Method and apparatus for controlling TRIAC dimmable device

What is claimed is: 1. A method for controlling a circuit, comprising: receiving a sensed signal corresponding to a current flowing through an energy transfer module in response to an on/off state of a triode for alternating current (TRIAC), providing the sensed signal to a state machine that transitions between a TRIAC on state and a TRIAC off state based on the sensed signal, the TRIAC off state having a first off sub-state and a second off sub-state; transitioning the state machine from the TRIAC on state to the first off sub-state of the TRIAC off state; transitioning the state machine from the first off sub-state of the TRIAC off state to the TRIAC on state a first condition of the state machine is satisfied; transitioning the state machine from the first off sub-state of the TRIAC off state to the second off sub-state of the TRIAC off state when the first condition of the state machine is not satisfied and a time duration condition of the state machine is satisfied; and transitioning the state machine from the second off sub-state of the TRIAC off state to the TRIAC on state when a second condition of the state machine is satisfied. 2. The method of claim 1 , wherein the time duration condition is that the state machine is in the first off sub-state of the TRIAC off state for more than half of a total TRIAC off time. 3. The method of claim 1 , further comprising: determining a total TRIAC off time based on a previous time duration that the state machine is in the TRIAC off state. 4. The method of claim 1 , wherein the state machine transitions from the TRIAC on state to the first off sub-state of the TRIAC off state when the sensed signal is lower than a threshold. 5. The method of claim 4 , wherein a plurality of pulses, generated by a controller of the circuit, are adjusted based on the sensed signal to control a switch of the energy transfer module. 6. The method of claim 5 , therein the sensed signal is lower than the threshold at least over three consecutive pulses in the plurality of pulses. 7. The method of claim 1 , further comprising: controlling the energy transfer module based on states of the state machine. 8. The method of claim 1 , further comprising: implementing, by the TRIAC, at least two phases, a first phase and a second phase; dedicating the first phase to the TRIAC on state; and dedicating the second phase to the TRIAC off state, the first and second phases being non-overlapping. 9. The method of claim 8 , further comprising: implementing, by the TRIAC, a third phase, the first, second, and third phases being non-overlapping; and dedicating the third phase to charge a part of the TRIAC that wirelessly communicates with a control component external to the TRIAC, the third phase occurring at least once per each alternating current cycle of the TRIAC. 10. The method of claim 1 , wherein a full range from 0 to 2π in an alternating current cycle of the TRIAC has a first phase range of an interval from 0 to β, a second phase range of an interval from β to α dedicated to the TRIAC off state, a third phase range of an interval from α to π dedicated to the TRIAC on state, a fourth phase range of an interval from π to (π+α) dedicated to the TRIAC off state, and a fifth phase range of an interval from (π+α) to 2π dedicated to the TRIAC on state, the first, second, third, fourth, and fifth phase ranges being non-overlapping. 11. A circuit including a controller configured to: receive a sensed signal corresponding to a current flowing through an energy transfer module in response to an on/off state of a triode for alternating current (TRIAC); provide the sensed signal to a state machine that transitions between a TRIAC on state and a TRIAC off state based on the sensed signal, the TRIAC off state having a first off sub-state and a second off sub-state; transition the state machine from the TRIAC on state to the first off sub-state of the TRIAC off state; transition the state machine from the first off sub-state of the TRIAC off state to the TRIAC on state when a first condition of the state machine is satisfied; transition the state machine from the first off sub-state of the TRIAC off state to the second off sub-state of the TRIAC off state when the first condition of the state machine is not satisfied and a time duration condition of the state machine is satisfied; and transition the state machine from the second off sub-state of the TRIAC off state to the TRIAC on state when a second condition of the state machine is satisfied. 12. The circuit of claim 11 , wherein the time duration condition is that the state machine is in the first off sub-state of the TRIAC off state for more than half of a total TRIAC off time. 13. The circuit of claim 11 , wherein the controller is further configured to determine a total TRIAC off time based on a previous time duration that, the state machine is in the TRIAC off state. 14. The circuit of claim 11 , wherein the state machine transitions from the TRIAC on state to the first off sub-state of the TRIAC off state when the sensed signal is lower than a threshold. 15. The circuit of claim 14 , wherein a plurality of pulses, generated by the controller, are adjusted based on the sensed signal to control a switch of the energy transfer module. 16. The circuit of claim 15 , wherein the sensed signal is lower than the threshold at least over three consecutive pulses in the plurality of pulses. 17. The circuit of claim 11 , wherein the controller is further configured to control the energy transfer module based on states of the state machine. 18. The circuit of claim 11 , wherein the controller is further configured to: implement, by the TRIAC, at least two phases, a first phase and a second phase; dedicate the first phase to the TRIAC on state; and dedicate the second phase to the TRIAC off state, the first and second phases being non-overlapping. 19. The circuit of claim 18 , wherein the controller is further configured to: implement, by the TRIAC, a third phase, the first, second, and third phases being non-overlapping; and dedicate the third phase to charge a part of the TRIAC that wirelessly communicates with a control component external to the TRIAC, the third phase occurring at least once per each alternating current cycle of the TRIAC. 20. The circuit of claim 11 , wherein a full range from 0 to 2π in an alternating current cycle of the TRIAC has a first phase range of an interval from 0 to β, a second phase range of an interval from β to α dedicated to the TRIAC off state, a third phase range of an interval from α to π dedicated to the TRIAC on state, a fourth phase range of an interval from π to (π+α) dedicated to the TRIAC off state, and a fifth phase range of an interval from (π+α) to 2π dedicated to the TRIAC on state, the first, second, third, fourth, and fifth phase ranges being non-overlapping.