Driving control system and method for electric vehicle

What is claimed is: 1 . A driving control method for an electric vehicle, comprising: determining whether or not a driving state of the vehicle is a countersteer situation based on vehicle driving information collected from the vehicle; determining a countersteer index configured to indicate a degree to which a countersteer effect is increased with respect to a driver's countersteer amount; and performing countersteer expansion control to increase the countersteer effect, in response to the determined countersteer index satisfying an expansion requirement after determining that the driving state of the vehicle is the countersteer situation, wherein the countersteer expansion control is control of one of or both of driving force and braking force applied to wheels of the vehicle. 2 . The method of claim 1 , wherein the countersteer expansion control is one of control configured to stop applying the driving force to rear wheels of the vehicle and control configured to reduce the driving force applied to the rear wheels. 3 . The method of claim 1 , wherein the countersteer expansion control is configured to resume rear wheel slip control configured to adjust the driving force of rear wheels of the vehicle so as to reduce rear wheel slip. 4 . The method of claim 1 , wherein the countersteer expansion control is configured to apply a part of the driving force as much as a distribution ratio or all of the driving force to front wheels of the vehicle. 5 . The method of claim 1 , wherein the countersteer expansion control is configured to apply one-sided braking force to turning outer wheels among front wheels and rear wheels of the vehicle turning along a curved road. 6 . The method of claim 1 , wherein the countersteer expansion control is configured to apply one-sided braking force to a turning outer wheel among rear wheels of the vehicle turning along a curved road. 7 . The method of claim 1 , wherein the countersteer expansion control comprises one of: torque vectoring control configured to apply the driving force only to a turning inner wheel among front wheels of the vehicle turning along a curved road; torque vectoring control configured to reduce the driving force of a turning outer wheel among rear wheels of the vehicle relative to the driving force of a turning inner wheel among the rear wheels through a change in a torque distribution ratio between left wheels and right wheels of the vehicle turning along the curved road, to reduce the driving force of the turning outer wheel among the rear wheels relative to a previous control cycle, or to perform slip limit control only on the turning outer wheel among the rear wheels; and torque vectoring control configured to reduce the driving force of the turning inner wheel among the rear wheels relative to the driving force of the turning outer wheel among the rear wheels through the change in the torque distribution ratio between the left wheels and the right wheels of the vehicle turning along the curved road, to reduce the driving force of the turning inner wheel among the rear wheels relative to the previous control cycle, or to perform slip limit control only on the turning inner wheel among the rear wheels. 8 . The method of claim 1 , wherein the expansion requirement is set to a condition in which the countersteer index reaches a set maximum value or exceeds a set threshold. 9 . The method of claim 1 , wherein, in determining the countersteer index, the countersteer index is determined from set data, wherein the set data: uses a steering angle among the vehicle driving information as an essential input variable; and uses one of or any combination of a target yaw rate determined from the steering angle, a measured yaw rate detected by a sensor, a yaw rate error which is a difference between the target yaw rate and the measured yaw rate, and a vehicle speed, as an additional input variable, and wherein the countersteer index is set to a value corresponding to the input variables used. 10 . The method of claim 9 , wherein the countersteer index is set to a larger value as, among the set data, one of or any combination of an absolute value of the steering angle increases, an absolute value of the target yaw rate increases, an absolute value of the measured yaw rate increases, an absolute value of the yaw rate error increases, and the vehicle speed increases. 11 . A driving control system for an electric vehicle, comprising: a driving information detector configured to detect information for indicating a driving state of the vehicle; and a control unit configured to perform countersteer expansion control to increase a countersteer effect with respect to a driver's countersteer amount, wherein the control unit is configured to: determine whether the driving state of the vehicle is a countersteer situation based on vehicle driving information comprising the information detected by the driving information detector, determine a countersteer index configured to indicate a degree to which the countersteer effect is increased with respect to the driver's countersteer amount, and perform the countersteer expansion control configured to control one of or both of driving force and braking force applied to wheels of the vehicle to increase the countersteer effect, in response to the determined countersteer index satisfying an expansion requirement after determining that the driving state of the vehicle is the countersteer situation. 12 . The driving control system of claim 11 , wherein the countersteer expansion control is one of control configured to stop applying the driving force to rear wheels and control configured to reduce the driving force applied to the rear wheels. 13 . The driving control system of claim 11 , wherein the countersteer expansion control is configured to resume rear wheel slip control configured to adjust the driving force of rear wheels of the vehicle so as to reduce rear wheel slip. 14 . The driving control system of claim 11 , wherein the countersteer expansion control is configured to apply a part of the driving force as much as a distribution ratio or all of the driving force to front wheels of the vehicle. 15 . The driving control system of claim 11 , wherein the countersteer expansion control is configured to apply one-sided braking force to turning outer wheels among front wheels and rear wheels of the vehicle turning along a curved road. 16 . The driving control system of claim 11 , wherein the countersteer expansion control is configured to apply one-sided braking force to a turning outer wheel among rear wheels of the vehicle turning along a curved road. 17 . The driving control system of claim 11 , wherein the countersteer expansion control comprises one of: torque vectoring control configured to apply the driving force only to a turning inner wheel among front wheels of the vehicle turning along a curved road; torque vectoring control configured to reduce the driving force of a turning outer wheel among rear wheels of the vehicle compared to the driving force of a turning inner wheel among the rear wheels through a change in a torque distribution ratio between left wheels and right wheels of the vehicle turning along the curved road, to reduce the driving force of the turning outer wheel among the rear wheels compared to a previous control cycle, or to perform slip limit control only on the turning outer wheel among the rear wheels; and torque vectoring control configured to reduce the driving force of the turning inner wheel among the rear wheels compared to th