Rectifier

The invention claimed is: 1. An AC to DC conversion device comprising: first and second AC input terminals arranged to be coupled respectively to first and second terminals of a phase of an AC current generator; an H-bridge rectification device comprising two pairs of diodes, each pair being coupled to a respective one of the AC terminals to produce a DC output comprising a rectified back EMF waveform; and a waveform generator comprising an output coupled to the DC output of the H-bridge rectification device, and configured to input a unidirectional waveform to the DC output, the unidirectional waveform having the same magnitude and fundamental frequency as the rectified back EMF waveform, phase shifted by a predetermined angle δ relative to the rectified back EMF waveform. 2. An AC to DC conversion device according to claim 1 , wherein predetermined angle is determined in accordance with a required power in accordance with the equation: P = EV ⁢ sin ⁢ δ XL . 3. An AC to DC conversion device according to claim 1 , wherein power input of the waveform generator is coupled to the DC output of the H-bridge rectification device. 4. An AC to DC conversion device according to claim 1 , wherein the waveform generator comprises a half-bridge or full bridge converter coupled between the first and second DC outputs of the H-bridge rectifier. 5. An AC to DC conversion device according to claim 4 , wherein the waveform generator comprises a plurality of half-bridge or full-bridge rectifiers connected in series. 6. An AC to DC conversion device according to claim 1 , wherein a power input of the waveform generator is coupled to an energy storage device such as a chemical battery, capacitor or fuel cell. 7. An AC to DC conversion device according to claim 4 , wherein the energy storage device is coupled across terminals of a capacitor VCn of the half-bridge inverter. 8. An AC to DC conversion device according to claim 6 , wherein a DC to DC converter configured to provide a constant input voltage to the waveform generator is provided between the input to the waveform generator and the power storage device, and wherein the DC to DC converter may be coupled across opposite terminals of a capacitor of the half-bridge inverter. 9. An AC to DC conversion device according to claim 1 , wherein the waveform generator comprises a half-bridge or full-bridge inverter coupled across either of the positive and negative DC output side of the H-bridge rectification device. 10. An AC to DC conversion device according to claim 9 , wherein the conversion device comprises a first inverter coupled across the positive DC output of the H-bridge rectification device, and a second inverter coupled across the negative DC output of the H-bridge rectification device. 11. An AC to DC conversion device according to claim 10 , wherein the waveform generator comprises a fixed voltage input coupled between an input of the inverter and the negative or positive DC output of the H-bridge rectification device. 12. An AC to DC conversion device according to claim 10 , wherein the waveform generator comprises a plurality of half-bridge or full-bridge inverters coupled in series across the positive or negative DC output of the H-bridge rectification device. 13. An electrical generation system comprising: an electrical generator comprising a stator comprising one or more stator windings arranged in one or more phases; and an AC to DC conversion device according to claim 1 coupled to the stator windings of the electrical generator. 14. An electrical generation system according to claim 13 , wherein the electrical generator comprises two or more phases which may be configured to operate at 2π/n radians from one another, where n represents the number of phases. 15. An electrical generation system according to claim 14 , wherein first and second terminals of each phase are associated with a respective AC to DC conversion device. 16. An electrical generation system according to claim 13 , wherein the electrical generation system comprises an AC to DC conversion device associated with each phase, having DC outputs connected in series. 17. An electrical generation system according to claim 13 , wherein the waveform generator is configured to provide a voltage to oppose the back EMF waveform of the DC output of the H-bridge rectification device. 18. An electrical generation system according to claim 13 , wherein the electrical generator and waveform generator are each configured to provide a non-sinusoidal waveform such as a trapezoidal waveform. 19. A method of operating an AC to DC conversion device, said AC to DC conversion device comprising: first and second AC input terminals arranged to be coupled respectively to first and second terminals of a phase of an AC current generator; an H-bridge rectification device comprising two pairs of diodes, each pair being coupled to a respective one of the AC terminals to produce a DC output comprising a rectified back EMF waveform; and a waveform generator comprising an output coupled to the DC output of the H-bridge rectification device, and configured to input a unidirectional waveform to the DC output, the unidirectional waveform having the same magnitude and fundamental frequency as the rectified back EMF waveform, phase shifted by a predetermined angle δ relative to the rectified back EMF waveform; wherein the method comprises providing a unidirectional waveform to the DC output, the unidirectional waveform having the same magnitude and fundamental frequency as the rectified back EMF, phase shifted by a predetermined angle relative to the rectified back EMF waveform. 20. A method according to claim 19 , wherein the generator comprises a wound field generator, and the method comprises controlling electrical generator field windings to control generator output AC voltage.