Switching regulator system with transition detection and filter capacitor discharge circuitry

What is claimed is: 1. A switching regulator system comprising: a switching regulator configured to generate regulated voltage pulses at a switching output in response to a setpoint of an output voltage received at a setpoint input and feedback of the output voltage received at a feedback input; a filter capacitor coupled between a filtered output and ground, wherein the filtered output is coupled to the switching output through a power inductor; a transistor configured to provide a discharge path that discharges the filter capacitor with a current between 0.25 ampere±10% and 10 amperes±10%, wherein the discharge path bypasses the power inductor with the transistor having a first current terminal coupled to the filtered output, a second current terminal coupled directly to ground, and a control input; a transition comparator having a first comparator input coupled to the setpoint input, a second comparator input coupled to the feedback input, and a comparator output coupled to the control input, wherein the transition comparator is configured to monitor for a setpoint voltage dropping below a feedback voltage and in response turn on the transistor to discharge the filter capacitor; and a slew driver coupled between the comparator output and the control input of the transistor, wherein the slew driver is configured to slow a transition time of the transistor from an off-state to an on-state by a predetermined amount. 2. The switching regulator system of claim 1 further comprising the power inductor coupled between the switching output and the filtered output. 3. The switching regulator system of claim 2 wherein the power inductor has an inductance between 0.5 microhenry and 3 microhenries. 4. The switching regulator system of claim 1 wherein the transition comparator is configured to turn on the transistor to completely discharge the filter capacitor. 5. The switching regulator system of claim 1 wherein the filter capacitor has a capacitance between 0.5 microfarad and 15 microfarads. 6. The switching regulator system of claim 1 wherein the transistor is a field-effect transistor (FET) configured to discharge the filter capacitor with a current of between 0.25 ampere and 10 amperes. 7. The switching regulator system of claim 1 further including a charge pump having a pump output coupled to the switching output and a tri-state input coupled to the comparator output, the charge pump being configured to place the switching output in a high impedance state in response to the transition comparator turning on the transistor. 8. The switching regulator system of claim 7 further comprising: an error amplifier having an error output coupled to a pump control input of the charge pump, a first error input coupled to the setpoint input, and second error input coupled to the feedback input through a first impedance and coupled to the error output through a second impedance; and an electronic shorting switch coupled across the second impedance and having a shorting control input coupled to the comparator output, wherein the electronic shorting switch is configured to short the second impedance in response to the transition comparator turning on the transistor. 9. The switching regulator of claim 7 wherein the charge pump is a buck/boost type charge pump. 10. The switching regulator system of claim 1 further comprising a transition detector having a detector input coupled to the setpoint input and an enable output coupled to an enable input of the transition comparator, wherein the transition detector is configured to detect the setpoint voltage dropping below the feedback voltage and in response to generate an enable signal at the enable output. 11. The switching regulator system of claim 10 wherein the transition detector comprises: a detector comparator having a detector output coupled to the enable output, a non-inverting input coupled to the detector input and an inverting input; a resistor coupled between the detector input and the inverting input; and a capacitor coupled between the inverting input and ground, wherein the transition detector is configured to hold the enable signal active for a duration determined by a resistance of the resistor and a capacitance of the capacitor. 12. The switching regulator system of claim 11 wherein a time constant of the resistor and capacitor is between 1 microsecond and 5 microseconds. 13. The switching regulator system of claim 11 wherein the resistor has a resistance between 100 kilohms and 500 kilohms. 14. The switching regulator system of claim 11 wherein the capacitor has a capacitance between 1 picofarad and 5 picofarads. 15. The switching regulator system of claim 11 wherein the resistor has a resistance between 500 kilohms and 1 megohm. 16. The switching regulator system of claim 11 wherein the capacitor has a capacitance between 5 picofarads and 10 picofarads. 17. The switching regulator system of claim 11 wherein the transition detector further comprises an electronic switch coupled in series with a current source between the inverting input and ground, wherein the electronic switch has a control input coupled to the detector output and is configured to close when the enable signal is active. 18. The switching regulator system of claim 10 wherein the slew driver has an enable input coupled to an enable output of the transition detector. 19. The switching regulator system of claim 1 wherein the slew driver is a FET buffer having an on-state channel resistance that combined with input capacitance of the transistor determines the transition time of the transistor from the off-state to the on-state. 20. The switching regulator system of claim 1 further comprising a digital-to-analog converter having an analog output coupled to the setpoint input and a digital input, wherein the digital-to-analog converter is configured to generate the setpoint voltage at the analog output corresponding to a digital number received at the digital input.