Energy-harvesting apparatus with plural mechanical amplifiers

The invention claimed is: 1. An energy harvester for harvesting energy from an input vibration, comprising: a first mechanical amplifier responsive to the input vibration; and a second mechanical amplifier coupled to and driven with an output of the first mechanical amplifier; in which at least one of the first and second mechanical amplifiers comprises a parametric resonator driven in parametric resonance; and in which an energy harvester power output is generated by electrically damping the second mechanical amplifier. 2. An energy harvester according to claim 1 , in which said energy harvester power output is an electrical power output and the second mechanical amplifier is electrically damped to generate the electrical power output. 3. An energy harvester according to claim 1 , in which the first mechanical amplifier is not electrically damped. 4. An energy harvester according to claim 1 , in which the first mechanical amplifier is not electrically damped. 5. An energy harvester according to claim 1 , in which the first mechanical amplifier comprises the parametric resonator. 6. An energy harvester according to claim 5 , in which the second mechanical amplifier comprises a non-resonant mechanical amplifier, a direct resonator or a further parametric resonator. 7. An energy harvester according to claim 6 , in which the non-resonant mechanical amplifier, the direct resonator or the further parametric resonator is electrically damped to generate said energy harvester power output. 8. An energy harvester according to claim 6 , in which the second mechanical amplifier comprises a further mechanical amplifier, coupled to the non-resonant mechanical amplifier, the direct resonator or the further parametric resonator, and in which the further mechanical amplifier is damped to generate said energy harvester power output. 9. An energy harvester according to claim 1 , in which the second mechanical amplifier comprises the parametric resonator. 10. An energy harvester according to claim 9 , in which the first mechanical amplifier comprises a direct resonator. 11. An energy harvester according to claim 10 , in which the direct resonator of the first mechanical amplifier and the parametric resonator of the second mechanical amplifier form an auto-parametric amplifier. 12. An energy harvester according to claim 10 , in which the resonant frequency of the direct resonator is a sub-multiple of the resonant frequency of the parametric resonator. 13. An energy harvester according to claim 9 , in which the first mechanical amplifier is a non-resonant mechanical amplifier. 14. An energy harvester according to claim 9 , in which the parametric resonator is electrically damped to generate said energy harvester power output. 15. An energy harvester according to claim 9 , in which the second mechanical amplifier comprises a further mechanical amplifier, coupled to the parametric resonator, and in which the further mechanical amplifier is electrically damped to generate said energy harvester power output. 16. An energy harvester according to claim 1 , in which the energy harvester is a macro-scale device, a micro-scale device, a thick-film device, a thin-film device or a MEMS device. 17. An energy harvester according to claim 1 , in which the first and second mechanical amplifiers provide first and second degrees of freedom. 18. An energy harvester according to claim 1 , in which the first mechanical amplifier has a rest position which is in an unstable equilibrium. 19. An energy harvester according to claim 1 , comprising one or more resonators which can be excited in at least one of the direct and parametric resonance. 20. An energy harvester for harvesting energy from an input vibration, comprising: a first mechanical amplifier responsive to the input vibration; and a second mechanical amplifier coupled to and driven with an output of the first mechanical amplifier driven in parametric resonance; in which at least one of the first and second mechanical amplifiers comprises a parametric resonator; and an electrical damping mechanism for generating an energy harvester power output, in which the electrical damping mechanism does not act directly on the first mechanical amplifier. 21. A method for harvesting mechanical vibration, comprising the steps of: driving a first mechanical amplifier with the vibration; driving a second mechanical amplifier with an output of the first mechanical amplifier; and extracting a power output by electrically damping the second mechanical amplifier; in which at least one of the first and second mechanical amplifiers is a resonator driven in parametric resonance. 22. An energy harvester for harvesting energy from an input vibration, comprising: a first mechanical amplifier comprising a direct resonator responsive to the input vibration; and a second mechanical amplifier coupled to the first mechanical amplifier and comprising a parametric resonator; in which a resonant frequency ω of the direct resonator is a sub-multiple of a resonant frequency ω the parametric resonator, such that ω= 2 ω 0 ln, where n is the order of the sub-multiple; and in which an energy harvester power output is generated by electrically damping the second mechanical amplifier. 23. The energy harvester of claim 22 , in which a resonant frequency of the direct resonator of the first mechanical amplifier is about twice a resonant frequency of the parametric resonator of the second mechanical amplifier.