Multi-bleeder mode control for improved LED driver performance

What is claimed is: 1. A multi-bleeder circuit for a light-emitting diode (LED) driver circuit, the multi-bleeder circuit comprising: a first bleeder circuit; a second bleeder circuit; and a controller coupled to receive a line sense signal representative of an input voltage, a bleeder current sense signal representative of a current conducted through the second bleeder circuit, and a return current sense signal representative of a return current from a load, wherein the controller is further coupled to activate and deactivate the first and second bleeder circuits based on the line sense signal, the bleeder current sense signal, and the return current sense signal, wherein the input voltage comprises a phase-controlled rectified input voltage from a dimming circuit and a rectifier, and wherein the controller is configured to: in response to the LED driver circuit turning on: cause the first switching element to be in the OFF state; and operate the second bleeder circuit in a first mode of operation; in response to a supply voltage of the controller increasing to a supply threshold value: cause the first switching element to be in the OFF state for a delay period after the supply voltage of the controller increases to the supply threshold value; and operate the second bleeder circuit in a second mode of operation for the delay period after the supply voltage of the controller increases to the supply threshold value; in response to determining that the dimming circuit has not performed phase-angle dimming after the delay period: cause the first switching element to be in the OFF state; and operate the second bleeder circuit in a fourth mode of operation; in response to determining that the dimming circuit has performed leading-edge dimming after the delay period: cause the first switching element to be in the ON state; and operate the second bleeder circuit in the second mode of operation; and in response to determining that the dimming circuit has performed trailing-edge dimming after the delay period: cause the first switching element to be in the OFF state; and operate the second bleeder circuit in a third mode of operation. 2. The multi-bleeder circuit of claim 1 , wherein the controller is configured to control the first bleeder circuit using an open-loop control, and wherein the controller is configured to control the second bleeder circuit using a closed-loop control based on the bleeder current sense signal and the return current sense signal. 3. The multi-bleeder circuit of claim 1 , wherein the return current comprises a summation of a current conducted through the load and the current conducted through the second bleeder circuit. 4. The multi-bleeder circuit of claim 1 , wherein the controller is coupled to receive the return current sense signal from a return current sense resistor that is coupled to receive the return current, and wherein the return current sense signal comprises a voltage across the return current resistor. 5. The multi-bleeder circuit of claim 1 , wherein the first bleeder circuit comprises an open loop control of current in the first bleeder circuit. 6. The multi-bleeder circuit of claim 5 , wherein the open loop control of current in the first bleeder circuit is implemented using a first switching element, and wherein the controller is coupled to activate and deactivate the first bleeder circuit by switching the first switching element between an ON state and an OFF state. 7. The multi-bleeder circuit of claim 1 , wherein the second bleeder circuit comprises a closed loop control of current in the second bleeder circuit. 8. The multi-bleeder circuit of claim 7 , wherein the closed loop control of current in the second bleeder circuit is implemented using a second switching element, and wherein the controller is coupled to activate and deactivate the second bleeder circuit by sinking or sourcing current to the second switching element. 9. The multi-bleeder circuit of claim 8 , wherein the closed loop control of current in the second bleeder circuit is implemented using a linear mode control of the second switching element, and wherein the controller linearly controls the activation of the second switching element to conduct in a linear mode in a closed-loop response to the bleeder current sense signal and the return current sense signal. 10. The multi-bleeder circuit of claim 8 , wherein the closed-loop control of current in the second bleeder circuit is implemented using pulse width modulation (PWM) mode by switching the second switching element between an ON state and an OFF state. 11. The multi-bleeder circuit of claim 1 , wherein the dimming circuit comprises a phase-controlled Triac dimming circuit. 12. The multi-bleeder circuit of claim 1 , wherein in the first mode of operation the controller is configured to cause the second switching element to be latched in the ON state. 13. The multi-bleeder circuit of claim 1 , wherein in the second mode of operation the controller is configured to: cause the second switching element to be in the ON state in response to the start of a cycle of the line sense signal until it is determined that the dimming circuit has performed leading-edge dimming or it is determined that the line sense signal is greater than an upper threshold value; in response to determining that the dimming circuit has performed leading-edge dimming or determining that the line sense signal is greater than the upper threshold value, operating the second bleeder circuit in a closed-loop based on the bleeder current sense signal and the return current sense signal until the line sense signal decreases below a lower threshold value; and in response to the line sense signal decreasing below the lower threshold value, transferring operation of the second switching element from closed-loop control to be latched in the ON state. 14. The multi-bleeder circuit of claim 1 , wherein in the third mode of operation the controller is configured to: cause the second switching element to be in the OFF state in response to a zero-crossing of the line sense signal until it is determined that a trailing-edge drop in the line sense signal has occurred or it is determined that the line sense signal is below a lower threshold value; and in response to determining that the trailing-edge drop in the line sense signal has occurred or determining that the line sense signal is below the lower threshold value, causing the second switching element to be latched in the ON state. 15. The multi-bleeder circuit of claim 1 , wherein in the fourth mode of operation the controller is configured to cause the second switching element to be latched in the OFF state. 16. A light-emitting diode (LED) driver circuit comprising: an input to be coupled to receive an alternating current (ac) input voltage; a Triac dimming circuit coupled to the input to receive the ac input voltage and output a phase-controlled ac input voltage; a rectifier coupled to receive the phase-controlled ac input voltage and output a phase-controlled rectified input voltage; a power converter coupled to receive the phase-controlled rectified input voltage and output a regulated output signal to a load; a first bleeder circuit coupled between the rectifier and the power converter; a second bleeder circuit coupled between the rectifier and the power converter; and a controller coupled to receive a line sense signal representative of a voltage of the phase-controlled rectified input voltage, a bleeder current sense signal representative of a current conducted through the second bleeder c