Vehicle radar apparatus and method of controlling the same

What is claimed is: 1. A radar apparatus comprising: an antenna unit including Nt transmitting antennas and Nr receiving antennas, wherein one of the Nt transmitting antennas is vertically offset from the other transmitting antennas, or one of the Nr receiving antennas is vertically offset from the other receiving antennas, and Nt and Nr are natural numbers that are greater than or equal to 2; a transceiver configured to control the Nt transmitting antennas to transmit a first transmission signal including a plurality of chirp signals having a same phase through a first transmission antenna among Nt transmitting antennas, and transmit a second transmission signal, which is a phase shift transmission signal having N different phase shift values (a n ), through a second transmission antenna among Nt trasnmitting antennas, and control the Nr receiving antennas to receive a reflected signal reflected from a target; and a signal processor configured to determine a height (h) of the target based on a discrete phase shift value (a max ) that is a phase shift value having greatest reception power among N phase shift values. 2. The radar apparatus of claim 1 , wherein the transceiver divides the phase shift transmission signal having the N phase shift values by time index or sequence to transmit the phase shift transmission signal. 3. The radar apparatus of claim 2 , wherein the N phase shift values of the phase shift transmission signal are 0°, (360/N)°, ((360×2)/N)°, . . . , and ((360×(N−1))/N)°. 4. The radar apparatus of claim 1 , wherein the transceiver transmits the phase shift transmission signal through beamforming centered at an azimuth angle of 0°. 5. The radar apparatus of claim 1 , wherein the signal processor determines a maximum phase shift value (â) using the discrete phase shift value (a max ) and determines the height (h) of the target based on the maximum phase shift value. 6. The radar apparatus of claim 5 , wherein the signal processor determines an elevation angle (θ ele ) of the target based on the maximum phase shift value (â) and determines the height (h) of the target based on a distance (R) to the target and the elevation angle (θ ele ) of the target. 7. The radar apparatus of claim 2 , wherein: Nt is 2; and the phase shift transmission signal comprises a plurality of fast chirp signals. 8. The radar apparatus of claim 7 , wherein, when the time index is n, the phase shift transmission signal comprises a signal in which two fast chirp signals having phases of 0°+((360×n)/N)° and 180°+((360×n)/N)° are repeated, wherein n=0, 1, 2, . . . , and (N−1). 9. The radar apparatus of claim 7 , wherein the phase shift transmission signal comprises 2×N fast chirp signals having phases of 0°, 0°+((360)/N)°, 0°+((360×2)/N)°, . . . , and 0°+((360×(N−1))/N)°, and 180°, 180°+((360)/N)°, 180°+((360×2)/N)°, . . . , and 180°+((360×(N−1))/N)°. 10. The radar apparatus of claim 1 , wherein the transceiver forms (Nt−1)×Nr virtual receiving antennas. 11. A method of controlling a radar apparatus, the method comprising: transmitting a first transmission signal including a plurality of chirp signals having the same phase through a first transmission antenna among Nt transmitting antennas, and transmits a second transmission signal, which is a phase shift transmission signal having N different phase shift values, through a second transmission antenna among the Nt transmitting antennas, wherein Nt is a natural number that is greater than or equal to 2; receiving a reflected signal reflected from a target through Nr receiving antennas, wherein Nr is a natural number that is greater than or equal to 2; and determining a discrete phase shift value (a max ) which is a phase shift value having greatest reception power among the N phase shift values and determining a height (h) of the target based on the determined discrete phase shift value (a max ). 12. The method of claim 11 , wherein one of the Nt transmitting antennas is vertically offset from the other transmitting antennas, or one of the Nr receiving antennas is vertically offset from the other receiving antennas. 13. The method of claim 12 , wherein the transmitting of the phase shift transmission signal comprises dividing the phase shift transmission signal having the N phase shift values by time index or sequence to transmit the phase shift transmission signal. 14. The method of claim 12 , wherein the N phase shift values of the phase shift transmission signal are 0°, (360/N)°, ((360×2)/N)°, . . . , and ((360×(N−1))/N)°. 15. The method of claim 12 , wherein the transmitting of the phase shift transmission signal comprises transmitting the phase shift transmission signal through beamforming centered at an azimuth angle of 0°. 16. The method of claim 12 , wherein the determining of the height (h) of the target comprises determining a maximum phase shift value (â) using the discrete phase shift value (a max ) and determining the height (h) of the target based on the maximum phase shift value. 17. The method of claim 16 , wherein the determining of the height (h) of the target comprises determining an elevation angle (θ ele ) of the target based on the maximum phase shift value (â) and determining the height (h) of the target based on a distance (R) to the target and the elevation angle (θ ele ) of the target. 18. The method of claim 13 , wherein: Nt is 2; and the phase shift transmission signal comprises a plurality of fast chirp signals. 19. The method of claim 18 , wherein, when the time index is n, the phase shift transmission signal comprises a signal in which two fast chirp signals having phases of 0°+((360×n)/N)° and 180°+((360×n)/N)° are repeated, wherein n=0, 1, 2, . . . , and (N−1). 20. The method of claim 18 , wherein, when the phase shift transmission signal comprises 2×N fast chirp signals having phases of 0°, 0°+((360)/N)°, 0° ((360×2)/N)°, . . . , and 0°+((360×(N−1))/N)°, and 180°, 180°+((360)/N)°, 180°+((360×2)/N)°, . . . , and 180°+((360×(N−1))/N)°.