Abstract: Systems and methods according to one or more embodiments are provided for determining an emitted radiation intensity of an object in a thermal image. In one example, a system includes a memory component configured to store a plurality of captured thermal images of a scene and a processor. The processor is configured to select a pixel on a thermal image corresponding to a measured radiation intensity associated with an object in the scene. Real world coordinates of the object are determined. An emitted radiation intensity of the object is calculated using the determined real world coordinates and the measured radiation intensity. Additional systems and methods are also provided.

Abstract: A system for capturing a thermal video stream includes a thermal image capture component, such as an IR camera, configured to capture and digitize the thermal video stream having n-bits of data per pixel, a memory configured to store the captured thermal images, and a processor. The processor is configured to select captured thermal images as frames for a video stream and subdivide each captured thermal image into separate m-bit and k-bit image streams. The processor is further configured to compress the m-bit thermal image stream in a video compression format that includes frame and metadata, compress the k-bit image stream using a lossless or substantially lossless compression format, and incorporate the compressed k-bit image stream into the coded m-bit video stream as metadata.

Abstract: An infrared (IR) imaging module may capture a background image in response to receiving IR radiation from a background of a scene and determine background calibration terms using the background image. The determined background calibration terms may be scale factors and/or offsets that equalize the pixel values of the background image to a baseline, value. IR imaging device may use the background calibration terms to capture images that have the baseline value for pixels corresponding to IR radiation received from the background and higher values (or lower values) for pixels corresponding to IR radiation received from a foreground. Such images may be used to count people and generate a heat map. The background calibration terms may be updated periodically, with the update period being increased at least for some pixels or a pixel area when a person is detected.

Abstract: A system for capturing a thermal video stream includes a thermal image capture component, such as an IR camera, configured to capture and digitize the thermal video stream having n-bits of data per pixel, a memory configured to store the captured thermal images, and a processor. The processor is configured to select captured thermal images as frames for a video stream and subdivide each captured thermal image into separate m-bit and k-bit image streams. The processor is further configured to compress the m-bit thermal image stream in a video compression format that includes frame and metadata, compress the k-bit image stream using a lossless or substantially lossless compression format, and incorporate the compressed k-bit image stream into the coded m-bit video stream as metadata.

Abstract: An infrared (IR) imaging module may capture a background image in response to receiving IR radiation from a background of a scene and determine background calibration terms using the background image. The determined background calibration terms may be scale factors and/or offsets that equalize the pixel values of the background image to a baseline, value. IR imaging device may use the background calibration terms to capture images that have the baseline value for pixels corresponding to IR radiation received from the background and higher values (or lower values) for pixels corresponding to IR radiation received from a foreground. Such images may be used to count people and generate a heat map. The background calibration terms may be updated periodically, with the update period being increased at least for some pixels or a pixel area when a person is detected.

Abstract: Systems and methods according to one or more embodiments are provided for determining an emitted radiation intensity of an object in a thermal image. In one example, a system includes a memory component configured to store a plurality of captured thermal images of a scene and a processor. The processor is configured to select a pixel on a thermal image corresponding to a measured radiation intensity associated with an object in the scene. Real world coordinates of the object are determined. An emitted radiation intensity of the object is calculated using the determined real world coordinates and the measured radiation intensity. Additional systems and methods are also provided.