Buck-boost converter with small disturbance at mode transitions

The invention claimed is: 1. A Buck-Boost switching power converter, comprising: a mode transition detector, configured to monitor Buck and Boost pulse-width modulation (PWM) input signals, and to detect skipping or regeneration of said input signals; an error amplifier; a main compensation capacitor, at an output of said error amplifier; and charge and discharge circuitry, comprising a PMOS current source, and a NMOS current source, configured to charge or discharge said main compensation capacitor during a mode transition, based on detection of said mode transition by said mode transition detector, wherein for a mode transition from Buck to ½frequency Buck, from Buck to Buck-Boost, from Buck-Boost to Boost, and from ½frequency Boost to Boost, said PMOS current source is configured to be on, and wherein for a mode transition from Boost to ½frequency Boost, from Boost to Buck-Boost, from Buck-Boost to Buck, and from ½frequency Buck to Buck, said NMOS current source is configured to be on. 2. The Buck-Boost switching power converter of claim 1 , wherein said mode transition detector further comprises digital logic gates, configured to detect a mode transition between said PWM input signals. 3. The Buck-Boost switching power converter of claim 1 , further comprising a pulse signal generator connected between said mode transition detector and said charge and discharge circuitry. 4. The Buck-Boost switching power converter of claim 3 , wherein said pulse signal generator is configured to skip or regenerate said PWM input signals, during said mode transition. 5. The Buck-Boost switching power converter of claim 3 , wherein said pulse signal generator is configured to output a pulse having a signal width of one clock cycle. 6. The Buck-Boost switching power converter of claim 1 , wherein said main compensation capacitor is charged or discharged, such that said output of said error amplifier is shifted close to a target value. 7. The Buck-Boost switching power converter of claim 1 , wherein said error amplifier comprises an operational transconductance amplifier. 8. The Buck-Boost switching power converter of claim 7 , wherein said error amplifier is configured to receive inputs comprising a reference voltage and a feedback output voltage. 9. The Buck-Boost switching power converter of claim 8 , further comprising a feed-forward gain path connected across said error amplifier inputs and having a feed-forward capacitor at its output. 10. The Buck-Boost switching power converter of claim 9 , wherein a feed-forward resistor is connected across said main compensation capacitor and said feed-forward capacitor. 11. The Buck-Boost switching power converter of claim 10 , wherein said main compensation capacitor is charged or discharged, such that said output of said error amplifier is shifted close to a target value across said feed-forward resistor. 12. The Buck-Boost switching power converter of claim 1 , wherein said charge and discharge circuitry comprises control switches for said current sources. 13. The Buck-Boost switching power converter of claim 12 , wherein said charge and discharge circuitry is configured such that one of said control switches for said PMOS or NMOS current sources is turned on. 14. A method for operating a Buck-Boost switching converter comprising the steps of: monitoring Buck and Boost pulse-width modulation (PWM) input signals to detect a mode transition, and skippinq or regenerating said input signals; providing an error amplifier, and a main compensation capacitor at an output of said error amplifier; and charging said main compensation capacitor with a PMOS current source for said mode transition from Buck to ½frequency Buck, from Buck to Buck-Boost, from Buck-Boost to Boost, and from ½frequency Boost to Boost or discharging said main compensation capacitor with a NMOS current source for said mode transition from Boost to ½frequency Boost, from Boost to Buck-Boost, from Buck-Boost to Buck, and from ½frequency Buck to Buck, based on detection of said mode transition. 15. The method of claim 14 , further comprising a pulse signal generator that skips or regenerates said PWM input signals, during said mode transition. 16. The method of claim 15 , wherein said pulse signal generator outputs a pulse having a signal width of one clock cycle. 17. The method of claim 14 , wherein said main compensation capacitor charges or discharges, such that said output of said error amplifier shifts close to a target value. 18. The method claim 14 , wherein said error amplifier receives inputs comprising a reference voltage and a feedback output voltage. 19. The method of claim 18 , further comprising a feed-forward gain path connected across said error amplifier inputs and a feed-forward capacitor. 20. The method of claim 19 , wherein a feed-forward resistor connects across said main compensation capacitor and said feed-forward capacitor. 21. The method of claim 20 , wherein said main compensation capacitor charges or discharges, such that said output of said error amplifier shifts close to a target value across said feed-forward resistor.