Configurable combination spectrometer and polarizer

What is claimed is: 1. A multimode configurable imaging spectropolarimeter comprising: a first beamsplitter configured to split incident electromagnetic radiation from a scene into a first optical path and a second optical path and to direct reflected electromagnetic radiation from the first and second optical paths along a combined optical path toward a focal plane; a movable first mirror positioned in the first optical path and configured to reflect electromagnetic radiation in the first optical path back toward the first beamsplitter, the first mirror being movable over a first scan range to provide a first optical path length difference between the first optical path and the second optical path; a polarizing beamsplitter positioned in the second optical path and configured to split electromagnetic radiation in the second optical path into a first polarization and a second polarization, the first and second polarizations being orthogonal to one another; a movable second mirror positioned in the second optical path and configured to reflect the first polarization toward the first beamsplitter, the second mirror being selectively movable over a second scan range to provide a second optical path length difference between the first and second polarizations; a fixed third mirror positioned in the second optical path and configured to reflect the second polarization toward the first beamsplitter; and at least one imaging sensor positioned at the focal plane and configured to receive the reflected electromagnetic radiation from the first and second optical paths and to produce a first interferogram from interference between the first polarization and the reflected electromagnetic radiation from the first optical path and a second interferogram from interference between the second polarization and the reflected electromagnetic radiation from the first optical path, the second interferogram being superimposed on the first interferogram and offset in frequency relative to the first interferogram. 2. The multimode configurable imaging spectropolarimeter of claim 1 , wherein the first interferogram comprises a first range of measured frequencies corresponding to the first polarization and the second interferogram comprises a second range of measured frequencies corresponding to the second polarization, and wherein the first and second ranges of measured frequencies do not overlap. 3. The multimode configurable imaging spectropolarimeter of claim 2 , wherein the at least one imaging sensor includes two imaging sensors each configured to receive the reflected electromagnetic radiation from the first and second optical paths. 4. The multimode configurable imaging spectropolarimeter of claim 3 , further comprising: a first bandpass filter positioned in front of a first one of the two imaging sensors and having a first passband including the first range of measured frequencies; and a second bandpass filter positioned in front of a second one of the two imaging sensors and having a second passband including the second range of measured frequencies. 5. The multimode configurable imaging spectropolarimeter of claim 1 , wherein the first and second polarizations are vertical polarization and horizontal polarization. 6. The multimode configurable imaging spectropolarimeter of claim 1 , further comprising a controller configured to selectively interrupt a scanning movement of the first mirror and the second mirror, and to impart a vibration to one of the first and second mirrors so as to substantially prevent formation of the first and second interferograms at the at least one imaging sensor. 7. An imaging method comprising: receiving electromagnetic radiation from a scene with an imaging transform spectrometer; splitting the electromagnetic radiation into a first optical path and a second optical path within the imaging transform spectrometer; splitting electromagnetic radiation in the second optical path into first and second orthogonal polarizations; reflecting the first and second polarizations and electromagnetic radiation from the first optical path to a focal plane; selectively producing first and second superimposed interferograms on an imaging sensor positioned at the focal plane by selectively controlling movement of a movable first mirror in the first optical path to produce a first optical path length difference between the first and second optical paths, the first interferogram produced from interference between the first polarization and the electromagnetic radiation reflected from the first optical path, and the second interferogram produced from interference between the second polarization and the electromagnetic radiation reflected from the first optical path; selectively producing an offset in frequency between the first and second superimposed interferograms by directing the first polarization to a movable second mirror, and selectively controlling movement of the second mirror in the second optical path to produce a second optical path length difference between the first and second polarizations; and configuring the imaging transform spectrometer between a spectral imaging mode and a spectropolarimetric imaging mode by deactivating the movement of the movable first mirror to configure the imaging transform spectrometer into the spectral imaging mode, and activating the movement of the movable first mirror to configure the imaging transform spectrometer into the spectropolarimetric imaging mode. 8. The imaging method of claim 7 , further comprising: configuring the imaging transform spectrometer into a broadband spatial imaging mode by: deactivating the movement of the movable first mirror; deactivating the movement of the movable second mirror; and imparting a vibration to one of the movable first mirror and the movable second mirror to substantially prevent formation of the first and second interferograms at the at least one imaging sensor. 9. The imaging method of claim 7 , wherein splitting the electromagnetic radiation in the second optical path into the first and second orthogonal polarizations includes splitting the electromagnetic radiation in the second optical path into a vertical polarization component and a horizontal polarization component. 10. The imaging method of claim 7 , wherein splitting the electromagnetic radiation in the second optical path into the first and second orthogonal polarizations includes: reflecting the second polarization from a polarizing beamsplitter; and transmitting the first polarization through the polarizing beamsplitter to the movable second mirror; and wherein selectively producing the offset in frequency further includes reflecting the first polarization with the movable second mirror. 11. The imaging method of claim 7 , wherein splitting the electromagnetic radiation in the second optical path into the first and second orthogonal polarizations includes: directing the first polarization to the movable second mirror using a polarizing beamsplitter; directing the second polarization to a fixed third mirror; and reflecting the second polarization with the fixed third mirror. 12. The imaging method of claim 7 , wherein the first interferogram comprises a first range of measured frequencies and the second interferogram comprises a second range of measured frequencies, and wherein selectively producing the offset in frequency includes producing a sufficient offset in frequency such that the first and second ranges of measured frequencies do not overlap. 13. A multimode configurable imaging spectropolarimeter comprising: a first beamsplitter configured to split incident electromagnetic radiation