Optical modulator, optical receiver, conversion device, spin orbital direct product state generation device, and quantum computer

What is claimed is: 1. An optical modulator that generates a coherent laser beam in a superposition state of two orthogonal angular momentum states, the optical modulator comprising: a first waveguide; a second waveguide; a first phase shifter provided in one or both of the first and second waveguides and configured to control a phase of the laser beam incident on the waveguide; a first optical element configured to combine the laser beam propagating through the first waveguide and the laser beam propagating through the second waveguide and separate the combined laser beam into two laser beams; a third waveguide on which one of the laser beams separated by the first optical element is incident; a fourth waveguide on which the other of the laser beams separated by the first optical element is incident; a second phase shifter provided in one or both of the third and fourth waveguides and configured to control a phase of the laser beam incident on the waveguide; and a second optical element configured to combine the laser beam propagating through the third waveguide and the laser beam propagating through the fourth waveguide and emit the laser beam in the superposition state of the two orthogonal angular momentum states. 2. The optical modulator according to claim 1 , wherein, when θ is a phase difference provided between the phase of the laser beam propagating through the first waveguide and the phase of the laser beam propagating through the second waveguide, the first optical element separates the combined laser beam so that a ratio of intensity of the laser beam incident on the third waveguide to intensity of the laser beam incident on the third waveguide becomes cos 2 (θ/2): sin 2 (θ/2). 3. The optical modulator according to claim 1 , further comprising: a third optical element configured to separate an incident laser beam into two laser beams with identical intensity, wherein one of the laser beams separated by the third optical element is incident on the first waveguide and the other of the laser beams separated by the third optical element is incident on the second waveguide. 4. The optical modulator according to claim 3 , wherein the first and third optical elements are multi-mode interference optical waveguides, and wherein the third optical element is formed by connecting the three first optical elements in series or a length of a waveguide of the third optical element is designed to an optimum value of when the length of the waveguide is three times a length of a waveguide of the first optical element. 5. The optical modulator according to claim 1 , further comprising: a temperature adjustment type phase shifter provided in one or both of the third and fourth waveguides and configured to adjust a phase of the laser beam propagating through the waveguide. 6. The optical modulator according to claim 1 , wherein the angular momentum state is an orbital angular momentum state, wherein a laser beam with an identical phase and intensity to the laser beam incident on the first waveguide is incident on the second waveguide, wherein the second optical element is a ring waveguide disposed between the third and fourth waveguides, and wherein an inner circumference of the ring waveguide has a periodic structure and a period of the periodic structure has magnitude which is an integral multiple of a wavelength of the laser beam in the ring waveguide. 7. The optical modulator according to claim 1 , wherein the angular momentum state is a spin angular momentum state, and wherein a laser beam in a spin angular momentum state orthogonal to the laser beam incident on the first waveguide is incident on the second waveguide. 8. The optical modulator according to claim 7 , wherein the second optical element is a coupler of photonic crystal with a rectangular planar shape, and wherein the third waveguide is coupled with a first side surface of the coupler and the fourth waveguide is coupled with a second side surface adjacent to the first side surface of the coupler. 9. The optical modulator according to claim 7 , further comprising: a fifth waveguide; a sixth waveguide on which a laser beam in a spin angular momentum state orthogonal to a laser beam incident on the fifth waveguide is incident; and a third optical element configured to combine the laser beam propagating through the fifth waveguide and the laser beam propagating through the sixth waveguide and separate the combined laser beam into two laser beams with identical intensity, wherein one of the laser beams separated by the third optical element is incident on the first waveguide and the other of the laser beams separated by the third optical element is incident on the second waveguide, wherein the first to sixth waveguides are formed on a substrate; wherein the third to sixth waveguides are each connected to a spot-size converter provided on a predetermined end surface of the substrate, and wherein the second optical element is coupled with an optical fiber connected to the third and fourth waveguides via the spot-size converter. 10. A quantum computer in which the superposition state of the angular momentum states according to claim 1 is formed as quantum bits. 11. An optical receiver that receives a coherent laser beam in a superposition state of two orthogonal angular momentum states, the optical receiver comprising: a first optical element on which light in any angular momentum state is incident and which is configured to separate the light into two laser beams in the two orthogonal angular momentum states; a first waveguide on which one of the laser beams from the first optical element is incident; a second waveguide on which the other of the laser beams from the first optical element is incident; a first phase shifter provided in one or both of the first and second waveguides and configured to control a phase of the laser beam incident on the waveguide; a second optical element configured to combine the laser beam propagating through the first waveguide and the laser beam propagating through the second waveguide and separate the combined laser beam into two laser beams; a third waveguide on which one of the laser beams separated by the second optical element is incident; a fourth waveguide on which the other of the laser beams separated by the second optical element is incident; a second phase shifter provided in one or both of the third and fourth waveguides and configured to control a phase of the laser beam incident on the waveguide; a third optical element configured to combine the laser beam propagating through the third waveguide and the laser beam propagating through the fourth waveguide and separate the combined laser beam into two laser beams; a fifth waveguide on which one of the laser beams separated by the third optical element is incident; a sixth waveguide on which the other of the laser beams separated by the third optical element is incident; a first receiver configured to detect the laser beam propagating through the fifth waveguide; and a second receiver configured to detect the laser beam propagating through the sixth waveguide. 12. The optical receiver according to claim 11 , wherein the second and third optical elements are multi-mode interference optical waveguides, wherein, when the laser beam is incident on the fifth wavelength and no laser beam is incident on the sixth wavelength, the third optical element is designed to separate the laser beam incident on the fifth wavelength into two laser beams with identical intensity and cause the laser beams to be incident on the third and fourth waveguides, and wherein the second optical el