Method and system for controlling voltage applied across a piezoelectric stack of a downhole acoustic transmitter

The invention claimed is: 1. An acoustic transmitter for transmitting an acoustic signal through a drill pipe, the transmitter comprising: (a) a piezoelectric stack; (b) a voltage boost circuitry for boosting a voltage from a voltage source; (c) a signal modulation circuitry electrically coupled to the voltage boost circuitry and to the piezoelectric stack, the signal modulation circuitry for applying a stack signal comprising voltage from the voltage source across the piezoelectric stack; (d) at least one of a temperature sensor and a compression sensor positioned to measure a temperature of the piezoelectric stack and a compressive stress applied to the piezoelectric stack, respectively; and (e) a control circuitry communicatively coupled to the voltage boost circuitry, signal modulation circuitry, and to the at least one of the temperature sensor and the compression sensor, the control circuitry configured to perform a method comprising: (i) monitoring at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack; (ii) comparing at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack to a temperature threshold and a stress threshold, respectively; and (iii) when the stack signal is an alternating voltage signal and when at least one of the temperature of the stack and the compressive stress applied to the stack respectively exceeds the temperature threshold and the stress threshold, modifying the stack signal such that a negative polarity portion of the stack signal has a maximum magnitude less than a magnitude of a negative polarity limit. 2. The transmitter of claim 1 , wherein the at least one of a temperature sensor and a compression sensor comprises at least the temperature sensor. 3. The transmitter of claim 1 , wherein the at least one of a temperature sensor and a compression sensor comprises at least the compression sensor. 4. The transmitter of claim 1 , wherein the at least one of a temperature sensor and a compression sensor comprises the temperature sensor and the compression sensor. 5. The transmitter of claim 1 wherein the voltage boost circuitry comprises a DC/DC voltage converter that sets a maximum voltage swing across the stack, and wherein modifying the stack signal comprises adjusting the DC/DC voltage converter such that the maximum voltage swing across the piezoelectric stack is reduced. 6. The transmitter of claim 1 wherein modifying the stack signal comprises adding a DC offset to the stack signal. 7. The transmitter of claim 6 wherein the voltage boost circuitry comprises a DC/DC voltage converter that sets a maximum voltage swing across the piezoelectric stack, and modifying the stack signal further comprises adjusting the DC/DC voltage converter to reduce the maximum voltage swing across the piezoelectric stack such that a positive polarity portion of the stack signal is unclipped. 8. The transmitter of claim 7 wherein the DC/DC voltage converter is adjusted such that the peak magnitude of the positive polarity portion of the stack signal after the DC offset is added to the stack signal is identical to a peak magnitude of the positive polarity portion of the signal before the DC offset is added to the stack signal. 9. The transmitter of claim 1 wherein modifying the stack signal comprises clipping the negative polarity portion of the stack signal. 10. A method for transmitting an acoustic signal through a drill pipe, the method comprising: (a) monitoring at least one of a temperature of a piezoelectric stack for generating the acoustic signal and a compressive stress applied to the piezoelectric stack; (b) comparing the at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack to a temperature threshold and a stress threshold, respectively; and when the stack signal is an alternating voltage signal and when at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack respectively exceeds the temperature threshold and the stress threshold, modifying the stack signal such that a negative polarity portion of the stack signal has a maximum magnitude less than a magnitude of a negative polarity limit. 11. The method of claim 10 wherein the maximum magnitude of the negative polarity portion of the stack signal is reduced in response to the temperature of the piezoelectric stack. 12. The method of claim 10 wherein the maximum magnitude of the negative polarity portion of the stack signal is reduced in response to the compressive stress applied to the piezoelectric stack. 13. The method of claim 10 wherein the maximum magnitude of the negative polarity portion of the stack signal is reduced in response to the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack. 14. The method of claim 10 wherein a maximum voltage swing across the stack signal is set by a DC/DC voltage converter, and wherein reducing the maximum magnitude of the negative polarity portion of the stack signal comprises adjusting the DC/DC voltage converter such that the voltage swing across the piezoelectric stack is reduced. 15. The method of claim 10 wherein reducing the maximum magnitude of the negative polarity portion of the stack signal comprises adding a DC offset to the stack signal. 16. The method of claim 15 wherein a maximum voltage swing across the stack signal is set by a DC/DC voltage converter, and wherein reducing the maximum magnitude of the negative polarity portion of the stack signal further comprises adjusting the DC/DC voltage converter to reduce the maximum voltage swing across the piezoelectric stack such that a positive polarity portion of the stack signal is unclipped. 17. The method of claim 16 wherein the DC/DC voltage converter is adjusted to reduce the maximum voltage swing across the piezoelectric stack such that the peak magnitude of the positive polarity portion of the stack signal after the DC offset is added to the stack signal is identical to a peak magnitude of the positive polarity portion of the signal before the DC offset is added to the stack signal. 18. The method of claim 10 wherein reducing the maximum magnitude of the negative polarity portion of the stack signal comprises clipping the negative polarity portion of the stack signal. 19. A non-transitory computer readable medium having encoded thereon computer program code that is executable by a processor and that, when executed by the processor, causes the processor to perform a method for transmitting an acoustic signal through a drill pipe, the method comprising: (a) monitoring at least one of a temperature of a piezoelectric stack for generating the acoustic signal and a compressive stress applied to the piezoelectric stack; (b) comparing the at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack to a temperature threshold and a stress threshold, respectively; and (c) when the stack signal is an alternating voltage signal and when at least one of the temperature of the piezoelectric stack and the compressive stress applied to the piezoelectric stack respectively exceeds the temperature threshold a n d the stress threshold, modifying the stack signal such that a negative polarity portion of the stack signal has a maximum magnitude less than a magnitude of a negative polarity limit.