Phase adjustment device, phase difference detecting device and phase-adjusting method

What is claimed is: 1. A phase adjustment device comprising: a detection signal generator configured to generate a pair of first and second detection signals for detecting a phase difference between two signals whose phases have been adjusted by two phase adjusters, respectively, a maximum sensitivity phase difference of one of the first and second detection signals being not overlap with that of the other, and detection sensitivity of the phase difference becoming maximum at the maximum sensitivity phase difference; a detection signal selector configured to select one of the first and second detection signals whose predetermined range around the maximum sensitivity phase difference covers a preset phase difference; and a phase controller configured to control an amount of phase-adjusting by at least one of the two phase adjusters based on a difference between the phase difference detected within the predetermined range using the selected detection signal and the preset phase difference. 2. The phase adjustment device according to claim 1 , wherein the detection signal generator comprises: a first branch unit configured to branch one of the two signals into first and second branch signals; a second branch unit configured to branch the other of the two signals into third and fourth branch signals; a first delayer configured to generate a first delayed signal obtained by delaying a phase of the first branch signal; a second delayer configured to generate a second delayed signal obtained by delaying a phase of the third branch signal; a first mixer configured to generate a first synthesized signal obtained by synthesizing the first delayed signal and the fourth branch signal; a second mixer configured to generate a second synthesized signal obtained by synthesizing the second delayed signal and the second branch signal; an adder configured to add the first synthesized signal and the second synthesized signal so as to generate the first detection signal; and a subtractor configured to subtract the second synthesized signal from the first synthesized signal so as to generate the second detection signal. 3. The phase adjustment device according to claim 2 , wherein the first detection signal is in proportion to cos θ·cos φ and the second detection signal is in proportion to sin θ·cos φ, when it is assumed that φ is an amount of phase-delaying by the first delayer and the second delayer, and θ is the phase difference detected by using the first and second detection signals. 4. The phase adjustment device according to claim 2 , wherein the amount of phase-delaying by the first delayer and the second delayer is set to any other value than π/2·n, and wherein n is zero or an integer. 5. The phase adjustment device according to claim 2 , wherein the amount of phase-delaying by the first delayer and the second delayer is set to π·(1/4+n/2), wherein n is zero or an integer. 6. The phase adjustment device according to claim 1 , wherein the maximum sensitivity phase difference of the first detection signal is ±π/2, and the maximum sensitivity phase difference of the second detection signal is zero or π. 7. The phase adjustment device according to claim 2 , wherein the amount of phase-delaying by the first and second delayers is variable, and wherein the detection signal generator further comprises a delay amount controller configured to control the amount of phase-delaying by the first and second delayers based on the preset phase difference so as to maximize an amplitude of the first detection signal or an amplitude of the second detection signal. 8. The phase adjustment device according to claim 2 , wherein the detection signal generator further comprises: a first differential signal converter configured to convert the fourth branch signal into a first differential signal; and a second differential signal converter configured to convert the second branch signal into a second differential signal, and wherein the first mixer is configured to generate the first synthesized signal obtained by synthesizing the first delayed signal and the fourth branch signal converted into the first differential signal, and wherein the second mixer is configured to generate the second synthesized signal obtained by synthesizing the second delayed signal and the second branch signal converted into the second differential signal. 9. The phase adjustment device according to claim 2 , wherein the detection signal generator further comprises: a third differential signal converter configured to convert one of the two signals into a third differential signal; and a fourth differential signal converter configured to convert the other of the two signals into a fourth differential signal, wherein the first branch unit branches the third differential signal into the first and second branch signals, wherein the second branch unit branches the fourth differential signal into the third and fourth branch signals, wherein the first delayer is configured to generate the first delayed signal obtained by delaying the phase of the first branch signal as a differential signal, wherein the second delayer is configured to generate the second delayed signal obtained by delaying the phase of the third branch signal as a differential signal, wherein the first mixer is configured to generate the first synthesizing signal obtained by synthesizing the first delayed signal as the differential signal and the fourth branch signal, and wherein the second mixer is configured to generate the second synthesized signal obtained by synthesizing the second delayed signal as the differential signal and the second branch signal. 10. A phase-adjusting method comprising: generating a pair of first and second detection signals for detecting a phase difference between two signal whose phases have been adjusted by two phase adjusters, respectively, a maximum sensitivity phase difference of one of the detection signals being not overlap with that of the other, and detection sensitivity of the phase difference becoming maximum at the maximum sensitivity phase difference; selecting one of the first and second detection signals whose predetermined range around the maximum sensitivity phase difference covers a preset phase difference; and controlling an amount of phase-adjusting by at least one of the two phase adjusters based on a difference between the phase difference detected within the predetermined range using the selected detection signal and the preset phase difference.