Polarization reducing apparatus, light source apparatus, optical amplifying apparatus, and excitation light source apparatus for raman amplification

What is claimed is: 1. A polarization reducing apparatus comprising: a separating unit configured to separate input light into components having polarization directions orthogonal to each other; a winding waveguide of silicon formed on a silicon substrate in a winding manner, the winding waveguide transmitting a first component among the components separated by the separating unit; an optical path configured to have a shorter optical path length than the winding waveguide and a lower refractive index than the winding waveguide, the optical path transmitting a second component among the components separated by the separating unit; a combining unit configured to combine the first component and the second component; and an output unit configured to output light including the first component and the second component combined by the combining unit, wherein the optical path is an optical path in which the second component propagates through space. 2. The polarization reducing apparatus according to claim 1 , further comprising a loss medium configured to induce an optical loss on the second component transmitted through the optical path, such that respective intensities of the first component and of the second component are equalized at the combining unit. 3. The polarization reducing apparatus according to claim 1 , wherein an optical path length difference between the winding waveguide and the optical path is greater than or equal to a coherence length of the input light. 4. The polarization reducing apparatus according to claim 1 , wherein the separating unit is a polarization separator configured to perform polarization separation of the input light into first light of a polarization component in a first direction and second light of a polarization component in a second direction orthogonal to the first direction, the winding waveguide transmits the first light, and the optical path transmits the second light. 5. The polarization reducing apparatus according to claim 4 , wherein the winding waveguide has a greater optical loss than the optical path, and the polarization reducing apparatus includes an adjusting unit configured to adjust the polarization direction of the input light input to the polarization separator into a polarization direction forming less than 45 degrees as a smaller angle among angles relative to the first direction. 6. The polarization reducing apparatus according to claim 5 , wherein the adjusting unit adjusts the polarization direction of the input light input to the polarization separator such that respective intensities of light transmitted through the silicon substrate and of the second component are equalized at the combining unit. 7. The polarization reducing apparatus according to claim 5 , comprising: a measuring device configured to measure a polarization degree of the light consisting of the first component and the second component combined by the combining unit, and a control circuit configured to control adjustment of the polarization direction of the input light by the adjusting unit, based on the polarization degree measured by the measuring device. 8. The polarization reducing apparatus according to claim 1 , wherein the winding waveguide is a silicon thin line ridge waveguide. 9. A light source apparatus comprising: a light source configured to emit light; a separating unit configured to separate the light emitted by the light source into components having polarization directions orthogonal to each other; a winding waveguide of silicon formed on a silicon substrate in a winding manner, the winding waveguide transmitting a first component among the components separated by the separating unit; an optical path configured to have a shorter optical path length than the winding waveguide and a lower refractive index than the winding waveguide, the optical path transmitting a second component among the components separated by the separating unit; a combining unit configured to combine the first component and the second component; and an output unit configured to output light including the first component and the second component combined by the combining unit, wherein the optical path is an optical path in which the second component propagates through space. 10. An optical amplifying apparatus comprising: a light source disposed in an amplifying apparatus that amplifies an optical signal transmitted through an optical fiber, and configured to emit light of a constant wavelength; a separating unit configured to separate the light emitted by the light source into components having polarization directions orthogonal to each other; a winding waveguide of silicon formed on a silicon substrate in a winding manner, the winding waveguide transmitting a first component among the components separated by the separating unit; an optical path configured to have a shorter optical path length than the winding waveguide and a lower refractive index than the winding waveguide, the optical path transmitting a second component among the components separated by the separating unit; a combining unit configured to combine the first component and the second component; and an input unit configured to input light including the first component and the second component combined by the combining unit, into the optical fiber that propagates the optical signal, wherein the optical path is an optical path in which the second component propagates through space. 11. An excitation light source apparatus for Raman amplification, the excitation light source apparatus comprising: a light source configured to emit excitation light; a waveguide that transmits the excitation light emitted from the light source and equipped with a diffraction grating configured to cause the excitation light output from the waveguide to have a constant wavelength; a separating unit configured to separate the excitation light output from the waveguide, into components having polarization directions orthogonal to each other; a winding waveguide of silicon formed on a silicon substrate in a winding manner, the winding waveguide transmitting a first component among the components separated by the separating unit; an optical path configured to have a shorter optical path length than the winding waveguide and a lower refractive index than the winding waveguide, the optical path transmitting a second component among the components separated by the separating unit; a combining unit configured to combine the first component and the second component; and an output unit configured to output light including the first component and the second component combined by the combining unit, wherein the optical path is an optical path in which the second component propagates through space.