Apparatus and method for controlling an oscillating device

What is claimed is: 1. A control system for use with an oscillating device comprising a response signal having a back electromotive force component, the control system comprising a driver adapted to provide a drive signal to the oscillating device; wherein the drive signal comprises an amplitude and a polarity; a sensor adapted to sense an electrical parameter of the response signal; and a controller coupled to the sensor and to the driver, the controller comprising a calculator adapted to determine a sign of curvature of a curved portion of the back electromotive force component of the response signal based on the electrical parameter; the controller being adapted to provide a control signal to adjust the amplitude of the drive signal to slow down the oscillating device, wherein upon reversing the polarity of the drive signal the curved portion gradually flattens before changing its sign of curvature and wherein the controller is adapted to withdraw the drive signal upon identifying the change in the sign of curvature of the curved portion of the back electromotive force component. 2. The control system as claimed in claim 1 , wherein identifying a change in the sign of curvature comprises identifying a change from a negative curvature to a positive curvature. 3. The control system as claimed in claim 1 , wherein identifying a change in the sign of curvature comprises identifying that the curved portion of the back electromotive force component of the response signal has a zero curvature. 4. The control system as claimed in claim 1 , wherein the sensor is adapted to sense the electrical parameter at a plurality of sampling times associated with a sampling pattern to obtain a first measurement, a second measurement and a third measurement; and wherein the calculator is adapted to compare the second and third measurements with the first measurement, and to determine the sign of curvature based on the comparison. 5. The control system as claimed in claim 4 , wherein the oscillating device comprises a resonance frequency, the control system comprising a frequency controller adapted to adjust the drive signal to drive the oscillating device at the resonance frequency. 6. The control system as claimed in claim 1 , wherein the driver is a current driver to provide a current signal, and wherein the sensor is a voltage sensor to sense a voltage across the oscillating device. 7. A method of controlling an oscillating device adapted to provide a response signal comprising a back electromotive force component, the method comprising providing a drive signal to drive the oscillating device, wherein the drive signal comprises an amplitude and a polarity; sensing an electrical parameter of the response signal; adjusting the amplitude of the drive signal to reverse its polarity and slow down the oscillating device; determining a sign of curvature of a curved portion of the back electromotive force component of the response signal based on the electrical parameter; wherein upon reversing the polarity of the drive signal the curved portion gradually flattens before changing its sign of curvature and withdrawing the drive signal upon identifying the change in the sign of curvature of the curved portion of the back electromotive force component. 8. The method as claimed in claim 7 , wherein identifying a change in the sign of curvature comprises identifying a change from a negative curvature to a positive curvature. 9. The method as claimed in claim 7 , wherein identifying a change in the sign of curvature comprises identifying that the curved portion of the back electromotive force component of the response signal has a zero curvature. 10. The method as claimed in claim 7 , wherein determining the sign of curvature comprises sensing the electrical parameter at a plurality of sampling times to obtain a first measurement, a second measurement and a third measurement; comparing the second and third measurements with the first measurement; and determining the sign of curvature based on the comparison. 11. The method as claimed in claim 7 , wherein the oscillating device comprises a resonance frequency, the method comprising adjusting the drive signal to drive the oscillating device at the resonance frequency. 12. The method as claimed in claim 7 , wherein the drive signal is a current signal and wherein the electrical parameter is a voltage. 13. An oscillating device system comprising an oscillating device comprising a response signal having a back electromotive force component, and a control system, the control system comprising a driver adapted to provide a drive signal to the oscillating device; wherein the drive signal comprises an amplitude and a polarity; a sensor adapted to sense an electrical parameter of the response signal; and a controller coupled to the sensor and to the driver, the controller comprising a calculator adapted to determine a sign of curvature of a curved portion of the back electromotive force component of the response signal based on the electrical parameter; the controller being adapted to provide a control signal to adjust the amplitude of the drive signal to reverse its polarity and slow down the oscillating device, wherein upon reversing the polarity of the drive signal the curved portion gradually flattens before changing its sign of curvature; the controller being adapted to withdraw the drive signal upon identifying the change in the sign of curvature of the curved portion of the back electromotive force component. 14. A mobile device comprising an oscillating device system; the oscillating device system comprising an oscillating device comprising a response signal having a back electromotive force component, and a control system, the control system comprising a driver adapted to provide a drive signal to the oscillating device; wherein the drive signal comprises an amplitude and a polarity; a sensor adapted to sense an electrical parameter of the response signal; and a controller coupled to the sensor and to the driver, the controller comprising a calculator adapted to determine a sign of curvature of a portion of the back electromotive force component of the response signal based on the electrical parameter; the controller being adapted to provide a control signal to adjust the amplitude of the drive signal to reverse its polarity and slow down the oscillating device, wherein upon reversing the polarity of the drive signal the curved portion gradually flattens before changing its sign of curvature; the controller being adapted to withdraw the drive signal upon identifying the change in the sign of curvature of the curved portion of the back electromotive force component. 15. A controller for use with a driver for providing a drive signal to an oscillating device, and a sensor for sensing an electrical parameter of a response signal of the oscillating device, wherein the drive signal comprises an amplitude and polarity, and wherein the response signal comprises a back electromotive force component; the controller comprising a calculator adapted to determine a sign of curvature of a curved portion of the back electromotive force component of the response signal based on the electrical parameter; the controller being adapted to provide a control signal to adjust the amplitude of the drive signal to reverse its polarity and slow down the oscillating device, wherein upon reversing the polarity of the drive signal the curved portion gradually flattens before changing its sign of curvature, the controller being adapted to withdraw the drive signal upon identifying the change in the sign of