Driving module, motion assistance apparatus including the driving module, and method of controlling the motion assistance apparatus

What is claimed is: 1. A driving module comprising: a driver configured to transmit power; an input side rotary body connected to the driver and configured to rotate; and a first decelerator and a second decelerator configured to operate using the power received from the driver through the input side rotary body, the first decelerator configured to transmit the power to a first supporting structure of a motion assistance apparatus, the second decelerator configured to transmit the power to a second supporting structure of the motion assistance apparatus, wherein a first gear ratio from the input side rotary body to a first output terminal of the first decelerator differs from a second gear ratio from the input side rotary body to a second output terminal of the second decelerator, wherein the first decelerator comprises a first planet gear, a first carrier, a first ring gear, and a first pulley, the second decelerator comprises a second planet gear, a second carrier, a second ring gear, and a second pulley, the first and second ring gears are fixed together to perform a single rigid body motion, and the first and second carriers are fixed to the first and second pulleys, respectively, to perform a single rigid body motion. 2. The driving module of claim 1 , wherein at least one of the first planet gear or the second planet gear connected to an outer circumferential surface of the input side rotary body and configured to rotate with respect to an axis of rotation thereof and revolve around the input side rotary body using the power received through the input side rotary body, at least one of the first carrier or the second carrier connected to the axis of rotation of a corresponding one of the first planet gear or the second planet gear, and configured to rotate when the corresponding one of the first planet gear or the second planet gear revolves around the input side rotary body, at least one of the first ring gear or the second ring gear including an inner circumferential surface, the inner circumferential surface configured to be connected to a corresponding one of the first planet gear or the second planet gear, and at least one of the first pulley or the second pulley configured to act as a corresponding one of the first output terminal of the first decelerator or the second output terminal of the second decelerator, the at least one of the first pulley or the second pulley including an outer circumferential surface over which a power transmitter configured to transmit the power from the input side rotary body to a corresponding one of the first supporting structure or the second supporting structure that is connected to the driving module is to be wound. 3. The driving module of claim 2 , wherein the first planet gear of the first decelerator and the second planet gear of the second decelerator are fixed together to perform a single rigid body motion. 4. The driving module of claim 2 , wherein the first pulley and the first ring gear are fixed together to perform a single rigid body motion, or the second pulley and the second ring gear are fixed together to perform a single rigid body motion. 5. The driving module of claim 4 , wherein the first pulley and the first ring gear are provided as an integral body such that the first pulley is defined along on a first outer circumferential surface of the first ring gear, or the second pulley and the second ring gear are provided as an integral body such that the second pulley is defined along on a second outer circumferential surface of the second ring gear. 6. The driving module of claim 4 , wherein the first carrier is coupled to the axis of rotation of the first planet gear, and the first ring gear is restricted by the first planet gear and the first pulley, or the second carrier is coupled to the axis of rotation of the second planet gear, and the second ring gear is restricted by the second planet gear and the second pulley. 7. A motion assistance apparatus comprising: a fixing member configured to be fixed to a user; a driving module on one side of the fixing member, the driving module including, a driver configured to transmit power, an input side rotary body connected to the driver and configured to rotate, a first decelerator configured to operate based on the power received from the driver through the input side rotary body, the first decelerator configured to transmit the power to a first joint member of the motion assistance apparatus, and a second decelerator configured to operate based on the power received from the driver through the input side rotary body, the second decelerator configured to transmit the power to a second joint member of the motion assistance apparatus; the first joint member and the second joint member configured to assist respective rotary motions; a first power transmitter connected to a first output terminal of the first decelerator to the first joint member such that the first output terminal of the first decelerator and the first joint member are enabled to have opposite rotation directions; and a second power transmitter connected to a second output terminal of the second decelerator to the second joint member such that the second output terminal of the second decelerator and the second joint member are enabled to have identical rotation directions, wherein a first gear ratio from the input side rotary body to the first output terminal of the first decelerator differs from a second gear ratio from the input side rotary body to the second output terminal of the second decelerator, and wherein the first decelerator comprises a first planet gear, a first carrier, a first ring gear, and a first pulley, the second decelerator comprises a second planet gear, a second carrier, a second ring gear, and a second pulley, the first and second ring gears are fixed together to perform a single rigid body motion, and the first and second carriers are fixed to the first and second pulleys, respectively, to perform a single rigid body motion. 8. The motion assistance apparatus of claim 7 , wherein the first power transmitter and the second power transmitter are asymmetrically provided to each other with respect to the driving module. 9. The motion assistance apparatus of claim 8 , wherein when seeing from respective sides of the motion assistance apparatus, the first power transmitter is provided in an overlapping manner between the driving module and the first joint member, and the second power transmitter is provided in a non-overlapping manner between the driving module and the second joint member. 10. The motion assistance apparatus of claim 7 , wherein the first pulley corresponds to the first output terminal of the first decelerator, and the second pulley corresponds to the second output terminal of the second decelerator. 11. A motion assistance apparatus comprising: a fixing member configured to be fixed to a user; a driving module on one side of the fixing member, the driving module including a driver configured to transmit driving power, an input side rotary body connected to the driver and configured to rotate, a first decelerator configured to operate using the power received from the driver through the input side rotary body, the first decelerator configured to transmit the power to a first joint member of the motion assistance apparatus, and a second decelerator configured to operate using the power received from the driver through the input side rotary body, the second decelerator configured to transmit the power to a second joint member of the motion assistance apparatus; the first joint member and the second joint member configured to assist resp