Systems and methods for damper actuator without microcontroller

What is claimed is: 1. An actuator comprising: a motor configured to drive an external device to a determined position when the motor is energized; a switching circuit configured to drive control signals to control voltage applied to energize the motor, the drive control signals comprising a drive active signal and a hold active signal and the switching circuit comprising: a first semiconductor switch having a gate that receives a timer signal and a first semiconductor switch terminal connected to a reference voltage such that the first semiconductor switch drives high the hold active signal when the timer signal is not present on the gate of the first semiconductor switch; and a second semiconductor switch having a gate connected to the first semiconductor switch terminal to receive the hold active signal and a second semiconductor switch terminal connected to the reference voltage such that the second semiconductor switch drives high the drive active signal when the hold active signal is not present on the gate of the second semiconductor switch; and a motor circuit configured to energize the motor with a high voltage to drive the external device to the determined position and energize the motor with a low voltage to hold the external device in the determined position, wherein the motor circuit comprises: a third semiconductor switch having a gate connected to the second semiconductor switch terminal to receive the drive active signal, wherein the third semiconductor switch is configured to energize the motor with the high voltage when the drive active signal is driven to high; and a fourth semiconductor switch having a gate connected to the first semiconductor switch terminal to receive the hold active signal, wherein the third semiconductor switch is configured to energize the motor with the low voltage when the hold active signal is driven to high. 2. The actuator of claim 1 , wherein the timer signal changes value based on a determined time that has passed from a moment the motor is energized. 3. The actuator of claim 2 , wherein the determined time is determined by a distance travelled by a gear train. 4. The actuator of claim 1 , further comprising: a zener diode connected in parallel with the motor; and a fifth semicondutor switch having a gate connected to the reference voltage, a fifth semiconductor switch terminal connected to the motor and another fifth semiconductor switch terminal of the fifth semiconductor switch connected to a ground voltage. 5. The actuator of claim 4 , wherein the fifth semiconductor switch is configured to, when the motor is de-energized, disconnect the motor from the ground voltage and allow the zener diode to provide an electrical load to the motor. 6. An actuator adapted to provide drive power and hold power to an external device, comprising: a motor for driving the external device to a determined position when energized; a drive/hold switch connected with the motor, the drive/hold switch configured to select a high voltage or a low voltage, the high voltage for energizing the motor to drive the external device to the determined position and the low voltage to hold the external device when a determined time has passed from a moment the motor is energized, where the low voltage is lower than the high voltage; and an active/return switch connected with the motor, the active/return switch configured to: in a de-energized mode, connect the motor with a zener diode and disconnect the motor from the high voltage or the low voltage selected by the drive-hold switch; and in an energized mode, supply the high voltage or the low voltage selected by the drive/hold switch to the motor and disconnect the motor from the zener diode. 7. The actuator of claim 6 , wherein the active/return switch comprises a relay. 8. The actuator of claim 6 , wherein the active/return switch comprises a semiconductor device. 9. The actuator of claim 8 , wherein the semiconductor device comprises a metal-oxide semiconductor field-effect transistor. 10. The actuator of claim 6 , wherein the time is determined by a timer signal. 11. The actuator of claim 6 , where the time is determined by a distance travelled by a gear train connected to the motor. 12. An actuator comprising: a motor configured to drive an external device to a determined position when the motor is energized; a switching circuit configured to drive control signals to control voltage applied to energize the motor, the drive control signals comprising a drive active signal and a hold active signal and the switching circuit comprising: a first semiconductor switch having a gate that receives a timer signal and a first semiconductor switch terminal connected to a reference voltage such that the first semiconductor switch drives high the hold active signal when the timer signal is not present on the gate of the first semiconductor switch; and a second semiconductor switch having a gate connected to the first semiconductor switch terminal to receive the hold active signal and a second semiconductor switch terminal connected to the reference voltage such that the second semiconductor switch drives high the drive active signal when the hold active signal is not present on the gate of the second semiconductor switch; and a motor circuit configured to: energize the motor with a high voltage to drive the external device to the determined position when the drive active signal is driven high by the switching circuit; and energize the motor with a low voltage to hold the external device in the determined position when the hold active signal is driven high by the switching circuit. 13. The actuator of claim 12 , wherein the motor circuit comprises: a third semiconductor switch having a gate connected to the second semiconductor switch terminal to receive the drive active signal, wherein the third semiconductor switch is configured to energize the motor with the high voltage when the drive active signal is driven high; and a fourth semiconductor switch having a gate connected to the first semiconductor switch terminal to receive the hold active signal, wherein the third semiconductor switch is configured to energize the motor with the low voltage when the hold active signal is driven high. 14. The actuator of claim 13 , wherein the third semiconductor switch and the fourth semiconductor switch each have a terminal operatively connected to the motor. 15. The actuator of claim 12 , wherein the timer signal changes value based on a determined time that has passed from a moment the motor is energized. 16. The actuator of claim 15 , wherein the determined time is determined by a distance travelled by a gear train. 17. The actuator of claim 12 , further comprising: a zener diode connected in parallel with the motor; and a fifth semicondutor switch having a gate connected to the reference voltage, a fifth semiconductor switch terminal connected to the motor and another fifth semiconductor switch terminal of the fifth semiconductor switch connected to a ground voltage. 18. The actuator of claim 17 , wherein the fifth semiconductor switch is configured to, when the motor is de-energized, disconnect the motor from the ground voltage and allow the zener diode to provide an electrical load to the motor.