Dielectric elastomer vibration system and power supply device

The invention claimed is: 1. A dielectric elastomer vibration system, comprising: a dielectric elastomer vibrator that includes a dielectric elastomer layer and a pair of electrode layers sandwiching the dielectric elastomer layer; and a power supply device that produces a potential difference across the pair of electrode layers, wherein the dielectric elastomer vibrator exhibits a relationship between the potential difference across the pair of electrode layers and an amount of deformation induced by the potential difference, the relationship having: a high-response region in which a relatively large deformation is induced in response to change of the potential difference; a low-response region of lower-potential difference corresponding to a lower potential difference than the high-response region and in which a relatively small deformation is induced in response to change of the potential difference; and a low-response region of higher-potential difference corresponding to a higher potential difference than the high-response region and in which a relatively small deformation is induced in response to change of the potential difference or in which a break point of the dielectric elastomer layer is included, and the power supply device produces the potential difference by applying a vibration signal voltage across the pair of electrode layers, the vibration signal voltage being generated by combining an alternating waveform voltage with a direct current bias voltage corresponding to a potential difference falling in the high-response region, and the potential difference produced by the vibration signal voltage has a maximum value and a minimum value both falling within the high-response region. 2. The dielectric elastomer vibration system according to claim 1 , wherein the potential difference produced by the bias voltage corresponds to a median value of the potential difference in the high-response region. 3. The dielectric elastomer vibration system according to claim 1 , wherein the power supply device includes a transformer having a booster function. 4. The dielectric elastomer vibration system according to claim 3 , comprising two dielectric elastomer vibrators with respective dielectric elastomer layers fixed in stretched state, wherein the transformer of the power supply device includes a primary winding and two secondary windings, the two secondary windings being wound in mutually opposite directions and configured to produce, from the waveform voltage, two waveform voltages of mutually opposite phases, and the power supply device applies two vibration signal voltages of mutually opposite phases separately across the respective pairs of electrode layers of the two dielectric elastomer vibrators. 5. The dielectric elastomer vibration system according to claim 4 , wherein the bias voltage is inputted to a node of the two secondary windings of the transformer. 6. The dielectric elastomer vibration system according to claim 1 , comprising two of the dielectric elastomer vibrators with the respective dielectric elastomer layers fixed to each other in stretched state, wherein the power supply device applies two vibration signal voltages having mutually opposite phases separately across the respective pairs of electrode layers of the two dielectric elastomer vibrators. 7. The dielectric elastomer vibration system according to claim 6 , wherein the power supply device includes a transformer that applies the bias voltage. 8. The dielectric elastomer vibration system according to claim 7 , wherein the transformer boosts the waveform voltage. 9. The dielectric elastomer vibration system according to claim 8 , wherein the transformer inverts the waveform voltage in phase. 10. The dielectric elastomer vibration system according to claim 6 , wherein the power supply device includes a transformer that inverts the waveform voltage in phase. 11. The dielectric elastomer vibration system according to claim 10 , wherein the transformer boosts the waveform voltage. 12. A power supply device for producing a potential difference across a pair of electrode layers sandwiching a dielectric elastomer layer included in a dielectric elastomer vibrator that exhibits a relationship between the potential difference across the pair of electrode layers and an amount of deformation induced by the potential difference, the relationship having: a high-response region in which a relatively large deformation is induced in response to change of the potential difference; a low-response region of lower-potential difference corresponding to a lower potential difference than the high-response region and in which a relatively small deformation is induced in response to change of the potential difference; and a low-response region of higher-potential difference corresponding to a higher potential difference than the high-response region and in which a relatively small deformation is induced in response to change of the potential difference or in which a break point of the dielectric elastomer layer is included, wherein the power supply device is configured to produce the potential difference by applying a vibration signal voltage across the pair of electrode layers, the vibration signal voltage being generated by combining a waveform voltage comprising an alternating current voltage with a bias voltage that is a direct current voltage corresponding to a potential difference falling in the high-response region. 13. The power supply device according to claim 12 , comprising a transformer having a booster function. 14. The power supply device according to claim 13 , wherein the transformer includes a primary winding and two secondary windings, the two secondary windings being wound in mutually opposite directions and inducing, from the one waveform voltage, two waveform voltages having mutually opposite phases, and the power supply device outputs two vibration signal voltages having mutually opposite phases separately to two of the dielectric elastomer vibrators that include the respective dielectric elastomer layers fixed to each other in stretched state. 15. The power supply device according to claim 14 , wherein the bias voltage is inputted to a node of the two secondary windings of the transformer. 16. The power supply device according to claim 12 , wherein the power supply device applies two vibration signal voltages having mutually opposite phases separately across two pairs of electrode layers of two of the dielectric elastomer vibrators that include the respective dielectric elastomer layers fixed to each other in stretched state. 17. The power supply device according to claim 16 , comprising a transformer that applies the bias voltage. 18. The power supply device according to claim 17 , wherein the transformer boosts the waveform voltage. 19. The power supply device according to claim 18 , wherein the transformer inverts the waveform voltage in phase. 20. The power supply device according to claim 16 , comprising a transformer that inverts the waveform voltage in phase. 21. The power supply device according to claim 20 , wherein the transformer boosts the waveform voltage.