Optical waveguide element

The invention claimed is: 1. An optical waveguide element, comprising: as a core section, a rib waveguide including (i) a protruding section and (ii) two non-protruding sections shorter than the protruding section and so arranged in a first direction as to sandwich the protruding section, the core section having a first core region and a second core region overlapping with each other in a second direction, which is perpendicular to the first direction, and configured to form a PN junction, the optical waveguide element being configured to form, between the first core region and the second core region, a depletion layer extending from the protruding section to both of the two non-protruding sections, the depletion layer having a position in the second direction in each of the two non-protruding sections which position is lower than a position, in the second direction, of the depletion layer in the protruding section. 2. The optical waveguide element according to claim 1 , wherein the depletion layer extends from the protruding section to both the two non-protruding sections. 3. The optical waveguide element according to claim 1 , wherein the depletion layer has at least one end in the first direction which at least one end is positioned so that light guided through the core section has an electric field having an attenuation rate of not more than 13 dB relative to a peak value of the electric field in the core section. 4. The optical waveguide element according to claim 1 , wherein in at least one of the two non-protruding sections, the first core region has a thickness in the second direction which thickness is equal to a thickness, in the second direction, of the second core region. 5. The optical waveguide element according to claim 1 , wherein the optical waveguide element has a first tapered section having a tapered shape such that the two non-protruding sections each have a width in the first direction which width is smaller at a position closer to a first one of a light-entering end and a light-exiting end of the first tapered section, and a second tapered section adjacent to a second one of the light-entering end and the light-exiting end of the first tapered section and having a tapered shape such that the protruding section has a width in the first direction which width is smaller at a position closer to a first one of a light-entering end and a light-exiting end of the second tapered section. 6. The optical waveguide element according to claim 1 , wherein in at least one of the two non-protruding sections, the depletion layer has a height of hs/2 in the second direction (where hs is a thickness of the at least one of the two non-protruding sections) relative to a height, in the second direction, of a lower surface of the core section. 7. The optical waveguide element according to claim 1 , wherein in the protruding section, the depletion layer has a height of not less than hs/2 and not more than hr−hs/2 in the second direction (where hs is a thickness of at least one of the two non-protruding sections, and hr is a thickness of the protruding section) relative to a height, in the second direction, of a lower surface of the core section. 8. The optical waveguide element according to claim 7 , wherein in a case where the depletion layer overlaps with the electric field of the guided light by a maximum area, (i) in the protruding section, the first core region has a lower surface with a height of hr/2−hs/2 in the second direction relative to the height of the lower surface of the core section, and (ii) in the protruding section, the second core region has an upper surface with a height of hr/2+hs/2 in the second direction relative to the height of the lower surface of the core section. 9. The optical waveguide element according to claim 7 , wherein the protruding section has an undoped region, in which no dopant has intentionally been implanted, at least either directly above or directly below the first core region and the second core region. 10. An optical waveguide element, comprising: as a core section, a rib waveguide including (i) a protruding section and (ii) two non-protruding sections shorter than the protruding section and so arranged in a first direction as to sandwich the protruding section, the core section having a first core region and a second core region overlapping with each other in a second direction, which is perpendicular to the first direction, and configured to form a PN junction, the optical waveguide element being configured to form, between the first core region and the second core region, a depletion layer extending from the protruding section to at least one of the two non-protruding sections, in a case where the depletion layer overlaps with an electric field of guided light by a maximum area, (i) in the protruding section, the first core region having a lower surface with a height of hr/2−hs/2 in the second direction (where hs is a thickness of at least one of the two non-protruding sections, and hr is a thickness of the protruding section) relative to a height of a lower surface of the core section, and (ii) in the protruding section, the second core region having an upper surface with a height of hr/2+hs/2 in the second direction relative to the height of the lower surface of the core section. 11. The optical waveguide element according to claim 1 , wherein the depletion layer includes a first portion extending in the first direction and disposed in the protruding section, and two second portions extending in the first direction and disposed in the two non-protruding sections, respectively, and wherein each of the two second portions has a position in the second direction lower than a position, in the second direction, of the first portion.