Bolometer fluid flow sensor

What is claimed is: 1. A sensor comprising: a substrate having a first surface; a cap structure connected to the substrate, the cap structure configured to define a cavity between an inner surface of the cap structure and the first surface of the substrate, the cap structure including an infrared opaque material configured to block infrared radiation from entering the cavity from outside the cap structure; a plurality of absorbers, each absorber in the plurality of absorbers being connected to respective electrodes that suspend the respective absorber above the first surface of the substrate at a respective position within the cavity, each absorber in the plurality of absorbers being configured to absorb infrared radiation at the respective position within the cavity; and a plurality of readout circuits, each readout circuit in the plurality of readout circuits being connected to a respective absorber in the plurality of absorbers via the respective electrodes and configured to provide a measurement signal that indicates an amount of infrared radiation absorbed by the respective absorber. 2. The sensor of claim 1 further comprising: a heating element configured to heat a heated portion of the cap structure, each absorber in the plurality of absorbers being arranged in the cavity near a portion of the cap structure that is adjacent to the heated portion of the cap structure. 3. The sensor of claim 2 , wherein: a first absorber in the plurality of absorbers is arranged in the cavity near a portion of the cap structure that is adjacent to heated portion of the cap structure in a first direction from heated portion of the cap structure; and a second absorber in the plurality of absorbers is arranged in the cavity near a portion of the cap structure that is adjacent to heated portion of the cap structure in a second direction from heated portion of the cap structure, the second direction being opposite the first direction. 4. The sensor of claim 3 , wherein: a third absorber in the plurality of absorbers is arranged in the cavity near a portion of the cap structure that is adjacent to heated portion of the cap structure in a third direction from heated portion of the cap structure, the third direction being perpendicular to the first direction; and a fourth absorber in the plurality of absorbers is arranged in the cavity near a portion of the cap structure that is adjacent to heated portion of the cap structure in a fourth direction from heated portion of the cap structure, the fourth direction being opposite the third direction. 5. The sensor of claim 2 , wherein the absorbers in the plurality of absorbers are arranged near portions of the cap structure that are symmetrically arranged around the heated portion of the cap structure. 6. The sensor of claim 1 further comprising: a controller operably connected to each readout circuit in the plurality of readout circuits, the controller being configured to: receive the measurement signal from each readout circuit in the plurality of readout circuits; and determine a flow characteristic of a fluid that flows near the cap structure the measurement signals from at least two readout circuits in the plurality of readout circuits. 7. The sensor of claim 6 , the controller being further configured to: detect that a first amount of infrared radiation is being absorbed by a first absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the first absorber; detect that a second amount of radiation is being absorbed by a second absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the second absorber; and determine which direction the fluid is flowing between the first absorber and the second absorber based on a comparison of the first amount and the second amount. 8. The sensor of claim 6 , the controller being further configured to: detect that an amount of infrared radiation being absorbed by a first absorber in the plurality of absorbers began to change at a first point in time based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the first absorber; detect that an amount of infrared radiation being absorbed by a second absorber in the plurality of absorbers began to change at a second point in time based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the second absorber; and determine which direction the fluid is flowing between the first absorber to the second absorber in based on a comparison of the first point in time and the second point in time. 9. The sensor of claim 6 , the controller being further configured to: detect that a first amount of infrared radiation is being absorbed by a first absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the first absorber; detect that a second amount of radiation is being absorbed by a second absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the second absorber; and determine a speed at which the fluid is flowing in a direction from the first absorber toward the second absorber based on a difference between the first amount and the second amount. 10. A method of operating a sensor, the sensor including (i) a substrate having a first surface, (ii) a cap structure connected to the substrate, the cap structure configured to define a cavity between an inner surface of the cap structure and the first surface of the substrate, the cap structure including an infrared opaque material configured to block infrared radiation from entering the cavity from outside the cap structure, and (iii) a plurality of absorbers, each absorber in the plurality of absorbers being connected to respective electrodes that suspend the respective absorber above the first surface of the substrate at a respective position within the cavity, each absorber in the plurality of absorbers being configured to absorb infrared radiation at the respective position within the cavity, the method comprising: receiving a measurement signal from each readout circuit in a plurality of readout circuits, each readout circuit in the plurality of readout circuits being connected to a respective absorber in the plurality of absorbers via the respective electrodes and configured to provide a measurement signal that indicates an amount of infrared radiation absorbed by the respective absorber; and determining a flow characteristic of a fluid that flows near the cap structure the measurement signals from at least two readout circuits in the plurality of readout circuits. 11. The method of claim 10 further comprising: detecting that a first amount of infrared radiation is being absorbed by a first absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the first absorber; detecting that a second amount of radiation is being absorbed by a second absorber in the plurality of absorbers based on the measurement signal from the readout circuit in the plurality of readout circuits that is connected to the second absorber; and determining which direction the fluid is flowing between the first absorber and the second absorber based on a comparison of the first amount and the second amount. 12. The method of claim 10