Pulse radar device and control method therefor

What is claimed is: 1. A pulse radar device comprising: a pulse sequence generator that, in operation, generates a pulse sequence using two sub-pulse sequences including a first sub-pulse sequence and a second sub-pulse sequence, wherein the two sub-pulse sequences are complementary codes and satisfy constraint conditions including: (i) a sum of a total of odd-numbered terms of correlation calculation value between the first sub-pulse sequence and the first sub-pulse sequence having a specified timing deviation and a total of odd-numbered terms of correlation calculation value between the second sub-pulse sequence and the second sub-pulse sequence having the specified timing deviation is zero, and (ii) a sum of a total of even-numbered terms of the correlation calculation value between the first sub-pulse sequence and the first sub-pulse sequence having the specified timing deviation and a total of even-numbered terms of correlation calculation value between the second sub-pulse sequence and the second sub-pulse sequence having the specified timing deviation is zero; a Π/2-BPSK modulator that, in operation, generates modulation signals resultant from Π/2-BPSK modulation of the first sub-pulse sequence and the second sub-pulse sequence; a first phase rotator that, in operation, applies phase rotation by a first phase to the modulation signals for every specified number of pulses; and a radio transmitter that, in operation, transmits the modulation signals having undergone the phase rotation. 2. The pulse radar device according to claim 1 , further comprising: a radio receiver that, in operation, receives reflected signals that are the transmitted modulation signals reflected by a target; a second phase rotator that, in operation, applies phase rotation by a second phase that is opposite to the first phase for the reflected signals; and a correlator that, in operation, performs correlation calculation on an output of the second phase rotator, based on the modulation signals that are outputs of the Π/2-BPSK modulator. 3. The pulse radar device according to claim 1 , further comprising: a phase comparator that, in operation, provides a specified phase for the modulation signals that are outputs of the Π/2-BPSK modulator and rotates positions of signal points of the modulation signals on IQ plane in a specified direction for each of the sub-pulses. 4. The pulse radar device according to claim 3 , comprising: a radio receiver that, in operation, receives reflected signals; and a phase provider that, in operation, provides the specified phase, provided by the phase comparator for each of the sub-pulses, for the received reflected signals that are the transmitted modulation signals reflected by a target. 5. The pulse radar device according to claim 2 , wherein the correlator includes a correlation circuit corresponding to BPSK modulation scheme, a phase rotator disposed in an input stage of the correlation circuit, and a phase reverse rotator disposed in an output stage of the correlation circuit. 6. The pulse radar device according to claim 2 , wherein the pulse sequence is Golay code and wherein the correlator adds values corresponding to Π/2 and Π phase rotation respectively to a multiplication constant in a first stage and a multiplication constant in a second stage in a Golay correlator. 7. The pulse radar device according to claim 1 , wherein the pulse sequence generator further generates a third sub-pulse sequence in reverse order of the first sub-pulse sequence and a fourth sub-pulse sequence in reverse order of the second sub-pulse sequence, and repetitively outputs four pulses generated from the first sub-pulse sequence, the second sub-pulse sequence, the third sub-pulse sequence, and the fourth sub-pulse sequence, while changing an order of the four pulses, and wherein the first phase rotator provides the phase rotation for every set of the four pulses. 8. The pulse radar device according to claim 1 , wherein the pulse sequence generator further generates a third sub-pulse sequence in reverse order of the first sub-pulse sequence and a fourth sub-pulse sequence in reverse order of the second sub-pulse sequence and repetitively outputs four pulses generated from the first sub-pulse sequence, the second sub-pulse sequence, the third sub-pulse sequence, and the fourth sub-pulse sequence, while changing an order of the four pulses, and wherein the first phase rotator provides the same amount of the phase rotation for first two pulses in the first sub-pulse sequence and for the second sub-pulse sequence and for second two pulses in the third sub-pulse sequence and the fourth sub-pulse sequence. 9. A control method comprising: a pulse sequence generating step of generating a pulse sequence using two sub-pulse sequences, which are complementary codes and satisfy constraint conditions, the two sub-pulse sequences including a first sub-pulse sequence and a second sub-pulse sequence and the constraint conditions including: (i) a sum of a total of odd-numbered terms of correlation calculation value between the first sub-pulse sequence and the first sub-pulse sequence having a specified timing deviation and a total of odd-numbered terms of correlation calculation value between the second sub-pulse sequence and the second sub-pulse sequence having the specified timing deviation is zero, and (ii) a sum of a total of even-numbered terms of the correlation calculation value between the first sub-pulse sequence and the first sub-pulse sequence having the specified timing deviation and a total of even-numbered terms of correlation calculation value between the second sub-pulse sequence and the second sub-pulse sequence having the specified timing deviation is zero; a Π/2-BPSK modulating step of generating modulation signals resultant from Π/2-BPSK modulation of the first sub-pulse sequence and the second sub-pulses sequence; a first phase rotating step of applying phase rotation by a first phase to the modulation signals for every specified number of pulses; and a radio transmitting step of transmitting the modulation signals having undergone the phase rotation.