Lidar with a plurality of laser light rays having different wavelengths

What is claimed is: 1. A lidar comprising: a CW laser light source that oscillates a plurality of CW laser light rays with different wavelengths; an optical branching unit that splits the CW laser light oscillated by the CW laser light source; a light modulator that modulates first CW laser light split by the optical branching unit; an optical fiber amplifier that amplifies the laser light modulated by the light modulator; a transmit-receive optical system that irradiates a target with the laser light amplified by the optical fiber amplifier, and that receives scattered light of the laser light by the target; a first optical multiplexer that mixes the scattered light received by the transmit-receive optical system and second CW laser light split by the optical branching unit, and that outputs mixed light of the scattered light and the CW laser light; a photodetector that receives the mixed light output from the first optical multiplexer, and that detects beat signals of the scattered light and the CW laser light; an information extractor that extracts information about the target from the beat signals detected with the photodetector, wherein propagation optical paths of light within the lidar are composed of an optical fiber, and the beat signals detected by the photodetector are superposition of spectral components of the beat signals derived from the plurality of CW laser light rays with different wavelengths. 2. The lidar according to claim 1 , wherein the CW laser light source consists of a plurality of CW laser light sources that oscillate CW laser light rays with wavelengths different from each other, and the lidar further comprises: a second optical multiplexer that mixes the CW laser light rays oscillated by the plurality of CW laser light sources. 3. The lidar according to claim 1 , further comprising: a laser light amplifier that further amplifies the laser light amplified by the optical fiber amplifier; and a transmit-receive light separator that passes the laser light amplified by the laser light amplifier to the transmit-receive optical system, and that causes the scattered light received by the transmit-receive optical system to propagate to the first optical multiplexer. 4. The lidar according to claim 3 , wherein the laser light amplifier is a spatial solid-state laser amplifier. 5. The lidar according to claim 3 , wherein the laser light amplifier is a solid-state laser amplifier with a planar waveguiding structure. 6. The lidar according to claim 1 , wherein wavelength difference between the plurality of CW laser light rays is greater than gain bandwidth of stimulated Brillouin scattering occurring in an optical fiber. 7. The lidar according to claim 6 , wherein the frequency difference between the plurality of CW laser light rays is not less than 100 MHz. 8. The lidar according to claim 1 , further comprising: a controller that controls the different wavelengths of each of the plurality of CW laser light rays based on the information about the target extracted by the information extractor. 9. The lidar according to claim 8 , wherein the CW laser light sources are composed of a semiconductor laser. 10. The lidar according to claim 1 , wherein the information about the target extracted by the information extractor includes a received signal strength of the scattered light, a round-trip time, and a Doppler frequency.