Closure latch assembly with power reset circuit mechanism and method for reset

What is claimed is: 1. An electronic reset system of a closure latch assembly comprising: an electric motor having a motor shaft driven in one of an actuation direction and a reset direction opposite the actuation direction for moving an actuatable mechanism between an actuated and a non-actuated state; an energy storage device operatively coupled to the electric motor and configured to operate in an energy storing state to store electrical energy and in an energy discharge state to discharge the electrical energy; and a controller coupled to the electric motor and the energy storage device, the controller configured to: control the electric motor in a power-on state to drive the motor shaft in the actuation direction from a first position to a second position for causing the actuatable mechanism to shift from its non-actuated state into its actuated state, and control a transition of the energy storage device from the energy storing state into the energy discharge state in response to the actuatable mechanism being operated in a power reset mode for powering the electric motor using the stored electrical energy in the energy storage device to cause the actuatable mechanism to shift from the second position to the first position so as to reset the actuatable mechanism in its non-actuated state for providing a powered reset function. 2. The electronic reset system as set forth in claim 1 , wherein the controller is coupled to a power supply and connected to the electric motor through power supply lines and the controller is further configured to provide driving signals over the power supply lines at appropriate voltage levels generated using power supplied from the power supply. 3. The electronic reset system as set forth in claim 1 , wherein the controller is further configured to control charging of the energy storage device using energy from a power supply to a predetermined voltage level. 4. The electronic reset system as set forth in claim 3 , wherein the controller is further configured to charge the energy storage device to one of a maximum capacity charge voltage level of the energy storage device and a voltage level below the maximum capacity charge voltage level. 5. The electronic reset system as set forth in claim 1 , further including a temperature sensor in communication with the controller for determining a temperature of the energy storage device and wherein the controller is further configured to charge the energy storage device to a charge voltage level based on at least one factor chosen from the group consisting of the temperature of the energy storage device, a maximum storage capacity of the storage device, an age of the storage device, and an age of the actuatable mechanism. 6. A closure latch assembly for a closure panel of a motor vehicle, comprising: a latch mechanism operable in a first state to locate the closure panel in a first position and in a second state to locate the closure panel in a second position; a power actuator including an actuatable mechanism being operable in a non-actuated state to permit the latch mechanism to operate in its first state and in an actuated state to shift the latch mechanism from its first state into its second state; the power actuator including an electric motor having a rotary motor shaft driven in an actuation direction for causing the actuatable mechanism to shift from its non-actuated state into its actuated state and an electronic reset circuit mechanism having an energy storage device operatively coupled to the electric motor and configured to operate in an energy storing state to store electrical energy supplied to the electric motor in the energy storage device and in an energy discharge state to discharge the electrical energy from the energy storage device into the electric motor in an opposite polarity direction for causing the electric motor to rotate the rotary motor shaft in a reset direction so as to reset the actuatable mechanism in its non-actuated state for providing a powered reset function; and the power actuator including a controlling circuit selectively coupled to the electric motor for controlling the electric motor in a power-on state to drive the motor shaft in an actuation direction for causing the actuatable mechanism to shift from its non-actuated state into its actuated state, the electronic reset circuit mechanism configured to operate in the energy storing state in response to the controlling circuit being coupled to the electric motor and rotating the rotary motor shaft in the actuation direction from a first position to a second position, the electronic reset circuit mechanism configured to transition from its energy storing state into an energy discharge state in response to the actuatable mechanism being in its actuated state and the controlling circuit being decoupled from the electric motor. 7. The closure latch assembly as set forth in claim 6 , wherein the electric motor is a power release motor and the actuatable mechanism is a power release gear operably coupled to a pawl to shift the pawl from a ratchet holding position to a ratchet releasing position in response controlling the electric motor in a power-on state to drive the motor shaft in an actuation direction for causing the power release gear to shift from its non-actuated state into its actuated state. 8. The closure latch assembly as set forth in claim 6 , wherein the electronic reset circuit mechanism is operable in its energy discharge state to cause the electric moto to rotate the rotary motor shaft in the reset direction from its second position back to its first position. 9. The closure latch assembly as set forth in claim 6 , wherein the energy storage device includes a positive energy storage terminal and a negative energy storage terminal and the electric motor includes a first motor terminal and a second motor terminal and the electronic reset circuit mechanism includes: a first diode having a first diode anode connected to the first motor terminal and a first diode cathode connected to the positive energy storage terminal for isolating the energy storage device; a second diode having a second diode cathode connected to the second motor terminal and a second diode anode connected to the negative energy storage terminal for isolating the energy storage device; a low side switch connected between the first motor terminal and the negative energy storage terminal for selectively allowing current flow from the first motor terminal to the negative energy storage terminal in a low side on state and preventing current flow from the first motor terminal to the negative energy storage terminal in a low side off state; and a high side switch connected between the second motor terminal and the positive energy storage terminal for selectively allowing current flow from the positive energy storage terminal to the second motor terminal in a high side on state and preventing current flow from the positive energy storage terminal to the second motor terminal in a high side off state. 10. The closure latch assembly as set forth in claim 9 , further including a switching logic controller coupled to the low side switch and the high side switch and configured to: detect the controlling circuit being coupled to the electric motor, turn the low side switch to the low side off state and the high side switch to the high side off state in response to the controlling circuit being coupled to the electric motor and rotating the rotary motor shaft in the actuation direction, detect the actuatable mechanism being in its actuated state and the controlling circuit being coupled to the electric motor, and turn the low side switch to the low side on state and the high side switc