초록 ▼

A low-altitude altimeter (10) and a method of determining low altitudes for unmanned aerial vehicles (24). The altimeter includes at least two illuminators (12, 14), at least one sensor (16), and a computing device (18). The illuminators (12, 14) emit signals which are received by the sensor (16) in

A low-altitude altimeter (10) and a method of determining low altitudes for unmanned aerial vehicles (24). The altimeter includes at least two illuminators (12, 14), at least one sensor (16), and a computing device (18). The illuminators (12, 14) emit signals which are received by the sensor (16) in such a way that an angle at which they are received is determinable by the computing device (18). The computing device (18) processes each signal received by the sensor (16), determines the angle at which the sensor (16) received the signal, and, based thereon, determines the altitude of the unmanned aerial vehicle (24). When a first pair of illuminators are arranged along a fuselage axis, and a second pair of illuminators are arranged orthogonally to that axis, the computing device can combine first and second altitude, pitch angle, and roll angle measurements to provide a more refined altitude determination.

대표청구항 ▼

1. An altimeter comprising: at least two illuminators, with each illuminator operable to emit a signal;a downwardly orientable sensor operable to receive the signals emitted by the illuminators and sense data pertaining to angles from which the sensor received each of the signals; anda computing dev

1. An altimeter comprising: at least two illuminators, with each illuminator operable to emit a signal;a downwardly orientable sensor operable to receive the signals emitted by the illuminators and sense data pertaining to angles from which the sensor received each of the signals; anda computing device in communication with the sensor and operable to determine the angle at which the sensor received each of the signals, and, based thereon, to determine an altitude. 2. The altimeter as set forth in claim 1, wherein the illuminators and the sensor are mounted to an undersurface of an aircraft and spaced apart a known distance. 3. The altimeter as set forth in claim 1, wherein the sensor is located between the illuminators. 4. The altimeter as set forth in claim 1, wherein the illuminators are lasers. 5. The altimeter as set forth in claim 1, wherein the sensor is a digital camera. 6. The altimeter as set forth in claim 1, further including a filter operable to pass to the sensor a limited range of wavelengths that includes the wavelengths of the signals emitted by the illuminators. 7. The altimeter as set forth in claim 1, wherein the altimeter includes two illuminators and one one-dimensional sensor. 8. The altimeter as set forth in claim 1, wherein the altimeter includes four illuminators and two one-dimensional sensors. 9. The altimeter as set forth in claim 1, wherein the altimeter includes four illuminators and one two-dimensional sensor. 10. The altimeter as set forth in claim 1, wherein the angle at which the sensor received the signals is represented in pixel data, and the computing device is operable to convert the pixel data into the altitude. 11. The altimeter as set forth in claim 1, wherein the altimeter includes four illuminators and two sensors, orthogonally arranged to measure height, pitch angle, and roll angle, and wherein the computing device is operable to combine the height, pitch angle, and roll angle measurements to determine the altitude. 12. The altimeter as set forth in claim 11, wherein the illuminators and the sensor are mounted to an undersurface of an aircraft, and wherein a first two of the illuminators are aligned with a fuselage axis of the aircraft to measure the pitch angle, and a second pair of the illuminators are aligned orthogonally to the fuselage axis to measure the roll angle. 13. A method of determining an altitude of an unmanned aerial vehicle, the method comprising the steps of: (a) emitting a first signal and a second signal from the unmanned aerial vehicle toward a terrain;(b) detecting the first signal and the second signal at the unmanned aerial vehicle;(c) determining a first angle at which the first signal was detected and a second angle at which the second signal was detected; and(d) determining the altitude of the unmanned aerial vehicle as a function of the first and second angles. 14. The method according to claim 13 further comprising mounting a sensor to an underside of the unmanned aerial vehicle, the sensor detecting the first signal and the second signal. 15. The method according to claim 14 further comprising representing an angle at which the sensor received the signals in pixel data. 16. The method according to claim 13 wherein emitting a first signal and a second signal comprises emitting a first laser signal and a second laser signal. 17. A method of determining an altitude of an unmanned aerial vehicle, the method comprising the steps of: (a) emitting a first signal and a second signal from the unmanned aerial vehicle toward a terrain;(b) detecting the first signal and the second signal at the unmanned aerial vehicle;(c) determining a first angle at which the first signal was detected and a second angle at which the second signal was detected;(d) determining the altitude of the unmanned aerial vehicle as a function of the first and second angles; and(e) mounting a sensor to an underside of the unmanned aerial vehicle, the sensor detecting the first signal and the second signal.