Synthetic aperture radar and processing method of reproducing synthetic aperture radar image
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01S-013/90
G01S-013/00
출원번호
UP-0033485
(2008-02-19)
등록번호
US-7705767
(2010-05-20)
우선권정보
JP-2007/043093(2007-02-23)
발명자
/ 주소
Fujimura, Takashi
출원인 / 주소
NEC Corporation
인용정보
피인용 횟수 :
3인용 특허 :
14
초록▼
A synthetic aperture radar to provide high resolution in the azimuth direction under the predetermined conditions of wide observation swathwidth in the range direction, stripmap observation and free PRF (Pulse Repetition Frequency) comprises a transmission antenna 102 for a single system and receivi
A synthetic aperture radar to provide high resolution in the azimuth direction under the predetermined conditions of wide observation swathwidth in the range direction, stripmap observation and free PRF (Pulse Repetition Frequency) comprises a transmission antenna 102 for a single system and receiving antennae 104a, 104b for two systems. The beam width in the azimuth direction of a transmission beam 103 from the transmission antenna 102 is set equal to twice as wide as the beam width of each of the receiving antennae 104a, 104b. Moreover, a receiving antenna beam 105a is directed to the moving direction, while the other receiving antenna beam 105b is directed to opposite to the moving direction. The transmission antenna 102 and the receiving antennae 104a, 104b for two systems are used in common by dividing a single array antenna in the elevation direction to configure the receiving antennae 104a, 104b. The antenna size of the transmission antenna 102 in the azimuth direction is set to one half of the antenna size of the receiving antennae 104a, 104b by phase setting of each element of the array antenna or by electrical means when transmitting.
대표청구항▼
What is claimed is: 1. A synthetic aperture radar for installation on a movable platform to acquire radar images along a given surface, the given surface selected from a plurality of surfaces comprising a ground surface and a sea surface, the synthetic aperture radar comprising: a transmission ante
What is claimed is: 1. A synthetic aperture radar for installation on a movable platform to acquire radar images along a given surface, the given surface selected from a plurality of surfaces comprising a ground surface and a sea surface, the synthetic aperture radar comprising: a transmission antenna to output a transmission antenna beam, the transmission antenna beam having a width in a direction in which the movable platform is to move along the given surface; a first receiving antenna to receive a first receiving antenna beam having a width that is half the width of the transmission antenna beam, where the first receiving antenna beam is directed to the direction in which the movable platform is to move along the given surface; and, a second receiving antenna to receive a second receiving antenna beam having a width that is half the width of the transmission antenna beam, where the second receiving antenna beam is directed to a direction opposite to the direction in which the movable platform is to move along the given surface. 2. The synthetic aperture radar of claim 1, further comprising a single array antenna divisible into a first array antenna portion and a second array antenna portion along a direction perpendicular to the direction in which the movable platform is to move along the given surface, wherein the first receiving antenna is the first array antenna portion of the single array antenna, and the second receiving antenna is the second array antenna portion of the single array antenna. 3. The synthetic aperture radar of claim 2, wherein the width of each of the first receiving antenna beam and the second receiving antenna beam is half the width of the transmission antenna beam by one of: phase setting each of a plurality of array antenna elements of the single array antenna; in an electrical manner, operationally decreasing an antenna size of the transmission antenna so that the antenna size of the transmission antenna is operationally equal to half of an antenna size of the first receiving antenna and to half of an antenna size of the second receiving antenna. 4. The synthetic aperture radar of claim 2, wherein the first receiving antenna beam is directed to the direction in which the movable platform is to move along the given surface, and the second receiving antenna beam is directed to the direction opposite to the direction in which the movable platform is to move along the given surface by: phase setting each of a plurality of array antenna elements of the single array antenna. 5. The synthetic aperture radar of claim 1, wherein the first receiving antenna and the second receiving antenna are separate antennas disposed along a direction perpendicular to the direction in which the movable platform is to move along the given surface, and wherein the transmission antenna is a same antenna as one or more of the separate antennas, such that the one or more of the separate antennas function as the transmission antenna. 6. The synthetic aperture radar of claim 1, wherein the transmission antenna, the first receiving antenna, and the second receiving antenna are separate antennas disposed along a direction perpendicular to the direction in which the movable platform is to move along the given surface. 