초록 ▼

By using two SAR antennas spaced a known distance, B, and oriented at substantially the same look angle to illuminate the same target area, pixel data from the two antennas may be compared in phase to determine a difference Δφ from which a slant angle θ is determined for each pixel point from an equ

By using two SAR antennas spaced a known distance, B, and oriented at substantially the same look angle to illuminate the same target area, pixel data from the two antennas may be compared in phase to determine a difference Δφ from which a slant angle θ is determined for each pixel point from an equation Δφ=(2πB/λ)sin(θ-α), where λ is the radar wavelength and α is the roll angle of the aircraft. The height, h, of each pixel point from the aircraft is determined from the equation h=R cos θ, and from the known altitude, a, of the aircraft above sea level, the altitude (elevation), a', of each point is determined from the difference a-h. This elevation data may be displayed with the SAR image by, for example, quantizing the elevation at increments of 100 feet starting at sea level, and color coding pixels of the same quantized elevation. The distance, d, of each pixel from the ground track of the aircraft used for the display may be determined more accurately from the equation d=R sin θ.

대표청구항 ▼

1. A method for determining the elevation of terrain features in synthetic aperture radar image data using two antennae spaced apart a fixed distance, B, on a platform which carries the radar over terrain at a known altitude, a, with respect to a fixed reference, where the distance B is measured in

1. A method for determining the elevation of terrain features in synthetic aperture radar image data using two antennae spaced apart a fixed distance, B, on a platform which carries the radar over terrain at a known altitude, a, with respect to a fixed reference, where the distance B is measured in a horizontal plane while the platform is in level flight, comprising the steps of separately processing the return signals from said antennae to the pixel level and determining the slant range, R, and phase difference, Δφ, of pixels from the return signals received through said two antennae from substantially the same point of said terrain, from said phase difference, Δφ, and said spacing, B, determining for each pixel the slant angle, θ, between the slant range and a vertical line from the radar platform to the terrain, determining the vertical height, h, of said platform above each pixel from the slant range R as a function of the cosine of the slant angle φ for each pixel, and for each pixel, determining elevation, a', above said fixed reference as the difference between said known altitude a of the radar platform and the determined height h of said platform with respect to a corresponding point on said terrain for each pixel. 2. A method as defined in claim 1 including the process of displaying said pixels with an indication of elevation. 3. A method as defined in claim 2 including the step of determining the horizontal distance, d, of each point on said terrain for each pixel from said vertical line and displaying each pixel at its distance from said vertical line. 4. A method as defined in claim 1 wherein said indication of elevation is displayed by quantizing elevation of pixels at predetermined constant intervals, and for pixels of equal quantized elevation, displaying intensity in a predetermined color distinct from all other colors used for other quantized elevations over at least a distinct band of quantized elevations. 5. A method as defined in claim 4 including the step of determining the horizontal distance, d, of each point on said terrain for each pixel from said vertical line and displaying each pixel at its distance from said vertical line. 6. A method for determining the elevation of terrain features in synthetic aperture radar image data using two antennae spaced apart a fixed distance, B, on a platform which carries the radar over terrain, where the distance B is measured in a horizontal plane while the platform is in level flight, comprising the step of separately processing the return signals from said antennae in complex vector form to the pixel level, and recording for each pixel from each antennae the altitude, a, of the radar platform above a fixed reference together with the roll angle, α, of the platform, determining the slant range, R, of pixels from the return signals received through said two antennae from substantially the same point of said terrain, from said pixel data in complex vector form, determining the phase difference, Δφ, between pixels received from substantially the same point through said separate antennae from the relationship expressed by the equation Δφ=(2πB/λ) sin (θ-α) where λ is the wavelength of said radar, determining the vertical height, h, of said platform above each pixel from the slant range as a function of the cosine of the slant angle R for each pixel, and for each pixel, determining elevation, a', with respect to said fixed reference as the difference between said known altitude a of the radar platform and the determined height h of said platform with respect to a corresponding point on said terrain for each pixel. 7. A method as defined in claim 6 including the process of displaying said pixels with an indication of elevation. 8. A method as defined in claim 6 including the step of determining the horizontal distance, d, of each point on said terrain for each pixel from said vertical line and displaying each pixel at its distance from said vertical line. 9. A method as defined in claim 7 wherein said indication of elevation is displayed by quantizing elevation of pixels at predetermined constant intervals, and for pixels of equal quantized elevation, displaying intensity in a predetermined color distinct from all other colors used for other quantized elevations over at least a distinct band of quantized elevations. 10. A method as defined in claim 9 including the step of determining the horizontal distance, d, of each point on said terrain for each pixel from said vertical line and displaying each pixel at its distance from said interval.