Substrate-type optical waveguide element

The invention claimed is: 1. A substrate-type optical waveguide element comprising: a lower cladding; a core on the lower cladding, the core including a first core and a second core arranged side by side and a third core having an entrance edge surface connected to emission edge surfaces of the first core and the second core; and an upper cladding on the lower cladding, the upper cladding covering the core, the first core and the second core being arranged side by side in a side-by-side arrangement section that is started in a starting point corresponding to entrance edge surfaces of the first core and the second core and is ended in an ending point corresponding to the emission edge surfaces of the first core and the second core, an effective refractive index of a TE0 polarized wave guided through the first core in the absence of the second core being lower than an effective refractive index of a TE0 polarized wave guided through the second core in the absence of the first core, each of the effective refractive indexes being observed in the starting point of the side-by -side arrangement section. an effective refractive index of a TM0 polarized wave guided through the first core in the absence of the second core and the effective refractive index of the TE0 polarized wave guided through the second core in the absence of the first core being continuous as a function of a distance from the starting point of the side-by-side arrangement section, a magnitude relationship between an effective refractive index of an odd mode of a TE0 polarized wave guided through the core and an effective refractive index of an even mode of a TM0 polarized wave guided through the core being reversed between the starting point and the ending point of the side-by-side arrangement section, a refractive index distribution in a cross-section of the substrate-type optical waveguide element being vertically asymmetrical, the cross-section being perpendicular to a traveling direction of light guided through the core, the cross-section being in an interaction section, in which the odd mode of the TE0 polarized wave guided through the core and the even mode of the TM0 polarized wave guided through the core interact with each other. 2. The substrate-type optical waveguide element as set forth in claim 1 , wherein the emission edge surface of the first core and the emission edge surface of the second core are apart from each other. 3. The substrate-type optical waveguide element as set forth in claim 1 , wherein the emission edge surface of the first core and the emission edge surface of the second core are congruent with each other, wherein a cross-section of the core which cross -section is located in an entrance side of the ending point of the side-by-side arrangement section has a horizontally symmetric shape, and a cross-section of the core which cross-section is located in an emission side of the ending point of the side-by-side arrangement section has a horizontally symmetric shape, and wherein a symmetric axis of the cross-section of the core which cross-section is located in the entrance side of the ending point of the side-by-side arrangement section and a symmetric axis of the cross-section of the core which cross-section is located in the emission side of the ending point of the side-by-side arrangement section coincide with each other. 4. The substrate-type optical waveguide element as set forth in claim 1 , wherein a width W 1out of the emission edge surface of the first core, a width W 2out of the emission edge surface of the second core, and a width W 3in of the entrance edge surface of the third core satisfy W 1out +W 2out >W 3in . 5. The substrate-type optical waveguide element as set forth in claim 1 , wherein a distance between the first core and the second core is gradually reduced as the distance is located closer to the ending point from the starting point in the side-by-side arrangement section. 6. The substrate-type optical waveguide element as set forth in claim 1 , wherein the core further includes a slab via which the first core and the second core are communicated with each other in the interaction section, the slab having a height lower than heights of the first core and the second core. 7. The substrate-type optical waveguide element as set forth in claim 6 , further comprising: a fourth core having an emission edge surface connected with the entrance edge surface of the first core; and a fifth core having an emission edge surface connected with the entrance edge surface of the second. core, wherein a distance between the fourth core and the fifth core increases as the distance is located further from the starting point of the side-by-side arrangement section. 8. The substrate-type optical waveguide element as set forth in claim 7 , further comprising: a slab via which the fourth core and the fifth core are communicated with each other, the slab having a height identical to the height of the slab via which the first core and the second core are communicated with each other; a first tapered part having a height identical to the height of the slab, the first tapered part being communicated with the fourth core and the slab via which the fourth core and the fifth core are communicated with each other, the first tapered part having a width increasing as the width is located further from an entrance edge surface of the fourth core; and a second tapered part having a height identical to the height of the slab, the second tapered part being communicated with the fifth core and the slab via which the fourth core and the fifth core are communicated with each other, the second tapered part having a width increasing as the width is located further from an entrance edge surface of the fifth core. 9. The substrate-type optical waveguide element as set forth in claim 1 , wherein the lower cladding and the upper cladding are made of materials having different refractive indexes. 10. The substrate-type optical waveguide element as set forth in claim 1 , wherein each of the first core, the second core, and the third core has a cross-sectional shape of a trapezoid or a quasi-trapezoid. 11. The substrate-type optical waveguide element as set forth in claim 1 , further comprising: a first phase modulator for modulating a TE0 polarized wave; and a second phase modulator for modulating a TE0 polarized wave, wherein the entrance edge surface of the first core is supplied with a TE0 polarized wave modulated by the first phase modulator, and the entrance edge surface of the second core is supplied with a TE0 polarized wave modulated by the second phase modulator. 12. A substrate-type optical waveguide element comprising: a lower cladding; a core on the lower cladding, the core including a first core and a second core arranged side by side and a third core having an entrance edge surface connected to emission edge surfaces of the first core and the second core; and an upper cladding on the lower cladding, the upper cladding covering the core, the first core and the second core being arranged side by side in a side-by-side arrangement section that is started in a starting point corresponding to entrance edge surfaces of the first core and the second core and is ended in an ending point corresponding to the emission edge surfaces of the first core and the second core, an effective refractive index of a TE0 polarized wave guided through the first core in the absence of the second core being lower than an effective refractive index of a TE0 polarized wave guided through the second core in the absence of the first core, each of the effective refractive indexes being ob