Acoustic dipole piston transmitter

What is claimed is: 1. An acoustic dipole transmitter, comprising: a piston disposed in the dipole transmitter, at least a portion of the piston being made from a magnetic material; a first coil disposed in the dipole transmitter adjacent to the piston, the first coil moving the piston in a first direction when energized; a second coil disposed in the dipole transmitter adjacent to the piston, the second coil moving the piston in a second direction opposite the first direction when energized; and a feedback winding disposed with at least one of the first and second coils that generates a signal indicative of the amount of magnetic flux in at least one of the first and second coils. 2. An acoustic dipole transmitter according to claim 1 , further comprising a capacitance sensor disposed with at least one of the first and second coils that generates a signal indicative of the displacement of the piston. 3. An acoustic dipole transmitter according to claim 1 , further comprising: a capacitance sensor disposed with at least one of the first and second coils that generates a signal indicative of the displacement of the piston. 4. An acoustic dipole transmitter according to claim 1 , wherein no permanent magnets drive the piston. 5. An acoustic dipole transmitter according to claim 1 , wherein the piston includes a housing cylinder comprising a cobalt-iron alloy and the first and second coils are housed in an assembly comprising a silicon-iron alloy. 6. An acoustic dipole transmitter according to claim 1 , wherein the piston is arranged between the first and second coils by a centering spring. 7. An acoustic dipole transmitter according to claim 1 , wherein the piston is substantially disk shaped with convex first and second opposing surfaces. 8. An acoustic dipole transmitter according to claim 1 , further comprising a control system for energizing the first and second coils, the control system comprising: a first input that amplifies the signal indicative of the amount of magnetic flux in at least one of the first and second coils; a second input that amplifies the signal indicative of the displacement of the piston; a processor connected to the first and second inputs and configured to generate output waveforms for driving the first and second coils by performing one or more of the following using the amplified signals from the first and second inputs: determining a position of the piston relative to the first and second coils; determining an initial waveform shape; compensating for discontinuities caused by reversing the direction of piston travel; compensating for a non-linearity resulting from a change in drive current and piston acceleration; and first and second outputs that energize the first and second coils with output signals reflecting the output waveforms generated by the processor. 9. A downhole tool for taking acoustic measurements in a wellbore, the downhole tool comprising: a tool housing; and an acoustic dipole transmitter disposed at least partially within the tool housing and having a piston including a soft magnetic material, the piston being mounted on a centering spring between a first coil and a second coil, the first coil moving the piston in a first direction when energized and the second coil moving the piston in a second direction opposite the first direction when energized and a feedback winding disposed with at least one of the first and second coils that generates a signal indicative of the amount of magnetic flux in at least one of the first and second coils. 10. A downhole tool according to claim 9 , wherein the acoustic dipole transmitter further comprises a capacitance sensor disposed with at least one of the first or second coils that provides a signal indicating a position of the piston relative to the first and second coils. 11. A downhole tool according to claim 9 , wherein the acoustic dipole transmitter further comprises: a capacitance sensor disposed with at least one of the first or second coils that provides a signal indicative of a position of the piston relative to the first and second coils. 12. A downhole tool according to claim 9 , wherein the tool housing includes an acoustic dampening material. 13. A downhole tool according to claim 9 , wherein the acoustic dipole transmitter further comprises a control system for energizing the first and second coils, the control system comprising: a first input that amplifies the signal indicative of the amount of magnetic flux in at least one of the first and second coils; a second input that amplifies the signal indicative of the position of the piston relative to the first and second coils; a processor connected to the first and second inputs and configured to generate output waveforms for driving the first and second coils by performing one or more of the following using the amplified signals from the first and second inputs: determining a position of the piston relative to the first and second coils; determining an initial waveform shape; compensating for discontinuities caused by reversing the direction of piston travel; compensating for a non-linearity resulting from a change in drive current and piston acceleration; and first and second outputs that energize the first and second coils with output signals reflecting the output waveforms generated by the processor. 14. A method for transmitting acoustic signals into a subterranean formation of an oil and gas well comprising: positioning an acoustic dipole transmitter in a wellbore of the oil and gas well, the acoustic dipole transmitter including a piston made at least partially from a magnetic material; energizing a first coil in the acoustic dipole transmitter to move the piston in a first direction; de-energizing the first coil; energizing a second coil in the acoustic dipole transmitter to move the piston in a second direction opposite the first direction; de-energizing the second coil; and generating a signal indicative of the amount of magnetic flux in at least one of the first and second coils. 15. The method according to claim 14 , further comprising multiplying a sine wave signal and an input signal to generate an output waveform and using the output waveform to energize the first and second coils. 16. The method according to claim 15 , further comprising splitting the output waveform into a positive waveform and an inverted negative waveform and using the positive waveform to energize the first coil and the inverted negative waveform to energize the second coil. 17. The method according to claim 14 , further comprising compensating the split waveforms for non-linearities resulting from a change in coil current and/or piston acceleration. 18. The method according to claim 14 , wherein the first coil is de-energized before energizing the second coil, and the second coil is de-energized before energizing the first coil.