Sensor-less buck current regulator with average current mode control

We claim: 1. A buck converter controller integrated circuit comprising: a replica circuit including a replica transistor and a current sense amplifier, wherein the current sense amplifier is configured to drive the replica transistor with a first replica current equaling a scaled version of a current through a low-side switch transistor, and wherein the current sense amplifier is further configured to output a second replica current equaling another scaled version of the current through the low-side switch transistor; a sample switch configured to sample the second replica current during a sampling window to produce a sampled signal; an error amplifier configured to compare the sampled signal to a first reference signal to generate an error signal during the sampling window; and a controller configured to control a cycling of a high-side switch transistor and the low-side switch transistor responsive to the error signal, wherein the sample switch is disposed between the current sense amplifier and the error amplifier such that when the sample switch is open, the sampled signal is held at the error amplifier for the error signal. 2. The buck converter controller integrated circuit of claim 1 , wherein the replica transistor is a first replica transistor having a drain coupled to a drain of the low-side switch transistor and having a source coupled to a first input of the current sense amplifier, and wherein the replica circuit further includes a second replica transistor coupled between a source of the low-side switch transistor and a second input of the current sense amplifier, wherein the current sense amplifier is configured to compare the first input of the current sense amplifier and the second input of the current sense amplifier. 3. The buck converter controller integrated circuit of claim 2 , wherein a first output of the current sense amplifier is coupled to the source of the first replica transistor, and the wherein current sense amplifier is further configured to output the second replica current on a second output of the current sense amplifier. 4. The buck converter controller integrated circuit of claim 1 , wherein the reference signal is a reference voltage and the error signal is an error voltage, the buck converter controller integrated circuit further comprising: a temperature-compensated resistor configured to receive the second replica current to generate a voltage, wherein the error amplifier is configured to compare the voltage to the reference voltage to generate the error voltage. 5. The buck converter controller integrated circuit of claim 4 , wherein the error amplifier is an integrator error amplifier configured to integrate the error voltage during the sampling window. 6. The buck converter controller integrated circuit of claim 4 , further comprising: a voltage-to-current amplifier configured to translate the error voltage into a ramp current; and a ramp capacitor configured to generate a ramp voltage responsive to the ramp current. 7. The buck converter controller integrated circuit of claim 6 , further comprising: a pulse-width-modulator (PWM) latch; a PWM comparator configured to compare the ramp voltage to a first reference voltage VREF to generate a set signal for the PWM latch; a falling edge comparator configured to compare the ramp voltage to a first divided version of a reference voltage VREF to terminate the sampling window; a rising edge comparator configured to compare the ramp voltage to a second divided version of the reference voltage VREF to begin the sampling window, wherein the first divided version of the reference voltage VREF is greater than the second divided version of the reference voltage VREF. 8. The buck converter controller integrated circuit of claim 7 , further comprising: a shorting switch configured to ground the ramp voltage responsive to a true data output signal from the PWM latch. 9. The buck converter controller integrated circuit of claim 7 , wherein the PWM latch is configured to be reset responsive to a clock signal, wherein the PWM latch is configured to command the high-side switch transistor to be cycled on while the PWM latch is set and to command the high-side switch transistor to be cycled off while the PWM latch is reset. 10. A method of controlling a buck converter, comprising: replicating a current through a low-side switch transistor through a replica transistor to generate a scaled replica current of the current through the low-side switch transistor; sampling the scaled replica current during a sampling window, wherein the sampling window occurs during an on time for the low-side switch transistor to generate a sampled signal; holding the sampled signal at an error amplifier by opening a sample switch disposed between a current sense amplifier and the error amplifier; comparing the held signal to a reference signal to generate an error signal; and controlling an on time of a high-side switch transistor and the on time of the low-side switch transistor responsive to the error signal. 11. The method of claim 10 , wherein replicating the current through the low-side switch transistor through the replica transistor to generate the scaled replica current of the current through the low-side switch transistor comprises driving the low-side switch transistor responsive to feedback from a current sense amplifier to force the replica transistor to have a drain-to-source voltage equaling a drain-to-source voltage for the low-side switch transistor and to have a gate-to-source voltage equaling a gate-to-source voltage for the low-side switch transistor. 12. The method of claim 10 , wherein sampling the scaled replica current during the sampling window comprises sampling a voltage derived from the scaled replica current during the sampling window to generate a sampled signal voltage; and wherein comparing the held signal to the reference signal to generate the error signal comprises comparing the held signal voltage to a reference voltage to generate an error voltage. 13. The method of claim 12 , further comprising: integrating the error voltage during the sampling window. 14. The method of claim 12 , further comprising: converting the error voltage into an error current; charging a ramp capacitor with the error current to generate a ramp voltage; comparing the ramp voltage to a reference voltage VREF to generate a set signal when the ramp voltage equals the reference voltage VREF; setting a pulse width modulator (PWM) latch responsive to the set signal; and resetting the PWM latch responsive to a clock signal. 15. The method of claim 14 , further comprising: driving a high-side switch transistor on while the PWM latch is set; and driving the low-side switch transistor on while the PWM latch is reset.