Optical functional integrated unit and method for manufacturing thereof

The invention claimed is: 1. An optical functional integrated unit comprising: a mounting board; a first pedestal and a second pedestal that are provided on the mounting board; a positive optical device that is a semiconductor optical amplifier mounted on the first pedestal and configured to output a light from an active layer; and a passive optical device that is an external oscillator mounted on the second pedestal, wherein the passive optical device comprises: a silicon waveguide through which the light output from the positive optical device is guided; a substrate; a first ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the first ring resonator being configured by silicon; a second ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the second ring resonator having a different diameter from the first ring resonator, the second ring resonator being configured by silicon; a mirror that is formed at an end opposite to an end at a side of the positive optical device; a first electrode that is formed on the first ring resonator; a second electrode that is formed on the second ring resonator; a first polarization-separation unit that separates a polarization-multiplexed and phase-modulated optical signal input from outside into a first TE component and a first TM component; a second polarization-separation unit that separates a laser light exiting from the mirror into a second TE component and a second TM component; a first interferometer that causes the first TE component to interfere with the second TE component to output two optical signals, the phases of the two optical signals being different by 90 degrees; and a second interferometer that causes the first TM component to interfere with the second TM component to output two optical signals, the phases of the two optical signals being different by 90 degrees. 2. The optical functional integrated unit according to claim 1 , wherein the positive optical device comprises a first non-reflective film formed on an end at a side of the passive optical device of the active layer. 3. The optical functional integrated unit according to claim 2 , wherein the passive optical device further comprises a second non-reflective film formed on the end at the side of the positive optical device of the silicon waveguide. 4. The optical functional integrated unit according to claim 3 , wherein a refractive-index matching material is filled between the positive optical device and the passive optical device. 5. The optical functional integrated unit according to claim 1 , wherein heights of the first pedestal and the second pedestal are determined to bring a position of the active layer from a surface of the mounting board into line with a position of the silicon waveguide from the surface of the mounting board. 6. The optical functional integrated unit according to claim 1 , further comprising: a first mark pattern that is formed on the positive optical device and the passive optical device; a second mark pattern that is formed on the first pedestal and second pedestal, or the mounting board, wherein the first mark pattern and second mark pattern are configured to be able to perform position alignment using a light that has a wavelength capable of passing through the positive optical device and the passive optical device. 7. A method for manufacturing an optical functional integrated unit comprising: forming a first pedestal and second pedestal on a mounting board; mounting an positive optical device on the first pedestal, the positive optical device being a semiconductor optical amplifier configured to output a light from an active layer; and mounting an passive optical device on the second pedestal, wherein the passive optical device is an external oscillator comprising: a silicon waveguide to which the light output from the positive optical device is guided; a substrate; a first ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the first ring resonator being configured by silicon; a second ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the second ring resonator having a different diameter from the first ring resonator, the second ring resonator being configured by silicon; a mirror that is formed at an end opposite to an end at a side of the positive optical device; a first electrode that is formed on the first ring resonator; a second electrode that is formed on the second ring resonator; a first polarization-separation unit that separates a polarization-multiplexed and phase-modulated optical signal input from outside into a first TE component and a first TM component; a second polarization-separation unit that separates a laser light exiting from the mirror into a second TE component and a second TM component; a first interferometer that causes the first TE component to interfere with the second TE component to output two optical signals, the phases of the two optical signals being different by 90 degrees; and a second interferometer that causes the first TM component to interfere with the second TM component to output two optical signals, the phases of the two optical signals being different by 90 degrees. 8. An optical functional integrated unit comprising: a mounting board; a first pedestal and a second pedestal that are provided on the mounting board; a positive optical device that is mounted on the first pedestal and outputs a light from an active layer; and a passive optical device that is mounted on the second pedestal, wherein the passive optical device comprises: a silicon waveguide through which the light output from the positive optical device is guided; a first polarization-separation unit that separates a polarization-multiplexed and phase-modulated optical signal input from outside into a first TE component and a first TM component; a second polarization-separation unit that separates a laser light into a second TE component and a second TM component; a first interferometer that causes the first TE component to interfere with the second TE component to output two optical signals, the phases of the two optical signals being different by 90 degrees; and a second interferometer that causes the first TM component to interfere with the second TM component to output two optical signals, the phases of the two optical signals being different by 90 degrees. 9. The optical functional integrated unit according to claim 8 , wherein the positive optical device is a semiconductor optical amplifier. 10. The optical functional integrated unit according to claim 9 , wherein the passive optical device is an external oscillator, and the semiconductor optical amplifier and the external oscillator constitute a wavelength-tunable laser. 11. The optical functional integrated unit according to claim 10 , wherein the passive optical device further comprises: a substrate; a first ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the first ring resonator being configured by silicon; a second ring resonator that is formed on the substrate and optically connected to the silicon waveguide, the second ring resonator having a different diameter from the first ring resonator, the second ring resonator being configured by silicon; a mirror that is formed at an end opposite to an end at a side of the positive optical device; a first electrode that is formed on the first ring resonator; and a second electrode that is formed on the second ring resonator.