Regenerative braking control system and method of AWD hybrid vehicle

What is claimed is: 1. A regenerative braking control system of an AWD (all-wheel-drive) hybrid vehicle including a front wheel HEV (hybrid electric vehicle) powertrain and a rear wheel EV (electric vehicle) powertrain, the control system comprising: a manipulating instrument mounted to a steering wheel for manual shifting and regenerative braking control by a driver's manipulation; and a controller configured to adjust a regenerative braking amount and control a shift pattern of a front wheel motor of the front wheel HEV powertrain and to adjust a regenerative braking amount of a rear wheel motor of the rear wheel EV powertrain by receiving a (−) or (+) manipulation signal or a hold manipulation signal of the manipulating instrument. 2. The control system of claim 1 , wherein the manipulating instrument comprises a pair of paddles including a (−) paddle and a (+) paddle capable of performing a toggling manipulation or a hold manipulation. 3. A regenerative braking control system of an AWD (all-wheel-drive) hybrid vehicle including a front wheel HEV (hybrid electric vehicle) powertrain and a rear wheel EV (electric vehicle) powertrain, the control system comprising: a manipulating instrument mounted to a steering wheel for manual shifting and regenerative braking control by a driver's manipulation; and a controller configured to adjust a regenerative braking amount and control a shift pattern of a front wheel motor of the front wheel HEV powertrain and to adjust a regenerative braking amount of a rear wheel motor of the rear wheel EV powertrain by receiving a (−) or (+) manipulation signal or a hold manipulation signal of the manipulating instrument; wherein the controller comprises: an HCU (hybrid control unit) configured to output a torque command signal and a shift-pattern control signal for adjusting the regenerative braking amount of each of the front wheel motor and the rear wheel motor after variably setting a torque ratio between the front wheel motor of the front wheel HEV powertrain and the rear wheel motor of the rear wheel EV powertrain by receiving the (−) or (+) manipulation signal or the hold manipulation signal of the manipulating instrument; an MCU (motor control unit) configured to adjust the regenerative braking amount of each of the front wheel motor and the rear wheel motor on the basis of the torque command signal for the regenerative braking amount adjustment of each of the front wheel motor and the rear wheel motor; and a TCU (transmission control unit) configured to perform shift control of an automatic transmission on the basis of the shift-pattern control signal. 4. The control system of claim 3 , wherein off detection signals of an APS (accelerator position sensor) and a BPS (brake position sensor) for determining a coasting state of the vehicle are to be transmitted to the HCU during operation of the vehicle. 5. The control system of claim 3 , further comprising a driving mode selection switch configured to select a vehicle driving mode as an eco mode or a sports mode, a switching signal of the driving mode selection switch being transmitted to the HCU during operation of the vehicle. 6. The control system of claim 3 , wherein when receiving a (−) toggling manipulation signal or the hold manipulation signal of the manipulating instrument while the vehicle is in a coasting state and a driving mode thereof is an eco mode, the HCU is configured to variably set the torque ratio between the front wheel motor and the rear wheel motor and then to output the torque command signal and the shift-pattern control signal for an increase adjustment of the regenerative braking amount of each of the front wheel motor and the rear wheel motor. 7. The control system of claim 3 , wherein when receiving a (+) toggling manipulation signal or the hold manipulation signal of the manipulating instrument while the vehicle in a coasting state and a driving mode thereof is an eco mode, the HCU is configured to variably set the torque ratio between the front wheel motor and the rear wheel motor and then to output the torque command signal and the shift-pattern control signal for a decrease adjustment of the regenerative braking amount of each of the front wheel motor and the rear wheel motor. 8. The control system of claim 3 , wherein when the vehicle is in a coasting state and a driving mode thereof is a sports mode, the HCU is configured to transmit a lower-stage transmission command signal to a transmission stage lower than a current transmission stage to the TCU when the (−) manipulation signal of the manipulating instrument is received, and the HCU is configured to transmit an upper-stage transmission command signal to a transmission stage higher than the current transmission stage to the TCU when the (+) manipulation signal of the manipulating instrument is received. 9. The control system of claim 3 , further comprising: an AHB (active hydraulic booster) configured to receive a cooperative control signal for distribution of a total braking force from the HCU and for generating a hydraulic braking pressure of a hydraulic braking system in addition to a regenerative braking force of a motor when the driver presses a brake pedal. 10. A regenerative braking control method of an AWD hybrid vehicle that includes a front wheel HEV powertrain and a rear wheel EV powertrain, the control method comprising: determining whether the vehicle is in a coasting state or a current driving mode in a controller; changing a function of a driver manipulating instrument to a function of adjusting a regenerative braking amount when the vehicle is determined to be in the coasting state and a driving mode thereof is an eco mode in the controller; and adjusting the regenerative braking amount and controlling a shift pattern of a front wheel motor of the front wheel HEV powertrain and to adjust a regenerative braking amount of a rear wheel motor of the rear wheel EV powertrain when the controller receives a (−) or (+) manipulation signal or a hold manipulation signal of the manipulating instrument. 11. The control method of claim 10 , wherein adjusting the regenerative braking amount and controlling the shift pattern comprises an HCU of the controller variably setting a torque ratio between the front wheel motor of the front wheel HEV powertrain and the rear wheel motor of the rear wheel EV powertrain and then outputting a torque command signal for the regenerative braking amount adjustment of the front wheel motor and the rear wheel motor and a shift-pattern control signal. 12. The control method of claim 10 , wherein when vehicle speed is higher than o KPH, an APS is off, and a BPS is off while an HCU of the controller receives a signal of a vehicle speed sensor, a signal of an APS (accelerator position sensor), and a signal of a BPS (brake position sensor), the vehicle is determined to be in the coasting state. 13. The control method of claim 10 , further comprising: determining whether a first manipulation signal for performing a (−) manipulation of the manipulating instrument is an initial one-time toggling input signal or a one-time hold input signal; and after determining the first manipulation signal is the initial one-time toggling input signal, setting target deceleration by vehicle speed and setting a variable torque ratio between the front wheel motor and the rear wheel motor as a target torque ratio for meeting the target deceleration by an HCU of the controller. 14. The control method of claim 13 , further comprising: receiving, by the HCU, an additional one-time toggling input signal for continuously performing the (−) manipulation of the m