Optical modulator element, optical modulation module including optical modulator element, and method for manufacturing optical modulator element

What is claimed is: 1. An optical modulator element comprising: a first optical modulator and a second optical modulator that are disposed on a semiconductor substrate; an optical input terminal to receive a light beam; and a branch coupler to split the light beam received by said optical input terminal into said first and second optical modulators, wherein each of said first and second optical modulators includes: a pair of Mach-Zehnder waveguides; a first optical coupler to split rays from said branch coupler into said pair of Mach-Zehnder waveguides; and a second optical coupler to combine rays transmitted through said pair of Mach-Zehnder waveguides, and said first and second optical modulators are disposed in such a manner that a traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said first optical modulator and a traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said second optical modulator are angled away from each other, wherein the traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said first optical modulator forms an angle of 180° with the traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said second optical modulator, the optical modulator element further comprising: a first high-frequency wave electrode disposed along said pair of Mach-Zehnder waveguides of said first optical modulator; a second high-frequency wave electrode disposed along said pair of Mach-Zehnder waveguides of said second optical modulator; a first high-frequency wave transmission path connected to said first high-frequency wave transmission electrode; and a second high-frequency wave transmission path connected to said second high-frequency wave transmission electrode, wherein said first and second optical modulators are disposed so as to be mirror images of each other relative to said optical input terminal, said first and second high-frequency wave electrodes are disposed so as to be mirror images of each other relative to said optical input terminal, and said first and second high-frequency wave transmission paths are disposed so as to be mirror images of each other relative to said optical input terminal. 2. An optical modulation module comprising: an optical modulator element according to claim 1 ; a plurality of signal input terminals corresponding to said first high-frequency wave transmission path; and a plurality of signal input terminals corresponding to said second high-frequency wave transmission path, wherein said optical modulator element has sides that define an outline in a plan view, said sides including a first side and a second side, said plurality of signal input terminals corresponding to said first high-frequency wave transmission path and said plurality of signal input terminals corresponding to said second high-frequency wave transmission path are disposed on said first side of said optical modulator element, and said plurality of signal input terminals corresponding to said first high-frequency wave transmission path and said plurality of signal input terminals corresponding to said second high-frequency transmission path are disposed at regular intervals. 3. The optical modulation module according to claim 2 , further comprising: a first condenser lens disposed upstream of said optical input terminal; a first collimator lens disposed upstream of said first condenser lens; a second collimator lens disposed downstream of said second optical coupler included in said first optical modulator; a third collimator lens disposed downstream of said second optical coupler included in said second optical modulator; a rotator that is disposed downstream of said third collimator lens and rotates a polarization direction of rays 90°; a beam splitter that is disposed downstream of both said rotator and said second collimator lens and combines rays; and a second condenser lens disposed downstream of said beam splitter, wherein said first and second condenser lenses, the first to third collimator lenses, said rotator, and said beam splitter are disposed so as to be adjacent to said second side opposite to said first side of said optical modulator element. 4. The optical modulator element according to claim 1 , wherein the optical modulator element is configured to perform optical modulation in dual-polarization quadrature phase-shift keying. 5. An optical modulator element comprising: a first optical modulator and a second optical modulator that are disposed on a semiconductor substrate; an optical input terminal to receive a light beam; and a branch coupler to split the light beam received by said optical input terminal into said first and second optical modulators, wherein each of said first and second optical modulators includes: a pair of Mach-Zehnder waveguides; a first optical coupler to split rays from said branch coupler into said pair of Mach-Zehnder waveguides, and a second optical coupler to combine rays transmitted through said pair of Mach-Zehnder waveguides, wherein said first and second optical modulators are disposed in such a manner that a traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said first optical modulator and a traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said second optical modulator are angled away from each other the traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said first optical modulator forms an angle of 180° with the traveling direction of rays propagating through said pair of Mach-Zehnder waveguides of said second optical modulator, the optical modulator element includes sides that define an outline in a plan view, each of said first and second optical modulators of said optical modulator element further including an optical output terminal disposed downstream of said second optical coupler, and all of said optical input terminal, said optical output terminal of said first optical modulator, and said optical output terminal of said second optical modulator are disposed on one of said sides. 6. A method for manufacturing an optical modulator element according to claim 5 , comprising: (a) forming at least one pair of said optical modulator elements simultaneously on a semiconductor substrate; and (b) cutting said semiconductor substrate along a cutting line to split said at least one pair of optical modulator elements formed on said semiconductor substrate, wherein in said step (a), said at least one pair of optical modulator elements is formed on said semiconductor substrate so as to be rotationally symmetric at a rotation of 180 degrees with respect to said optical input terminal, said optical input terminal of one optical modulator element of said at least one pair of optical modulator elements is connected with said optical input terminal of the other optical modulator element of said at least one pair of optical modulator elements, said optical output terminal of said first optical modulator included in said one optical modulator element is connected with said optical output terminal of said second optical modulator included in said other optical modulator element, and said optical output terminal of said second optical modulator included in said one optical modulator element is connected with said optical output terminal of said first optical modulator included in said other optical modulator element, and in said step (b), said cutting line is a straight line that passes through a connection between said optical input terminal of said one optical modulator element and said optical input terminal of said other optical modulator e