Power conversion apparatus

The invention claimed is: 1. Power conversion apparatus configured to receive a high voltage alternating current (AC) signal at an input and to provide in dependence thereon a low voltage direct current (DC) signal from an output stage, the power conversion apparatus comprising: a main path comprising a high voltage capacitor in series with the input; a first path operative to carry current carried by the main path in at least one of a positive going part and a negative going part of the high voltage alternating current signal; a second path operative to carry current carried by the main path in the positive going part and negative going part of the high voltage alternating current signal; and first and second switches which are operative to determine when a respective one of the first and second paths carries current, in which the output stage receives current flowing in the first path and at least one of the first and second switches is operable in dependence on a control signal derived from the low voltage direct current signal. 2. Power conversion apparatus according to claim 1 configured to receive a mains AC signal at the input and to provide in dependence thereon an electronic circuit power supply at the output stage. 3. Power conversion apparatus according to claim 1 , wherein a peak voltage of the high voltage AC signal is higher than a voltage of the low voltage DC signal. 4. Power conversion apparatus according claim 1 , wherein the first and second switches are operative substantially out of phase with each other whereby the first and second switches are not closed at the same time. 5. Power conversion apparatus according to claim 1 configured such that the first path is in series with the output stage and the second path is in parallel with the output stage. 6. Power conversion apparatus according to claim 1 , wherein the second path provides for conduction between a high side of the input to the power conversion apparatus and a low side of the power conversion apparatus, the high voltage capacitor being in series with the high side of the input to the power conversion apparatus. 7. Power conversion apparatus according to claim 1 , wherein the first path comprises the first switch, the first switch being in series between the input to and the output stage of the power conversion apparatus. 8. Power conversion apparatus according to claim 1 , wherein the second path comprises the second switch, the second switch being in parallel with high and low sides of the input to the power conversion apparatus. 9. Power conversion apparatus according to claim 1 , wherein at least one of the first and second switches is operated in dependence on a control signal at a frequency higher than a frequency of the high voltage AC signal. 10. Power conversion apparatus according to claim 1 , comprising a holding capacitor which is electrically coupled in parallel with the output stage. 11. Power conversion apparatus according to claim 1 , wherein each of the first and second paths is operative to carry current in less than all of the positive going part or negative going part within a cycle of the high voltage AC signal. 12. Power conversion apparatus according to claim 1 configured for at least one of: the first path not being operative to carry current every positive going part or negative going part within a cycle of the high voltage AC signal; and the second path being operative to carry current during plural cycles of the high voltage AC signal. 13. Power conversion apparatus according to claim 1 further comprising a switch control circuit which is operative to generate at least one control signal in dependence on a determination made in respect of a condition of at least one signal in the power conversion apparatus. 14. Power conversion apparatus according to claim 13 in which the switch control circuit is configured to make a measurement in the power conversion apparatus and to compare the measurement with a reference value and to generate a control signal in dependence on the comparison, the measurement comprising at least one of: a voltage across the second switch; a voltage at the output stage; a voltage across the first switch; a direction of flow of current in the second path; and a voltage across the input. 15. Power conversion apparatus according to claim 1 configured such that the second switch is operable in dependence on a control signal derived from the low voltage DC current signal. 16. Power conversion apparatus according to claim 1 configured such that the first path carries current in only one of the positive and negative going parts of the high voltage AC signal. 17. Power conversion apparatus according to claim 16 configured such that the first path carries current in only the positive going part of the high voltage AC signal, the power conversion apparatus being configured such that the second path carries current in the negative and positive going parts of the high voltage AC signal. 18. Power conversion apparatus according to claim 16 comprising solely one switch in the first path and solely one switch in the second path. 19. Power conversion apparatus according to claim 1 configured such that the first path carries current in both the positive and negative going parts of the high voltage AC signal, the power conversion apparatus comprising an intermediate energy storing component and third, fourth and fifth switches which are each operable in dependence on a control signal derived from the low voltage direct current signal. 20. Power conversion apparatus according to claim 19 in which the intermediate energy storing component comprises one of an intermediate capacitor and an intermediate inductor, the intermediate energy storing component being disposed in series between the high voltage capacitor and the output stage. 21. Power conversion apparatus according to claim 19 configured such that a third path comprising the intermediate energy storing component carries current during a first portion of one of the positive and negative going parts of the high voltage AC signal. 22. Power conversion apparatus according to claim 21 in which the intermediate energy storing component stores charge during the negative going part, the third switch being connected at a first end to a first end of the intermediate energy storing component which is a closer end of first and second ends of the intermediate energy storing component to the output stage and connected at a second end to a low side of the power conversion apparatus. 23. Power conversion apparatus according to claim 22 and where the intermediate energy storing component is an intermediate capacitor, the fourth switch is connected at a first end to a second end of the intermediate capacitor and at a second end to a low side of the power conversion apparatus and wherein the intermediate energy storing component is an intermediate inductor, the fourth switch is connected at a first end to the second end of the intermediate inductor and at a second end to the output stage. 24. Power conversion apparatus according to claim 23 in which the fifth switch is connected at a first end to the first end of the intermediate energy storing component and at a second end to the output stage whereby the fifth switch is in series between the intermediate energy storing component and the output stage. 25. A power conversion arrangement comprising plural instances of