2-wire ultrasonic magnetostrictive driver

What is claimed: 1. A magnetostrictive ultrasonic dental scaler, comprising: a handpiece having an ultrasonic transducer that vibrates at an optimal operational frequency in response to an electromagnetic field applied thereto and an excitation coil that generates said electromagnetic field in response to an applied electrical signal; a resonant circuit that generates said electrical signal; and a control circuit comprising a microprocessor and a full bridge synchronous class D amplifier that generates a drive signal for said resonant circuit, said control circuit receiving sensed current and voltage outputs of said ultrasonic transducer as a result of changing impedance at said ultrasonic transducer, said microprocessor quadrature sampling said sensed current and voltage outputs at the same sampling rate as used for the generation of said electrical signal, generating a pulse width modulated signal from said quadrature sampled sensed current and voltage that represents a pulse train approximation of a sine wave of said drive signal, and said pulse train being applied to said full bridge synchronous class D amplifier to generate said drive signal, whereby changing pulse widths of the pulse train changes an amplitude of said drive signal. 2. A magnetostrictive ultrasonic dental scaler as in claim 1 , wherein said resonant circuit comprises an LC resonant circuit that when coupled to the ultrasonic transducer produces a high Q resonant circuit in line with a physical resonance of the ultrasonic transducer. 3. A magnetostrictive ultrasonic dental scaler as in claim 1 , further comprising an oscillator that generates a NCO frequency that is a multiple of an optimal operational frequency of said resonant circuit, said full bridge synchronous class D amplifier being driven at said NCO frequency. 4. A magnetostrictive ultrasonic dental scaler as in claim 3 , wherein said NCO frequency is n times said optimal operational frequency whereby a cycle of said optimal operational frequency is divided into n samples each having a period of duration T 1 corresponding to a 360°/n phase of said optimal operational frequency, said NCO frequency synchronizing a rate of the quadrature sampling with the optimal operational frequency of said ultrasonic transducer. 5. A magnetostrictive ultrasonic dental scaler as in claim 4 , further comprising lookup tables that store respective values representing pulse durations of said pulse trains in each of the n periods of duration T 1 for each side of said full bridge synchronous class D amplifier, wherein each lookup table stores respective pulses that are 180° out of phase with corresponding pulses sampled during the same sampling period of the other lookup table. 6. A magnetostrictive ultrasonic dental scaler as in claim 5 , wherein corresponding pulses in the respective lookup tables are offset by a pulse width value that is adjustable so as to induce a bias current to enable dynamic adjustment of a bias current output by said resonant circuit. 7. A magnetostrictive ultrasonic dental scaler as in claim 5 , further comprising an x bit counter, where 2 x =n, that is clocked by said oscillator at said NCO frequency, a value of said x bit counter being used as an address for said lookup tables for each T 1 period. 8. A magnetostrictive ultrasonic dental scaler as in claim 7 , wherein said oscillator comprises a numerically controlled oscillator implemented within said microprocessor. 9. A magnetostrictive ultrasonic dental scaler as in claim 8 , wherein said numerically controlled oscillator comprises an m-bit phase accumulator register that on each clock cycle of said NCO frequency is incremented by a frequency control word (FCW) whereby a current angular position of the numerically controlled oscillator is stored for a phase calculated as phase=2*π*(FCW/2m). 10. A magnetostrictive ultrasonic dental scaler as in claim 9 , wherein a most significant bit of the numerically controlled oscillator clocks said x bit counter. 11. A magnetostrictive ultrasonic dental scaler as in claim 8 , wherein the optimal operational frequency of the ultrasonic transducer is determined by measuring an amplitude relationship between current and voltage outputs of said resonant circuit, wherein said amplitude relationship between current and voltage outputs of said resonant circuit are sampled as the same sampling rate as used at an output of said numerically controlled oscillator at specific values of said x-bit counter. 12. A magnetostrictive ultrasonic dental scaler as in claim 11 , wherein voltage and current samples are taken 0, 90, 180, and 270 degrees phase shifted from the drive signal of the resonant circuit and said microprocessor calculates from the samples the amplitude relationship between current and voltage outputs of the resonant circuit as: | V|= 0.5*sqrt(( V 0 - V 180 ) 2 +( V 90 - V 270 ) 2 ) | I|= 0.5*sqrt(( I 0 - I 180 ) 2 +( I 90 - I 270 ) 2 ). 13. A magnetostrictive ultrasonic dental scaler as in claim 12 , further comprising determining said impedance Z of said ultrasonic transducer as Z=|V|/|I|, where V is the output voltage of said resonant circuit and I is the input current of said ultrasonic transducer and said optimal operational frequency is a frequency at a central location on a downward slope of impedance Z versus frequency on a curve of impedance Z versus frequency. 14. A magnetostrictive ultrasonic dental scaler as in claim 1 , wherein said microprocessor controls said resonant circuit to generate said electrical signal to excite said ultrasonic transducer at a variety of frequencies in a frequency range, calculates the impedance Z of said ultrasonic transducer at each of said variety of frequencies, and determines said optimal operational frequency as a frequency in said frequency range at which the impedance has a minimum value on an impedance versus frequency curve. 15. A magnetostrictive ultrasonic dental scaler as in claim 1 , further comprising a Hall effect current sensor that senses an output current of said resonant circuit. 16. A magnetostrictive ultrasonic dental scaler as in claim 1 , wherein said sensed current and voltage outputs of said ultrasonic transducer are provided via a feedback wire from a feedback loop including said excitation coil. 17. A magnetostrictive ultrasonic dental scaler as in claim 1 , further comprising a display screen including a touch panel display that controls power applied to the ultrasonic transducer so as to change the output amplitude of the ultrasonic transducer in response to touch panel inputs to the touch panel display. 18. A magnetostrictive ultrasonic dental scaler as in claim 17 , further comprising an asynchronous data line that transmits and receives data between the display and said microprocessor whereby when an event is changed on the display information relating to the change is transmitted on the asynchronous data line to the microprocessor, which interprets the display information and changes the power applied to the ultrasonic transducer and transmits update information back to the display to update a status of the display. 19. A magnetostrictive ultrasonic dental scaler as in claim 1 , further comprising a potentiometer controlling power and individual switches controlling functions whereby changes to the potentiometer and/or individual switches provide a direct analog signal into the microprocessor and the microprocessor interprets any changes in the analog signal to accordingly control power applied to the ultrasonic transducer.