Transmission device, information terminal, communication system, and communication method

What is claimed is: 1. A transmission device configured to transmit a visible light signal to a receiving device, comprising: a laser light source configured to emit visible light, the visible light is red light, green light, or blue light each having a different wavelength; an optical modulator configured to change intensity of the visible light and generate a visible light signal corresponding to the red light, green light, or blue light; and an electrical signal generation element configured to receive information data to be transmitted, and output the information data to the optical modulator, wherein the optical modulator has an optical waveguide that serves as a transmission path for the visible light, and an electrode layer that modulates the visible light traveling in the optical waveguide, the optical waveguide is formed of a material containing lithium niobate, the optical waveguide has a ridge portion and a flat portion, a wavelength of the red light is 638 nm, a wavelength of the green light is 520 nm, a wavelength of the blue light is 473 nm, a width of a cross section perpendicular to a transmission direction of the visible light of the ridge portion in the optical waveguide is within a range of 510.4 nm or more and 1182.5 nm or less, and a height of the cross section of the ridge portion is within a range of 510.4 nm or more and 709.5 nm or less, the electrical signal generation element is configured to change a voltage value Vπ required to phase-modulate the wavelength of light to half-wavelength applied to the electrode layer by the visible light transmitting through the optical waveguide, and an integrated value Vπ*Li[V*cm] which is a product of the voltage value Vπ and an interaction length Li is 1.79 V*cm when the visible light is the red light, is 1.39 V*cm when the visible light is the green light, and is 1.20 V*cm when the visible light is the blue light. 2. The transmission device according to claim 1 , wherein the optical modulator has a substrate, and the optical waveguide is a lithium niobate film grown on the substrate. 3. The transmission device according to claim 2 , wherein the substrate is a sapphire substrate or an aluminum oxide substrate. 4. The transmission device according to claim 1 , further comprising an exit port for emitting the visible light signals to an outside. 5. The transmission device according to claim 1 , further comprising a connection unit for connecting to an optical fiber that transmits the visible light signals to an outside. 6. An information terminal comprising a transmission device according to claim 1 . 7. The information terminal according to claim 6 , wherein the information terminal is a smartphone, a tablet, or a personal computer. 8. A communication system comprising: the transmission device according to claim 1 ; and a receiving device configured to receive the visible light signals transmitted by the transmission device. 9. A communication method using the communication system according to claim 8 , comprising the steps of: generating a first visible light signal including a reception permission signal and a second visible light signal including information data using the optical modulator, and irradiating the receiving device with the first visible light signal and the second visible light signal by the transmission device; a process of receiving the first visible light signal by the receiving device; and a process of determining whether to accept the reception permission signal or not, and receiving the second visible light signal by the receiving device when the reception permission signal is accepted. 10. The transmission device according to claim 1 , wherein the height of the cross section of the ridge portion is within a range of 560 nm or more and 709.5 nm or less. 11. The transmission device according to claim 1 , the optical waveguide includes a light receiving portion, a branch portion, a first branch optical waveguide, a second branch optical waveguide, a coupling portion, a visible light signal generation unit, and a visible light signal emitting unit, the visible light received by the light receiving portion propagates from the light receiving portion to the branch portion, is branched at the branch portion, and propagates to the first branch optical waveguide and the second branch optical waveguide, and the visible light propagating through each of the first branch optical waveguide and the second branch optical waveguide is combined at the coupling portion, becomes the visible light signal in the visible light signal generation unit, and is transmitted to the outside via the visible light signal emitting unit, the electrode layer has a first signal electrode, a second signal electrode, a first ground electrode, a second ground electrode, and a third ground electrode, the first signal electrode faces the first branch optical waveguide, the second signal electrode faces the second branch optical waveguide, the first ground electrode is disposed along the first signal electrode on a side opposite to a second signal electrode side of the first signal electrode, the second ground electrode is disposed along the second signal electrode on a side opposite to a first signal electrode side of the second signal electrode, the third ground electrode is disposed between the first signal electrode and the second signal electrode along the first ground electrode and the second signal electrode the first ground electrode, the second ground electrode, and the third ground electrode are connected by a bonding wire, and the electrical signal generation element applies a potential difference based on the voltage between each of the first signal electrode and the second signal electrode, and the first ground electrode, the second ground electrode, and the third ground electrode, depending on the visible light transmitting through the optical waveguide. 12. The transmission device according to claim 1 , the interaction length Li is more than 1 cm, and the electrical signal generation element applies a voltage of 1.79 V or less to the electrode when the visible light is the red light, 1.39 V or less to the electrode when the visible light is the green light, and 1.20 V or less to the electrode when the visible light is the blue light.