Vibration power generator, vibration monitoring device, and vibration monitoring system

What is claimed is: 1. A vibration power generator comprising: a vibration system attached to a vibrating member; wherein the vibration system includes a first vibration subsystem, and a second vibration subsystem attached to the first vibration subsystem, the first vibration subsystem includes a first mass member and a first elastic member configured to elastically couple the first mass member to the vibrating member, the second vibration subsystem includes a plate spring integral with a piezoelectric element, and a second mass member attached to the plate spring, the first vibration subsystem has a resonant frequency that is substantially equal to a resonant frequency of the second vibration subsystem, a resonance amplification factor of the second vibration subsystem is greater than a resonant amplification factor of the first vibration subsystem, a product of a mass of the first mass member and the resonance amplification factor of the first vibration subsystem is greater than a product of a mass of the second mass member and the resonance amplification factor of the second vibration subsystem, and the first elastic member is an elastic rubber body in a form of a block. 2. The vibration power generator of claim 1 , wherein the mass of the first mass member is at least five times the mass of the second mass member. 3. The vibration power generator of claim 1 , wherein the second vibration subsystem has a resonant frequency that is higher than or equal to 90% and lower than or equal to 110% of a resonant frequency of the first vibration subsystem. 4. The vibration power generator of claim 1 , wherein the piezoelectric element includes a piezoelectric film provided on a surface of the plate spring, and a compressive stress is applied to the piezoelectric film. 5. The vibration power generator of claim 4 , wherein the piezoelectric film has a lower coefficient of thermal expansion than the plate spring. 6. The vibration power generator of claim 5 , wherein the compressive stress is a residual stress caused by a difference between coefficients of thermal expansion of the plate spring and the piezoelectric film. 7. The vibration power generator of claim 1 , wherein a position of the second mass member on the plate spring is adjustable. 8. The vibration power generator of claim 1 , wherein the first vibration subsystem includes an adjustment mass member attached to the first mass member. 9. The vibration power generator of claim 1 , wherein the second vibration subsystem has a resonant frequency that is higher than or equal to 95% and lower than or equal to 105% of a resonant frequency of the first vibration subsystem. 10. The vibration power generator of claim 1 , wherein a direction of vibration of the first vibration subsystem is substantially identical to a direction of vibration of the second vibration subsystem. 11. A vibration monitoring device comprising: a vibration power generator; and a signal transmitter driven by the vibration power generator, wherein the vibration power generator comprises a vibration system attached to a vibrating member, the vibration system includes a first vibration subsystem, and a second vibration subsystem attached to the first vibration subsystem, the first vibration subsystem includes a first mass member, and a first elastic member configured to elastically couple the first mass member to the vibrating member, the second vibration subsystem includes a plate spring integral with a piezoelectric element, and a second mass member attached to the plate spring, the first vibration subsystem has a resonant frequency that is substantially equal to a resonant frequency of the second vibration subsystem, a resonance amplification factor of the second vibration subsystem is greater than a resonant amplification factor of the first vibration subsystem, a product of a mass of the first mass member and the resonance amplification factor of the first vibration subsystem is greater than a product of a mass of the second mass member and the resonance amplification factor of the second vibration subsystem, and the first elastic member is an elastic rubber body in a form of a block. 12. The vibration monitoring device of claim 11 , wherein the vibrating member has a first operating states to produce vibrations in a first frequency band, and the vibration system has a resonant frequency that falls within the first frequency band. 13. The vibration monitoring device of claim 11 , wherein the vibrating member has a first operating state to produce vibrations in a first frequency band, and the vibrating member has a second operating state to produce vibrations in a second frequency band, and the vibration system has a resonant frequency that falls within the second frequency band. 14. A vibration monitoring system comprising: a plurality of vibration monitoring devices, wherein each of the vibration monitoring devices includes: a vibration power generator; and a signal transmitter driven by the vibration power generator, the vibration power generator comprises a vibration system attached to a vibrating member, the vibration system includes a first vibration subsystem, and a second vibration subsystem attached to the first vibration subsystem, the first vibration subsystem includes a first mass member, and a first elastic member configured to elastically couple the first mass member to the vibrating member, the second vibration subsystem includes a plate spring integral with a piezoelectric element, and a second mass member attached to the plate spring, the first vibration subsystem has a resonant frequency that is substantially equal to a resonant frequency of the second vibration subsystem, a resonance amplification factor of the second vibration subsystem is greater than a resonant amplification factor of the first vibration subsystem, a product of a mass of the first mass member and the resonance amplification factor of the first vibration subsystem is greater than a product of a mass of the second mass member and the resonance amplification factor of the second vibration subsystem, the first elastic member is an elastic rubber body in a form of a block, the vibrating member has a plurality of states to produce vibrations in different frequency bands, and the resonant frequencies of the vibration systems of the vibration monitoring devices correspond to the different states of the vibrating member.