Optical connector, optical connector system, and active optical cable provided with same

The invention claimed is: 1. An optical connector comprising: a connector body provided between and connecting a substrate on which an optical input/output end face of an optical waveguide is formed and a ferrule into which an optical input/output end face of an optical fiber is inserted, wherein the connector body is L-shaped and includes an upper surface wall that conforms to a substrate layer of said substrate, an end face wall formed to be orthogonal to said upper surface wall at an end of said upper surface wall on said ferrule side, and an intervening wall formed to said end face wall and made of a translucent material at a position between said optical input/output end face of said optical waveguide and said optical input/output end face of said optical fiber; and an optical waveguide-side lens facing said optical input/output end face of said optical waveguide and an optical fiber-side lens facing said optical input/output end face of said optical fiber, formed integrally with said intervening wall, provided at a position between said optical input/output end face of said optical waveguide and said optical input/output end face of said optical fiber and configured to send and receive an optical signal between said optical input/output end faces, wherein said end face wall comprises a first end face facing an end face of said substrate in an optical transmission direction and positioned closer to said substrate than said optical waveguide-side lens, and a second end face facing said ferrule in said optical transmission direction and positioned closer to said ferrule than said optical fiber-side lens; and wherein a positioning surface that comes in contact with said substrate layer is formed on said upper surface wall of said connector body. 2. The optical connector of claim 1 , wherein in accordance with a traveling direction of an optical signal, one of said optical waveguide-side lens and said optical fiber-side lens acts as a collimator lens and the other acts as a condensing lens. 3. The optical connector of claim 1 , wherein a guide is formed between said connector body and said substrate and is configured to guide said connector body and said substrate to allow relative movement of said connector body and said substrate in a direction parallel to an extending direction of said optical waveguide. 4. An active optical cable comprising the optical connector of claim 1 . 5. An optical connector system comprising: a substrate comprising an optical element; a plurality of optical waveguides provided on said substrate so as to form an optical path continuing to said optical element, with optical input/output end faces of said optical waveguides formed on an end face of said substrate; a ferrule holding a plurality of optical fibers comprising optical input/output end faces configured to send and receive an optical signal to and from said optical input/output end faces of said plurality of optical waveguides; a receptacle being L-shaped and comprising an upper surface wall that conforms to a substrate layer of said substrate, an end face wall formed to be orthogonal to said upper surface wall at an end of said upper surface wall on said ferrule side, and an intervening wall extending between said upper surface wall and said end face wall and made of a translucent material at a position between said optical input/output end faces of said optical waveguides and said optical input/output end faces of said optical fibers; and a plurality of optical waveguide-side lenses facing said optical input/output end faces of said plurality of optical waveguides and a plurality of optical fiber-side lenses facing said optical input/output end faces of said plurality of optical fibers, said pluralities of optical waveguide-side lenses and optical fiber-side lenses provided integrally on said intervening wall of said receptacle at positions between, and in a non-contact manner relative to, said optical input/output end faces of said plurality of optical waveguides and said optical input/output end faces of said plurality of optical fibers, respectively, and configured to send and receive an optical signal between said optical input/output end faces of said plurality of optical waveguides and said optical input/output end faces of said plurality of optical fibers, wherein said end face wall comprises a first end face facing an end face of said substrate in an optical transmission direction and positioned closer to said substrate than said optical waveguide-side lens, and a second end face facing said ferrule in said optical transmission direction and positioned closer to said ferrule than said optical fiber-side lens; and wherein a positioning surface that comes in contact with said substrate layer is formed on said upper surface wall. 6. The optical connector system of claim 5 , wherein in accordance with a traveling direction of an optical signal, one of said optical waveguide-side lens and said optical fiber-side lens acts as a collimator lens and the other acts as a condensing lens. 7. The optical connector system of claim 5 , wherein a guide is formed between said receptacle and said substrate and is configured to guide said receptacle and said substrate to allow relative movement of said receptacle and said substrate in a direction parallel to an extending direction of said optical waveguides. 8. An active optical cable comprising the optical connector system of claim 5 .