Drive circuit for a light-emitting diode light source

The invention claimed is: 1. An apparatus to adjust an intensity of a light-emitting diode (LED) source, the apparatus comprising: a dimming field effect transistor (FET) that includes a source connection, a drain connection, and a gate connection; a variable impedance FET that includes a source connection, a drain connection, and a gate connection, the variable impedance FET coupled in electrical series between the dimming FET and the LED source; and drive control circuitry coupled to a gate of the dimming FET and the gate of the variable impedance FET, the drive control circuitry to: determine a drive voltage for the variable impedance FET to adjust the impedance of the variable impedance FET achieve a target load current based on a received target intensity of the LED source transmit the determined drive voltage to the gate of the variable impedance FET; determine a pulse width modulated (PWM) drive signal for the dimming FET to adjust the dimming FET to achieve the received target intensity of the LED source, wherein the PWM drive signal includes a series of pulses having a defined pulse width that occur at a defined pulse frequency; and wherein each of the pulses included in the pulse width modulated drive signal having a duration defined by a beginning time and an ending time; transmit the determined pulse width modulated drive voltage to the dimming FET; and sample a load current of the LED source over a sample window that begins a first offset time after the beginning time of at least one pulse in the PWM drive signal and concludes a second offset time before the ending time of the at least one pulse in the PWM drive signal. 2. The apparatus of claim 1 wherein to sample the load current of the LED source over a sample window that begins a first offset time after the beginning time of at least one pulse in the PWM drive signal and concludes a second offset time before the ending time of the at least one pulse in the PWM drive signal, the drive control circuitry to further: sample the load current of the LED source at a sample frequency greater than the pulse frequency of the PWM signal, wherein the sample frequency occurs during the sample window. 3. The apparatus of claim 2 , the drive control circuitry to further: receive a plurality of load current samples at the sample frequency; and determine an average load current of the LED source using the plurality of load current samples. 4. The apparatus of claim 3 , the drive control circuitry to further: determine a deviation between the determined average load current and the target load current; and adjust the gate voltage provided to the variable impedance FET to adjust the impedance of the variable impedance FET based on the determined deviation between the determined average load current and the target load current. 5. The apparatus of claim 4 wherein to adjust the gate voltage provided to the variable impedance FET to adjust impedance of the variable impedance FET based on the determined deviation between the determined average load current and the target load current, the drive control circuitry to further: determine whether the adjusted gate voltage provided to the variable impedance FET causes the variable impedance FET to operate inside a linear region; and responsive to the determination that the adjusted gate voltage provided to the variable impedance FET causes the variable impedance FET to operate inside the linear region, adjust the gate voltage supplied to the variable impedance FET to adjust the impedance of the variable impedance FET. 6. The apparatus of claim 5 wherein to adjust the gate voltage provided to the variable impedance FET to adjust impedance of the variable impedance FET based on the determined deviation between the determined average load current and the target load current, the drive control circuitry to further: responsive to the determination that the adjusted gate voltage provided to the variable impedance FET causes the variable impedance FET to operate outside the linear region adjust at least one of: the pulse width of the PWM drive signal provided to the dimming FET; or the pulse frequency of the PWM drive signal provided to the dimming FET. 7. A method to adjust an intensity of a light-emitting diode (LED) source, the method comprising: determining, by drive control circuitry, a drive voltage for a variable impedance field effect transistor (FET) to adjust the impedance of the variable impedance FET achieve a target load current based on a received target intensity of an LED source coupled in series with the variable impedance FET; transmitting, by the drive control circuitry, the determined drive voltage to the gate of the variable impedance FET; determining, by the drive control circuitry, a pulse width modulated (PWM) drive signal for a dimming FET coupled in series with the variable impedance FET, the PWM drive signal to adjust the dimming FET to achieve the received target intensity of the LED source, wherein the PWM drive signal includes a series of pulses having a defined pulse width that occur at a defined pulse frequency; and wherein each of the pulses included in the pulse width modulated drive signal having a duration defined by a beginning time and an ending time; transmitting, by the drive control circuitry, the determined pulse width modulated drive voltage to the dimming FET; and sampling, by the drive control circuitry, a load current of the LED source over a sample window that begins a first offset time after the beginning time of at least one pulse in the PWM drive signal and concludes a second offset time before the ending time of the at least one pulse in the PWM drive signal. 8. The method of claim 7 wherein sampling the load current of the LED source over a sample window that begins a first offset time after the beginning time of at least one pulse in the PWM drive signal and concludes a second offset time before the ending time of the at least one pulse in the PWM drive signal further comprises: sampling, by the drive control circuitry, the load current of the LED source at a sample frequency greater than the pulse frequency of the PWM signal, wherein the sample frequency occurs during the sample window. 9. The method of claim 8 , further comprising: receiving, by the drive control circuitry, a plurality of load current samples at the sample frequency; and determining, by the drive control circuitry, an average load current of the LED source using the plurality of load current samples. 10. The method of claim 9 , further comprising: determining, by the drive control circuitry, a deviation between the determined average load current and the target load current; and adjusting, by the drive control circuitry, the gate voltage provided to the variable impedance FET to adjust impedance of the variable impedance FET based on the determined deviation between the determined average load current and the target load current. 11. The method of claim 10 wherein adjusting the gate voltage provided to the variable impedance FET to adjust impedance of the variable impedance FET based on the determined deviation between the determined average load current and the target load current, further comprises: determining, by the drive control circuitry, whether the adjusted gate voltage provided to the variable impedance FET causes the variable impedance FET to operate in a linear region; and responsive to the determination that the adjusted gate voltage provided to the variable impedance FET causes the variable impedance FET to operate in the linear region, adjusting, by the drive control circuitry, the gate voltage supplied to the variable impedance