IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0105096
(2011-05-11)
|
등록번호 |
US-8471759
(2013-06-25)
|
우선권정보 |
KR-10-2010-0046406 (2010-05-18) |
발명자
/ 주소 |
- Sun, Sun Gu
- Park, Gyu Churl
- Cho, Byung Lae
- Ha, Jong Soo
|
출원인 / 주소 |
- Agency for Defense Development
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
4 인용 특허 :
8 |
초록
▼
Disclosure is a forward-looking 3D imaging radar, comprising: a transmitting unit which generates RF signals to be radiated for observing object in front of the radar; a transmitting antenna which radiates the RF signal generated by the transmitting unit; a receiving antenna which receives signals r
Disclosure is a forward-looking 3D imaging radar, comprising: a transmitting unit which generates RF signals to be radiated for observing object in front of the radar; a transmitting antenna which radiates the RF signal generated by the transmitting unit; a receiving antenna which receives signals radiated from the transmitting antenna and reflected by the object in front of the radar; a receiving unit which mixes the signal received by the receiving antenna and the branched signal from the transmitting unit, and converts the signal to digital signal; and a signal processor which controls the operations of the transmitting unit and receiving unit, sends command to the transmitting unit to generate RF signals, receives the digitally converted signal from the receiving unit and extracts phase information of the object in front of the radar, and generates 3D radar image by producing altitude information based on the principle of interferometer.
대표청구항
▼
1. A forward-looking 3D imaging radar, comprising: a transmitting unit which generates RF signals to be radiated for observing object in front of the radar;a transmitting antenna which radiates the RF signal generated by the transmitting unit;a receiving antenna which receives signals radiated from
1. A forward-looking 3D imaging radar, comprising: a transmitting unit which generates RF signals to be radiated for observing object in front of the radar;a transmitting antenna which radiates the RF signal generated by the transmitting unit;a receiving antenna which receives signals radiated from the transmitting antenna and reflected by the object in front of the radar;a receiving unit which mixes the signal received by the receiving antenna and the branched signal from the transmitting unit, and converts the signal to digital signal; anda signal processor which controls the operations of the transmitting unit and receiving unit, sends command to the transmitting unit to generate RF signals, receives the digitally converted signal from the receiving unit, compensates phase using a phase compensation value (φcomp) calculated by the below formula using distance of motion of a vehicle measured by a tachometer installed on the vehicle, extracts phase information of the object in front of the radar, and generates 3D radar image by producing altitude information based on the principle of interferometer: ϕcomp=2π×fc×2×v×Tac where (φcomp) is the phase compensation value, fc is center frequency, v is velocity of the vehicle, c is velocity of light, and Ta corresponds to Tp (dwell time)+Td1 (time for preparing transmission of waveform through a second transmitting antenna). 2. The forward-looking 3D imaging radar of claim 1, wherein the transmitting unit comprises a DDS (Direct Digital Synthesizer) which generates transmitting waveform, a 4 channel filter bank which selects the transmitting waveform having the optimal frequency on the basis of the waveform generated by the DDS, and a high power amplifier which amplifies the output of the 4 channel filter bank. 3. The forward-looking 3D imaging radar of claim 1, wherein the transmitting unit generates RF signal of UWB signal of wider than 1 GHz. 4. The forward-looking 3D imaging radar of claim 1, wherein the transmitting antenna is composed of 2 antennas. 5. The forward-looking 3D imaging radar of claim 4, wherein an RF switch is installed between the transmitting antenna and transmitting unit to select an antenna among the two transmitting antennas. 6. The forward-looking 3D imaging radar of claim 1, wherein the receiving antenna is composed of an antenna array comprising a plurality unit antennas. 7. The forward-looking 3D imaging radar of claim 6, wherein the receiving antenna array is disposed in 2 dimensional arrays. 8. The forward-looking 3D imaging radar of claim 7, wherein the horizontal interval between the unit antennas in the receiving antenna array is set to λ/2 and the vertical interval is set to d≦λ, where λ is wavelength of the transmitting signal. 9. A method of acquiring 3D image by using a forward-looking 3D imaging radar comprising a transmitting unit which generates RF signals, a transmitting antenna which radiates the RF signal, a receiving antenna which receives signals reflected by the object in front of the radar, a receiving unit which converts the received signal to digital signal; and a signal processor which generates 3D radar image, which comprises the steps of: a) generating RF signals to be radiated for observing object in front of the radar;b) radiating the RF signal generated by the transmitting unit to the outside through transmitting antenna;c) receiving signals radiated from the transmitting antenna and reflected by the object in front of the radar;d) mixing the signal received by the receiving antenna and the signal branched from the transmitting unit, and converting the analog signal to digital signal; ande) receiving the digitally converted signal from the receiving unit through the signal processor, compensating phase using a phase compensation value (φcomp) calculated by the below formula using distance of motion of a vehicle measured by a tachometer installed on the vehicle, extracting phase information of the object in front of the radar, and generating 3D radar image by producing altitude information based on the principle of interferometer: ϕcomp=2π×fc×2×v×Tac where φcomp is the phase compensation value, fc is center frequency, v is velocity of the vehicle, c is velocity of light, and Ta corresponds to Tp (dwell time)+Td1 (time for preparing transmission of waveform through a second transmitting antenna). 10. The method of acquiring 3D image of claim 9, wherein beat frequency of the LFM (Linear Frequency Modulation) signal is detected and sampled in order to mix the signal received by the receiving antenna and the RF signal transmitted by the transmitting unit, and to convert the signal to digital signal. 11. The method of acquiring 3D image of claim 9, wherein the process of extracting phase information of the object in front of the radar and generating 3D radar image by producing altitude information based on the principle of interferometer in the step e) comprises the steps of: e-1) acquiring respective 2D radar image information by using the signals measured by the first and second rows of the receiving antenna;e-2) calculating phases (φ1,φ2) of each pixel from the image information acquired;e-3) calculating phase difference (φ=φ1−φ2) of two pixels from the phases (φ1,φ2) of each pixel calculated above;e-4) calculating altitude information (h) of the each pixel;e-5) determining whether all the pixels are calculated after calculating the phase difference (φ=φ1−φ2) and altitude information (h);e-6) returning the process to the step e-2), when all the pixels are not determined to be calculated in step e-5), for the first and second rows of the receiving antenna; ande-7) generating 3D image information map, when all the pixels are calculated in step e-5), based on one 2D image and the altitude information calculated in the step e-4). 12. The method of acquiring 3D image of claim 11, wherein calculating the phase difference (φ=φ1−φ2) in the step e-3) is carried out by using the formula: ϕ=ϕ1-ϕ2=2πλΔR,ΔR=λ2πϕ, where λ is the wavelength of the received signal, and ΔR is the difference between the measured distance R1 which is the distance from the first receiving antenna (Ant1) to the object in front of the antenna, and measured distance R2 which is the distance from the second receiving antenna (Ant2) to the object in front of the antenna. 13. The method of acquiring 3D image of claim 11, wherein the step of calculating the altitude information (h) in the step e-4) is calculated by the formula: h=H+d2-ΔR2d(2R+ΔR), where H is the height of the installed antenna, d is the distance between two antennas, R is the measured distance from the first receiving antenna (Ant1) to the object in front of the antenna, ΔR is the difference between the measured distance R1 which is the distance from the first receiving antenna (Ant1) to the object in front of the antenna, and measured distance R2 which is the distance from the second receiving antenna (Ant2) to the object in front of the antenna.
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