Optical radar device

What is claimed is: 1. An optical radar device comprising: a light source outputting pulse light; a light scanning section operating a mirror plate to reflect the pulse light toward an object and to reflect reflected light received from the object; a light path change section guiding the pulse light outputted from the light source toward the light scanning section and guiding the reflected light reflected by the light scanning section in a direction that is different from a light source direction; a light receiver that receives the reflected light; and an opposite phase signal adder that adds an opposite phase signal to the output signal from the light receiver, that delays, by a predetermined time, a rise timing of the opposite phase signal to match a timing at which stray light is received by the light receiver relative to an output timing of the pulse light, that adjusts the opposite phase signal to match both an amplitude of the stray light and a resulting waveform of the stray light, and the opposite phase signal has an opposite phase with respect to a phase of the reflected light. 2. The optical radar device of claim 1 , wherein a timing of the opposite phase signal is a timing at which stray light generated inside or near the optical radar device is received by the light receiver. 3. The optical radar device of claim 1 further comprising: an amplitude controller that controls an amplitude of the opposite phase signal. 4. The optical radar device of claim 3 , wherein the amplitude controller controls the amplitude of the opposite phase signal according to a device state of the optical radar device. 5. The optical radar device of claim 4 , wherein the device state of the optical radar device is at least one of plural factors which is chosen from a group of factors, the group of factors including a scanning direction of the light scanning section, an internal temperature of the optical radar device, and a cumulative use time of the light source. 6. The optical radar device of claim 4 , wherein the device state is determined based on each of a scanning direction of the light scanning section, an internal temperature of the optical radar device, and a cumulative use time of the light source. 7. The optical radar device of claim 4 , wherein the device state is a scanning direction of the light scanning section. 8. The optical radar device of claim 4 , wherein the device state is an internal temperature of the optical radar device. 9. The optical radar device of claim 4 , wherein the device state is a cumulative use time of the light source. 10. The optical radar device of claim 1 further comprising: a stray light detector that detects a stray light that is characterized, from among the lights received by the light receiver, as having a predetermined delay from an output timing of the pulse light and as being constantly existing; and an amplitude increaser that increases the amplitude of the opposite phase signal relative to the stray light detected by the stray light detector. 11. The optical radar device of claim 1 , wherein the opposite phase signal adder performs a digital operation for the addition of the opposite phase signal. 12. The optical radar device of claim 1 , wherein the opposite signal has an opposite phase relative to the phase of the stray light. 13. The optical radar device of claim 1 , wherein the opposite phase signal adder further includes a waveform rectifying circuit. 14. The optical radar device of claim 1 , wherein the stray light is different than the reflected light. 15. The optical radar device of claim 1 , further comprising a collimate lens that is located between the light source and the light path change section, and that is configured to convert the pulse light into linearly-polarized light, and a quarter wave plate that is located between the light path change section and the light scanning section, and that is configured to convert the pulse light from linearly-polarized light to circularly-polarized light, and to convert the reflected light from circularly-polarized light to linearly polarized light. 16. The optical radar device of claim 1 , wherein the opposite phase signal adder adjusts the opposite phase signal to match the resulting waveform of the stray light in response to different device states, which each include a distinct stray light pattern. 17. The optical radar device of claim 1 , wherein the stray light is a constantly-existing stray light.