Systems and methods of adjusting slope compensation

What is claimed is: 1. A method comprising: operating a switching power converter comprising a charge control switch and a circuit controller, the charge control switch configured to control power flow through the switching power converter; measuring, by the circuit controller, an attribute of duty cycle of a first period of the charge control switch; measuring, by the circuit controller, an attribute of duty cycle of a second period of the charge control switch; measuring, by the circuit controller, an attribute of duty cycle of a third period of the charge control switch; determining, by the circuit controller, that the switching power converter is experiencing subharmonic oscillation based on the attributes of duty cycle of the first, second, and third periods of the charge control switch; and changing, by the circuit controller, an attribute of slope compensation responsive to the determining that the switching power converter is experiencing subharmonic oscillation. 2. The method of claim 1 wherein measuring the attributes of duty cycle in the first, second, and third periods of the charge control switch further comprises measuring conduction time of the charge control switch in each of the first, second, and third periods. 3. The method of claim 1 wherein changing the attribute of slope compensation further comprises increasing a slope of a ramp signal added to a current sense signal. 4. The method of claim 1 wherein changing the attribute of slope compensation further comprises increasing a slope of ramp signal subtracted from a voltage error signal. 5. The method of claim 1 wherein the third period is consecutive with the second period, and the second period is consecutive with the first period. 6. The method of claim 1 wherein operating the switching power converter further comprises operating at least one selected from a group comprising: an inductor-capacitor resonant converter; a flyback converter; an isolated buck-type converter; a non-isolated buck-type converter; an isolated boost converter; a non-isolated boost converter; and a buck-boost converter. 7. A circuit controller for a switching power converter, the circuit controller comprising: a first drive terminal, a voltage feedback terminal, and a current sense terminal; a peak current controller coupled to the first drive terminal, the voltage feedback terminal, and the current sense terminal, the peak current controller configured to assert the first drive terminal at a switching frequency, and to de-assert the first drive terminal in each period of the switching frequency based on a signal indicative of current sensed through the current sense terminal, a signal indicative of voltage error created based on a signal sensed through the voltage feedback terminal, and a ramp signal; the peak current controller configured to sense subharmonic oscillation of the switching power converter based on attributes of duty cycle of the assertions of the first drive terminal over a plurality of periods of the switching frequency; and the peak current controller configured to change an attribute of the ramp signal responsive to detection of the subharmonic oscillation. 8. The circuit controller of claim 7 wherein when the peak current controller changes the attribute of the ramp signal, the peak current controller is further configured to increase a slope of the ramp signal. 9. The circuit controller of claim 7 wherein when the peak current controller de-asserts the first drive terminal, the peak current controller is further configured to: add the ramp signal to the signal indicative of current thereby creating a compensated current signal; and de-assert the first drive terminal in each period of the switching frequency when a magnitude of the compensated current signal crosses a magnitude of the signal indicative of voltage error. 10. The circuit controller of claim 7 wherein when the peak current controller de-asserts the first drive terminal, the peak current controller is further configured to: subtract the ramp signal from the signal indicative of voltage error thereby creating a compensated error signal; and de-assert the first drive terminal in each period of the switching frequency when a magnitude of the signal indicative of current crosses a magnitude of the compensated error signal. 11. The circuit controller of claim 7 wherein when the peak current controller senses subharmonic oscillation, the peak current controller is further configured to: measure an attribute of duty cycle of a first period of the switching frequency; measure an attribute of duty cycle of a second period of the switching frequency; measure an attribute of duty cycle of a third period of the switching frequency; and determine that the switching power converter is experiencing subharmonic oscillation based on the attributes of duty cycle of the first, second, and third periods of the switching frequency. 12. The circuit controller of claim 11 wherein when the circuit controller determines that the switching power converter is experiencing subharmonic oscillation, the circuit controller is further configured to make the determination based on a duty cycle in the first period be greater than a duty cycle in the second period, and the duty cycle in the second period being shorter than a duty cycle in the third period. 13. The circuit controller of claim 11 wherein when the circuit controller determines that the switching power converter is experiencing subharmonic oscillations, the circuit controller is further configured to make the determination based on a duty cycle in the first period be less than a duty cycle in the second period, and the duty cycle in the second period being greater than a duty cycle in the third period. 14. The circuit controller of claim 11 wherein the third period is consecutive with the second period, and the second period is consecutive with the first period. 15. A switching power converter comprising: input voltage nodes and output voltage nodes; a power circuit coupled between the input voltage nodes and the output voltage nodes, the power circuit having a charge control switch that controls power flow from the input voltage nodes to the output voltage nodes, the charge control switch having a control input; a circuit controller coupled to the power circuit and configured to sense a signal indicative of current flow through the charge control switch, and configured to sense a signal indicative of voltage on the output voltage nodes, the circuit controller configured to: assert the control input of the charge control switch at a switching frequency; de-assert the control input of the charge control switch in each period of the switching frequency based on the signal indicative of current flow through the charge control switch, a signal indicative of voltage error created based on the signal indicative of voltage on the output voltage nodes, and a ramp signal; sense subharmonic oscillation of the power circuit based on attributes of duty cycle of the assertions of the control input of the charge control switch over a plurality of periods of the switching frequency; and increase slope compensation based on detection of subharmonic oscillation. 16. The switching power converter of claim 15 wherein when the circuit controller increases slope compensation, the circuit controller is further configured to increase a slope of the ramp signal. 17. The switching power converter of claim 15 wherein when the circuit controller de-asserts the control input of the charge control switch, the