile infrared sensor array according to claim 7, wherein the bottom of the sensor chip both beneath the peripheral support area and beneath a separation wall is mounted with a joining material of higher heat conductivity on the support substrate. 9. Thermopile infrared sensor array according to claim 7, wherein the joining material is a metal- or ceramic-filled adhesive, a metallic solder or a metal-ceramic-filled glass mass. 10. Thermopile infrared sensor array according to claim 1 wherein individual preamplifiers and the other electronic components are arranged distributed uniformly on the peripheral support area of the sensor chip so that a uniform heat distribution occurs from the developing heat losses. 11. Thermopile infrared sensor array according to claim 10, wherein individual preamplifiers are connected to one or more low-pass filters whose limit frequency is the same or at most two to three times higher than a row readout frequency or a column readout frequency of the array. 12. Thermopile infrared sensor array according to claim 1, wherein the sensor chip is provided with at least one edge area widened on one side on which electronic components with greater power loss are arranged. 13. Thermopile infrared sensor array according to claim 12, wherein individual preamplifiers are connected to a low-pass filter whose limit frequency is the same or higher, than a row or column readout frequency of the array. 14. Thermopile infrared sensor array according to claim 13, wherein the limit frequency is at most two to three times higher than a row or column readout frequency of the array. 15. Thermopile infrared sensor array according to claim 1, further comprising dummy elements wherein a dummy element to compensate for error signals is assigned to each preamplifier in addition to certain sensor elements. 16. Thermopile infrared sensor array according to claim 15, wherein the dummy elements are produced from a same sensor layer as the sensor elements but no recess is arranged beneath the dummy elements. 17. Thermopile infrared sensor array according to claim 15, wherein the dummy elements are constructed identically to the sensor element but are arranged in an edge area of the sensor chip and shielded by a diaphragm from radiation of a measured object. 18. Thermopile infrared sensor array according to claim 15, wherein the dummy elements are provided with cover layers that mask or reflect infrared radiation. 19. Thermopile infrared sensor array according to claim 1, wherein the semiconductor substrate has at least one additional recessed insulation area between a last separation wall of an outer row of thermopile sensor elements and an edge area of the sensor chip. 20. Thermopile infrared sensor array according to claim 1 wherein the cap has a surface that absorbs infrared radiation on an inside facing the sensor elements. 21. Thermopile infrared sensor array according to claim 20, wherein an aperture is arranged within the cap. 22. Thermopile infrared sensor array according to claim 21, wherein the aperture comprises a material that does not reflect infrared radiation. 23. Thermopile infrared sensor array according to claim 20, wherein a side of the aperture facing the sensor elements has a surface coating that absorbs infrared radiation. 24. Thermopile infrared sensor array according to claim 1, wherein the thin membrane comprises silicon dioxide, silicon nitride or a similar material. 25. Thermopile infrared sensor array according to claim 1, wherein the preamplifiers with low-pass filters are provided for every column or row of sensor elements.
Kennedy, Adam M.; Ray, Michael; Wyles, Richard H.; Wyles, Jessica K.; Radford, William A., Method and apparatus providing focal plane array active thermal control elements.
Schieferdecker Jorg,DEX ; Simon Marion,DEX ; Storck Karlheinz,DEX ; Rothley Manfred,DEX ; Zabler Erich,DEX ; Jahne Rolf,DEX, Sensor system and manufacturing process as well as self-testing process.
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