Constant current control buck converter without current sense

The invention claimed is: 1. A method for controlling an output current of a power supply, an output of the power supply coupled to an inductor: storing, in the inductor, power from the power supply when a switch is on and transferring power form the inductor to a load when the switch is off; sensing a voltage across the inductor; sensing a voltage across a switching current sense resistor coupled in series to the switch and to the inductor; determining a reset time of the inductor by determining a duration for the voltage across the inductor to decrease from a first value to a second value; determining a regulation voltage, wherein the regulation voltage is directly proportional to the switching period of the switch, a nominal output current value and a resistance of the switching current sense resistor, and inversely proportional to the sum of the reset time and the length of time the switch is in an on state; generating a control signal responsive to a comparison between the voltage across the switching current sense resistor and the regulation voltage, the control signal transitioning the switch to an off state responsive to the voltage across the switching current sense resistor exceeding the regulation voltage. 2. The method of claim 1 , wherein generating the control signal comprises determining the duty cycle of the control signal based on the comparison between the voltage across the switching current sense resistor and the regulation voltage. 3. The method of claim 1 , wherein the inductor discharges through a light emitting diode (LED). 4. The method of claim 1 , wherein the switch is a bipolar junction transistor (BJT). 5. The method of claim 1 , wherein the switch is a field effect transistor (FET). 6. A constant current controller comprising: a converter circuit, comprising: a switch configured to turn on or off responsive to a control signal being active or inactive, an inductor coupled to the switch configured to store power from a supply voltage when the switch is on and to transfer power to a load when the switch is off, and a switching current sense resistor coupled in series to the switch and the inductor; and a voltage sense circuit coupled to the inductor of the converter circuit, the voltage sense circuit configured to sense an inductor voltage across the inductor; and a controller comprising a first input coupled to the voltage sense circuit, a second input coupled to the switch current sense resistor and an output coupled to the switch of the converter circuit, the controller configured to: sense a voltage across the switching current sense resistor, determine a reset time of the inductor based on the sensed inductor voltage sensed by the voltage sense circuit, determine a regulation voltage from the determined reset time, a switching period of the switch and a length of time the switch is in an on state, and generate a control signal responsive to ta comparison between the voltage across the switching current sense resistor and the regulation voltage, the control signal transitioning the switch to an off state responsive to the voltage across the switching current sense resistor exceeding the regulation voltage. 7. The constant current controller of claim 6 , wherein the switching current sense resistor is configured to sense the current through the switch during the switch on time. 8. The constant current controller of claim 7 wherein the controller further comprises: a digital to analog converter (DAC), an input of the DAC coupled to the output of the regulation voltage generator and an output of the DAC coupled to the comparator, the DAC configured to convert a digital representation of the regulation voltage into an analog representation of the regulation voltage. 9. The constant current controller of claim 7 , wherein the controller comprises: a regulation voltage generator coupled to the first input of the controller, the regulation voltage generator configured to generate a regulation voltage based on the sensed inductor voltage, a length of time the switch of the converter circuit is on and a switching period of the switch; a comparator receiving the regulation voltage from the regulation voltage generator and the voltage across the switching current sense resistor, the comparator configured to generate a comparator output signal responsive to a comparison between the regulation voltage and the voltage across the switching current sense resistor; and a pulse width modulator (PWM) configured to receive the comparator output signal and generate the control signal transitioning the switch to an off state responsive to the voltage across the switching current sense resistor exceeding the regulation voltage. 10. The constant current controller of claim 9 , wherein the regulation voltage is directly proportional to the switching period of the switch and inversely proportional to the sum of a reset time and the length of time the switch of the converter circuit is on, the reset time representing a duration for a current across the inductor of the converter circuit to decrease from a peak value to a minimum value. 11. The method of claim 10 , wherein the regulation voltage is directly proportional to a nominal output current value and a resistance of the switching current sense resistor. 12. The constant current controller of claim 6 , wherein generating the control signal comprises determining the duty cycle of the control signal based on the comparison between the voltage across the switching current sense resistor and the regulation voltage. 13. The constant current controller of claim 6 further comprising: a bridge rectifier coupled to the switch, the bridge rectifier configured to rectify an alternating current (AC) supply voltage and generate a direct current (DC) supply voltage. 14. The constant current controller of claim 6 wherein the switch is a bipolar junction transistor. 15. The constant current controller of claim 6 wherein the switch is a field effect transistor (FET). 16. The constant current controller of claim 15 wherein the FET is a metal oxide semiconductor FET (MOSFET). 17. The constant current controller of claim 4 wherein the load is a light emitting diode (LED).