Preventing dark current in battery management system

What is claimed is: 1. A battery control apparatus comprising: a processor; a voltage regulator including an input and an output, the voltage regulator configured to receive power supplied from a power supply at the input, regulate the voltage of the power, and provided the regulated voltage to the output to power the processor; a first switch having a first state connecting the input of the voltage regulator to receive the power from the power supply and a second state disconnecting the input of the voltage regulator from the power supply to cut off the power from the input to the voltage regulator; and a second switch having an output connected to the first switch, the second switch configured to turn on based on a driving signal for operating the processor, and provide a control signal to the first switch to place the first switch in the one of the first state or the second state, wherein, in response to the second switch not receiving the driving signal, the second switch continues to turn on during a predetermined time based on either one or both of a power latch signal from the processor and an electrical signal corresponding to a power stored in a capacitor, wherein the second switch comprises: an OR gate configured to transmit an output signal when receiving at least one of the driving signal and the power latch signal; and a transistor connected between the OR gate and the first switch, the transistor configured to place the first switch in the first state in response to the output signal provided from the OR gate. 2. The battery control apparatus of claim 1 , wherein the first switch comprises: a transistor connected to the second switch, the transistor being located between the power supply and the voltage regulator; and a resistor connected in parallel to the transistor. 3. The battery control apparatus of claim 1 , wherein the second switch includes an input configured to receive a power latch signal from the processor and a driving signal from the power supply and to output the control signal to place the first switch in the first state in response to receiving at least one of the driving signal and the power latch signal. 4. The battery control apparatus of claim 1 , wherein the second switch comprises: a transistor having an input, the transistor configured to receive a current at the input and place the first switch in the first state when the input receives the current and to place the first switch in the second state when the input stops receiving the current; and a capacitor configured to provide the current to the transistor for a predetermined period of time after the driving signal stops being transmitted to the second switch, wherein, the current provided to the transistor corresponds to the current provided by the driving signal. 5. The battery control apparatus of claim 3 , wherein the second switch is configured to stop output of the control signal and place the first switch in the second state once a predetermined period of time elapses after the second switch ceases to receive the driving signal. 6. The battery control apparatus of claim 3 , wherein the second switch comprises: a first diode having an input and an output, the first diode configured transfer the driving signal received at the input of the first diode to the output of the first diode; a second diode having an input and an output, the second diode configured to transfer the power latch signal received at the input of the second diode to the output of the second diode; and a first transistor, connected to the output of the first diode and the output of the second diode, the first transistor configured to place the first switch in the first state and the second state, wherein the first transistor places the first switch in the second state when neither the driving signal is output from the first diode, nor the power latch signal is output from the second diode. 7. The battery control apparatus of claim 4 , wherein the capacitor has a capacity enabling the capacitor to provide the current to the transistor for the predetermined period of time. 8. The battery control apparatus of claim 4 , wherein the second switch further comprises: a diode, connected between the transistor and the capacitor, configured to transfer the driving signal and the current from the capacitor to the transistor; and a resistor connected in parallel to the diode. 9. The battery control apparatus of claim 5 , wherein the processor is configured to transmit the power latch signal to the second switch when the driving signal is not input to the processor for a period of time, the period of time being from a point in time when the driving power is provided to the processor to a point in time when the predetermined period of time elapses. 10. The battery control apparatus of claim 5 , wherein the processor is configured to terminate a program being processed by the processor during the predetermined period of time. 11. The battery control apparatus of claim 6 , wherein the second switch comprises a second transistor comprising an input configured to receive the driving signal and an output connected to the first diode, the second transistor configured to transfer the driving signal received at the input to the output. 12. The battery control apparatus of claim 9 , wherein the processor is configured to stop transmitting the power latch signal to the second switch, and the second switch is configured to place the first switch in the second state after the predetermined period of time elapses when the second switch stops receiving the driving signal and the power latch signal. 13. The battery control apparatus of claim 10 , wherein the processor is configured to set the predetermined period of time to be equal to or longer than a period of time required to terminate the program. 14. A power management apparatus comprising: a power providing unit configured to provide a driving power to a processor; and a power controller configured to control providing of the driving power by the power providing unit based on receiving an input of a driving signal to operate the processor, wherein the power controller comprises a first switch configured to connect a voltage regulator to the power providing unit and a second switch configured to turn on based on the driving signal, and wherein, in response to the second switch not receiving the driving signal, the second switch continues to turn on during a predetermined time based on either one or both of a power latch signal from the processor and an electrical signal corresponding to a power stored in a capacitor, wherein the second switch comprises: an OR gate configured to transmit an output signal when receiving at least one of the driving signal and the power latch signal; and a transistor connected between the OR gate and the first switch, the transistor configured to place the first switch in the first state in response to the output signal provided from the OR gate, the first state connecting the voltage regulator to receive the power from the power providing unit. 15. The power management apparatus of claim 14 , wherein the power providing unit comprises a voltage regulator configured to regulate a voltage of the driving power input to the processor. 16. The power management apparatus of claim 14 , wherein the power providing unit is configured to provide the driving power to the processor in response to receiving at least one of an input of a power latch signal from the processor and the input of the driving signal. 17. The power management apparatus o