Fire urgency estimator in geosynchronous orbit (FUEGO)

What is claimed is: 1. An apparatus for fire urgency estimation, the apparatus comprising: (a) an imager configured for capturing images, wherein said imager is configured for deployment within a satellite configured for orbiting Earth; (b) a processor configured for processing said images; and (c) programming executable on said processor for detecting fire locations across extensive geographic regions while suppressing false alarms by performing steps comprising: (i) classifying trends in response to temporal subtraction of images received by said imager over a time of seconds to minutes; (ii) dithering of images to improve resolution; (iii) adjusting detection thresholds in a time-sensitive autonomous manner to reduce false alarm rates despite constantly varying conditions; and (iv) generating calibrated decisions regarding fire urgency in response to steps (i) through (iii). 2. A method of fire urgency estimation for detecting fire locations across extensive geographic regions while suppressing false alarms, the method comprising: (a) classifying trends in response to temporal subtraction of images received by an imager over a time of seconds to minutes, wherein said images are captured by the imager integrated within a satellite orbiting Earth; (b) dithering of said images to improve resolution; (c) adjusting detection thresholds in a time-sensitive autonomous manner to reduce false alarm rates despite varying environmental conditions; and (d) generating calibrated decisions regarding fire urgency in response to steps (a) through (c). 3. A fire urgency estimator, comprising: (a) a platform comprising an imager configured to capture a plurality of Earth geographic images; (b) programming executable on the platform capable of performing steps comprising: (i) subtracting one Earth geographic image from another Earth geographic image; (A) wherein the two images are separated by a sampling interval to form a radiance difference image; and (B) wherein the two images view at least a portion of the same Earth geography; (ii) detecting candidate fires in the radiance difference image within the same Earth geography; (iii) excluding from the candidate fires those that fail one or more tests to form a set of non-excluded candidate fires; (iv) evaluating an importance cost of the non-excluded candidate fires; and (v) reporting the non-excluded candidate fires above a fire importance cost reporting threshold. 4. The fire urgency estimator of claim 3 , wherein the platform comprises either: (a) a satellite in Earth orbit; or (b) a manned aerial vehicle; or (c) an unmanned aerial vehicle (UAV). 5. The fire urgency estimator of claim 3 , wherein the platform further comprises: (a) a processor physically disposed proximally to the platform; or (b) a ground based processor; or (c) a distributed processor comprising: (i) a processor physically disposed within or proximal to the platform; and (ii) a ground based processor in communication with the processor physically disposed proximally to the platform; (iii) wherein processing takes place in both the platform processor and in the ground based processor; and (iv) wherein the platform processor and the ground based processor are in at least periodic communication. 6. The fire urgency estimator of claim 3 , wherein the imager comprises either a monospectral or multispectral imager. 7. The fire urgency estimator of claim 6 , wherein the imager comprises an ability to produce dithered geographic images. 8. The fire urgency estimator of claim 3 , wherein said detecting candidate fires comprises: (a) forming a histogram of the radiance difference image; and (b) calculating one or more properties from the histogram, wherein the one or more properties are selected from a group of properties consisting of: a mean, a maximum value, a standard deviation (σ), and a full width half maximum (FWHM) value. 9. The fire urgency estimator of claim 8 , wherein the step of detecting candidate fires further comprises detecting one or more fire candidates from the histogram. 10. The fire urgency estimator of claim 3 , further comprising: (a) a fire urgency receiver; (b) wherein the receiver is configured to receive from the platform at least one of the reported non-excluded candidate fires above the fire importance cost reporting threshold; and (c) wherein the receiver is configured to receive from the platform a geographic location corresponding to at least one reported non-excluded candidate fire. 11. A fire urgency estimator, comprising: (a) a computer processor; and (b) programming in a non-transitory computer readable medium and executable on the computer processor for performing steps comprising: (i) capturing a plurality of Earth geographic images by using an imager; (ii) subtracting one Earth geographic image from another Earth geographic image; (A) wherein the two images are separated by a sampling interval to form a radiance difference image; and (B) wherein the two images view at least a portion of the same Earth geography; (iii) detecting candidate fires in the radiance difference image within the same Earth geography; (iv) excluding from the candidate fires those that fail one or more tests to form a set of non-excluded candidate fires; (v) evaluating an importance cost of the non-excluded candidate fires; and (vi) reporting the non-excluded candidate fires above a fire importance cost reporting threshold. 12. A computer readable non-transitory storage medium comprising software configured to be run by at least one computer processor for performing steps comprising: (a) providing a radiance difference image by performing steps comprising: (i) acquiring at least two Earth geographic images; (ii) subtracting one Earth geographic image from another Earth geographic image to form the subtracted difference image; (iii) wherein the two images are separated by a sampling interval; (iv) wherein the two images view at least a portion of the same Earth geography; and (v) wherein the radiance difference image corresponds the portion of the same Earth geography; (b) detecting candidate fires in the radiance difference image within the same Earth geography; (c) excluding from the candidate fires those that fail one or more tests to form a set of non-excluded candidate fires; (d) evaluating an importance cost of the non-excluded candidate fires; and (e) reporting the non-excluded candidate fires above a fire importance cost reporting threshold. 13. A fire urgency estimator, comprising: (a) a platform; (b) the platform comprising an imager configured to capture a plurality of Earth geographic images (c) a processor disposed on the platform; and (d) means for reporting from the Earth geographic images one or more non-excluded candidate fires above a fire importance cost reporting threshold by processing the plurality of Earth geographic images on the processor; wherein the means for reporting comprises programming executable on the processor capable of performing steps comprising: (1) providing a radiance difference image by performing steps comprising: (i) acquiring at least two Earth geographic images; (ii) subtracting one Earth geographic image from another Earth geographic image to form the subtracted difference image; (iii) wherein the two images are separated by a sampling interval; (iv) wherein the two images view at least a portion of the same Earth geography; and (v) wherein the radiance difference image corresponds to the portion of the same Earth geography; (2) detecting candidate fires in the radiance difference image withi