Optical communication device and optical communication method

The invention claimed is: 1 . An optical communication device comprising: an optical transmitter that tracks a moving body and irradiates the moving body with a laser beam; and an optical receiver that is mounted on the moving body, receives the laser beam, and performs optical space communication with the optical transmitter, wherein the optical transmitter extends an irradiation range of the laser beam into an elliptical shape in a vertical direction orthogonal to a trajectory of the moving body, a light receiving range of the optical receiver is extended in a direction orthogonal to a direction in which the irradiation range of the laser beam is extended, and the light receiving range of the optical receiver is extended by expanding a light receiving diameter of the optical receiver using a cylindrical lens or by linearly arranging a plurality of optical receivers and combining their outputs. 2 . An optical communication device comprising: an optical transmitter that tracks a moving body and irradiates the moving body with a laser beam; and an optical receiver that is mounted on the moving body, receives the laser beam, and performs optical space communication with the optical transmitter, wherein the optical transmitter extends the irradiation range of the laser beam in a direction of a trajectory of the moving body, a light receiving range of the optical receiver is extended in a vertical direction orthogonal to a direction in which the irradiation range of the laser beam is extended, and the light receiving range of the optical receiver is extended by expanding a light receiving diameter of the optical receiver using a cylindrical lens or by linearly arranging a plurality of optical receivers and combining their outputs. 3 . The optical communication device according to claim 1 , wherein the optical transmitter includes a laser light source that emits the laser beam, a driver that modulates the laser beam, and a lens that refracts the laser beam. 4 . The optical communication device according to claim 3 , wherein the optical transmitter includes an optical mechanism that adjusts a beam waist of the laser beam. 5 . The optical communication device according to claim 3 , wherein the optical transmitter adjusts the irradiation range of the laser beam by adjusting an interval between the laser light source and the lens. 6 . The optical communication device according to claim 2 , wherein the optical transmitter includes a laser light source that emits the laser beam, a driver that modulates the laser beam, and a lens that refracts the laser beam. 7 . The optical communication device according to claim 6 , wherein the optical transmitter includes an optical mechanism that adjusts a beam waist of the laser beam. 8 . The optical communication device according to claim 6 , wherein the optical transmitter adjusts the irradiation range of the laser beam by adjusting an interval between the laser light source and the lens. 9 . An optical communication method, comprising the steps of: tracking a moving body and irradiating the moving body with a laser beam from an optical transmitter; and receiving the laser beam by an optical receiver mounted on the moving body and performing optical space communication between the optical transmitter and the optical receiver, wherein an irradiation range of the laser beam emitted from the optical transmitter is extended into an elliptical shape in a vertical direction orthogonal to a trajectory of the moving body, a light receiving range of the optical receiver is extended in a direction orthogonal to a direction in which the irradiation range of the laser beam is extended, and the light receiving range of the optical receiver is extended by expanding a light receiving diameter of the optical receiver using a cylindrical lens or by linearly arranging a plurality of optical receivers and combining their outputs. 10 . An optical communication method, comprising the steps of: tracking a moving body and irradiating the moving body with a laser beam from an optical transmitter; and receiving the laser beam by an optical receiver mounted on the moving body and performing optical space communication between the optical transmitter and the optical receiver, wherein the optical transmitter extends the irradiation range of the laser beam in a direction of a trajectory of the moving body, a light receiving range of the optical receiver is extended in a vertical direction orthogonal to a direction in which the irradiation range of the laser beam is extended, and the light receiving range of the optical receiver is extended by expanding a light receiving diameter of the optical receiver using a cylindrical lens or by linearly arranging a plurality of optical receivers and combining their outputs.