Robot and method of controlling robot

1 - 14 . (canceled) 15 . A robot comprising: a robot body; a battery accommodated in the robot body; a first leg and a second leg, each leg coupled to opposite first and second sides of the robot body, respectively; a first wheel assembly and a second wheel assembly rotatably coupled to the first leg and the second leg, respectively, the first wheel assembly and the second wheel assembly including a first wheel and a second wheel, respectively; a first suspension motor and a second suspension motor accommodated in the robot body, the first suspension motor and the second suspension motor being configured to drive the first leg and the second leg, respectively, the first suspension motor and the second suspension motor being configured to be sequentially driven when the robot body is tilted towards the first side or towards the second side when compared to a preset horizontal tilt of the robot body; and a first wheel motor and a second wheel motor accommodated in the first wheel assembly and the second wheel assembly, respectively, the first wheel motor and the second wheel motor being configured to provide a driving force to the first wheel and the second wheel, respectively, the first wheel motor and the second wheel motor being configured to be driven simultaneously when the robot body is tilted forward or backward when compared to the preset horizontal tilt. 16 . The robot of claim 15 , wherein the first wheel motor and the second wheel motor are configured to be driven so that the first wheel and the second wheel rotate backward when a tilted direction of the robot body is forward. 17 . The robot of claim 16 , wherein the first wheel motor and the second wheel motor are configured to be driven so that the first wheel and the second wheel rotate forward when the tilted direction of the robot body is backward. 18 . The robot of claim 17 , wherein, when the first wheel motor and the second wheel motor are driven in an opposite direction to the tilted direction, the first suspension motor and the second suspension motor are configured to be maintained in a stopped state. 19 . The robot of claim 15 , wherein, when a tilted direction of the robot body is toward the first side, the second suspension motor is configured to be controlled to be driven, and wherein, only when the preset horizontal tilt is not achieved, the first suspension motor is configured to be controlled after the driving of the second suspension motor is finished. 20 . The robot of claim 15 , further comprising a tilt detection sensor located in the robot body, the tilt detection sensor being configured to detect a tilting degree of the robot body. 21 . The robot of claim 15 , wherein each leg includes: a first link, the first link being link-connected to a corresponding side of the first side and the second side of the robot body, the first link being connected to a corresponding suspension motor of the first suspension motor and the second suspension motor; a second link, the second link being link-coupled to the corresponding side of the robot body to which the first link is coupled; and a third link, the third link being link-coupled to the first link and the second link, the third link being coupled to a corresponding wheel assembly of the first wheel assembly and the second wheel assembly, wherein, when a tilted direction of the robot body is toward the first side, the second suspension motor is configured to be driven such that an angle between the first link and the third link located at the second side decreases. 22 . The robot of claim 21 , wherein, when the preset horizontal tilt is not achieved and the angle between the second link and the third link that are located at the second side decreases to a preset minimum critical angle, the first suspension motor is configured to be driven so that the angle between the first link and the third link that are located at the first side increases. 23 . The robot of claim 22 , wherein, when the preset horizontal tilt is not achieved, the angle between the first link and the third link that are located at the first side is a preset maximum critical angle, and the angle between the first link and the third link that are located at the second side is the minimum critical angle, the first suspension motor and the second suspension motor are configured to be driven so that the maximum critical angle and the minimum critical angle are maintained. 24 . The robot of claim 15 , further comprising a contact detection sensor configured to detect a state in which the first wheel and the second wheel are in contact with a ground. 25 . The robot of claim 24 , wherein the contact detection sensor includes: a time of flight (TOF) sensor disposed on each wheel assembly, the time of flight (TOF) sensor being configured to measure a distance to the ground; and a load cell disposed on each leg, the load cell being configured to detect a normal force received by the leg from the ground. 26 . The robot of claim 25 , wherein, based on a signal from the contact detection sensor, each wheel motor is configured to stop driving the respective wheel regardless of a tilted degree of the robot body, when the respective wheel is spaced apart from the ground. 27 . A method of controlling a robot, the robot including a robot body, a first leg and a second leg, each leg connected to respective opposite sides of the robot body, a first wheel assembly and a second wheel assembly connected to the first leg and the second leg, respectively, the first wheel assembly and the second wheel assembly including a first wheel and a second wheel, respectively, a first suspension motor and a second suspension motor accommodated in the robot body, the first suspension motor and the second suspension motor configured to drive the first leg and the second leg, respectively, and, a first wheel motor and a second wheel motor accommodated in the first wheel assembly and the second wheel assembly, respectively, the first wheel motor and the second wheel motor being configured to provide a driving force to the first wheel and the second wheel, respectively, the method comprising: an attitude measuring operation of measuring a tilted direction and a tilt value compared to a preset horizontal tilt of the robot; and a motor driving operation of driving the first suspension motor and the second suspension motor or the first wheel motor and the second wheel motor according to the tilted direction, wherein, when the tilted direction of the robot body is toward the first side or toward the second side, the motor driving operation including sequentially driving the first suspension motor and the second suspension motor or driving any one of the first suspension motor and the second suspension motor. 28 . The method of claim 27 , wherein, when the tilted direction of the robot body is forward or backward, the motor driving operation includes controlling driving of the first wheel motor and the second wheel moto so that the first wheel and the second wheel rotate in a direction opposite to the tilted direction. 29 . The method of claim 28 , wherein, when the first wheel motor and the second wheel motor are driven in the opposite direction to the tilted direction, the motor driving operation includes maintaining the first suspension motor and the second suspension motor in a stopped state. 30 . The method of claim 27 , wherein, when the robot is tilted towards the first side, the motor driving operation includes: driving the second suspension motor to raise the second wheel located at the second