7. The synthetic aperture radar of claim 6, wherein one of: an antenna size of the transmission antenna is physically equal to half of an antenna size of the first receiving antenna and half of an antenna size of the second receiving antenna along the direction in which the movable platform is to move along the given surface; in an electrical manner, the antenna size of the transmission antenna is operationally decreased so that the antenna size of the transmission antenna is operationally equal to half of the antenna size of the first receiving antenna and half of the antenna size of the second receiving antenna along the direction in which the movable platform is to move along the given surface. 8. The synthetic aperture radar of claim 1, wherein the transmission antenna, the first receiving antenna, and the second receiving antenna are separate antennas disposed along the direction in which the movable platform is to move along the given surface. 9. The synthetic aperture radar of claim 8, wherein one of: an antenna size of the transmission antenna is physically equal to half of an antenna size of the first receiving antenna and half of an antenna size of the second receiving antenna along the direction in which the movable platform is to move along the given surface; in an electrical manner, the antenna size of the transmission antenna is operationally decreased so that the antenna size of the transmission antenna is operationally equal to half of the antenna size of the first receiving antenna and half of the antenna size of the second receiving antenna along the direction in which the movable platform is to move along the given surface. 10. The synthetic aperture radar of claim 1, wherein the first receiving antenna is slanted towards the direction in which the movable platform is to move along the given surface by a distance equal to half the width of the transmission antenna beam, and the second receiving antenna is slanted towards the direction opposite to the direction in which the movable platform is to move along the given surface by the distance equal to half the width of the transmission antenna beam. 11. The synthetic aperture radar of claim 1, wherein the first receiving antenna beam represents first received data within a frequency domain encompassing a Doppler frequency domain, and the second receiving antenna beam represents second received data within the frequency domain encompassing the Doppler frequency domain, and wherein only the Doppler frequency domain of the first received data and only the Doppler frequency domain of the second received data are extracted from the first received data and the second received data, and then bandwidth-synthesized to yield single bandwidth-synthesized received data. 12. The synthetic aperture radar of claim 11, wherein the first receiving antenna has a first range distance between the first receiving antenna and a target, and the second receiving antenna has a second range distance between the second receiving antenna and the target, and wherein a correction is made for a difference between the first range distance and the second range distance during bandwidth-synthesis to yield the single bandwidth-synthesized received data. 13. The synthetic aperture radar of claim 1, wherein the radar is to produce an image of the given surface via a range Doppler approach using the transmission antenna, the first receiving antenna, and the second receiving antenna. 14. A method for producing an image of a given surface using a synthetic aperture radar installed on a movable platform and having a transmission antenna, a first receiving antenna, and a second receiving antenna, the given surface selected from a plurality of surfaces comprising a ground surface and a sea surface, the method comprising: setting a width of a transmission antenna beam of the transmission antenna equal to twice a width of a first receiving antenna beam of the first receiving antenna and equal to twice a width of a second receiving antenna beam of the second receiving antenna, along a direction in which the movable platform is moving along the given surface; directing the first receiving antenna to the direction in which the movable platform is moving along the given surface, and direction the second receiving antenna to a direction opposite to the direction in which the movable platform is moving along the given surface; and, producing the image of the given surface based on first received data represented by the first receiving antenna beam and based on second received data represented by the second receiving antenna beam.
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이 특허에 인용된 특허 (14)
Wolfgang Keydel DE; Helmut Suss DE; Karl-Heinz Zeller DE; Reinhard Schroder DE, Aircraft or spacecraft based synthetic aperture radar.
Newcomb Gary L. (Catonsville MD) Brandt Timothy E. (Hanover MD) Borden Scott C. (Greenbelt MD) Stevenson Joseph (Catonsville MD), Method and system for real aperture radar ground mapping.
Frosch Robert A. Administrator of the National Aeronautics and Space Administration ; with respect to an invention of ( La Canada CA) Jain Atul (La Canada CA), Multibeam single frequency synthetic aperture radar processor for imaging separate range swaths.
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