Claims
- 1. A wide frequency band microphone including
a plurality of evacuated micromachined capacitive cells, each cell including a membrane supported above a common conductive electrode by an insulating support and each membrane supporting a conductive electrode for movement therewith whereby each electrode forms with the common conductive electrode a capacitor whose capacitance varies with movement of the membrane relative to the common electrode, and conductive lines interconnecting conductive electrodes of adjacent cells.
- 2. A wide frequency band microphone as in claim 1 in which the cells are arranged in a two-dimensional matrix.
- 3. A wide frequency band microphone as in claim 1 or 2 in which the membranes are rectangular.
- 4. A wide frequency band microphone as in claim 1 in which said conductive lines interconnecting conductive electrodes of adjacent cells connect the conductive electrodes in series to thereby form a transmission line in which the conductive lines are inductors connected to the capacitors formed by said conductive electrodes and common electrode.
- 5. The method of cleaning the surface of the microphone of claim 1 which comprises applying an alternating voltage between the conductive line and conductive electrode and the common conductive electrode to cause the membranes to vibrate.
- 6. A wide frequency band microphone including:
a plurality of micromachined capacitive microphone cells arranged in a two-dimensional array, each cell including a membrane supported above a common conductive electrode by an insulating support and each membrane supporting a conductive electrode for movement therewith whereby each electrode forms with the common conductive electrode a capacitor whose capacitance varies with movement of the membrane relative to the common electrode, a conductive line interconnecting all conductive electrodes of cells in said array in series, whereby the inductance of said conductive line and the capacitance of said capacitors form a high frequency transmission line whose electrical length changes responsive to movement of said membrane.
- 7. A wide frequency band microphone as in claim 6 in which the cells are arranged in a two-dimensional matrix.
- 8. A wide frequency band microphone as in claim 6 or 7 in which the membranes are rectangular.
- 9. The method of operating a micromachined capacitive microphone of the type which includes a plurality of micromachined capacitive cells arranged in a two-dimensional array over a broad frequency band, said cells each comprising a membrane supported by an insulating support above a common conductive electrode with a conductive electrode on each of said membranes to form with said spaced common electrode a capacitor,
said method comprising connecting said cells in series with conductive connecting lines whereby said connecting lines and said capacitors form a high frequency transmission line whose length varies with changes in the capacitance of said cells and inductance of said lines, applying a high frequency RF voltage to said high frequency transmission line, and determining the change in electrical length of the line responsive to a received acoustic signal to provide an output signal representative of the acoustic signal.
- 10. The method of claim 9 including the additional step of employing two parallel rows of connected microphones to form parallel transmission lines, applying an RF voltage to the input of one of said rows and using it as a reference for determining from the difference in RF length of the output of said two lines the direction of the incoming acoustic wave.
- 11. A method as in claim 10 including an additional pair of parallel lines disposed at an angle to the first pair to determine the direction of the incoming acoustic signal.
- 12. A wide frequency band microphone including:
a plurality of evacuated, micromachined capacitive cells, each cell including a membrane supported above a common conductive electrode by an insulating support and each membrane supporting a conductive electrode for movement therewith whereby each electrode forms with the common conductive electrode a capacitor whose capacitance varies with movement of the membrane relative to the common electrode, conductive lines independently interconnecting conductive electrodes of two parallel rows of adjacent cells in series whereby the inductance of said conductive lines and the capacitance of said capacitors form two parallel high frequency transmission lines whose electrical length changes responsive to movement of said membrane in response to sound, and means connected to said two transmission lines for determining from the change in electrical length between the two lines the direction of the source of sound received by the microphone.
- 13. A wide frequency band microphone as in claim 12 which includes at least two sets of said two parallel lines of cells disposed at an angle with respect to each other.
- 14. A wide frequency band microphone as in claim 13 in which the angle is a right angle.
- 15. A wide frequency band microphone as in claim 12 including means connected to one of said transmission lines for determining from the change in electrical length of said line the intensity of the sound as well as its direction.
- 16. The method of locating a microphone formed in accordance with claim 1 which comprises:
exciting the microphone by applying an AC voltage between the conductive electrodes and the common electrode to cause the membranes to vibrate and emit sound, receiving the sound waves at two spaced locations, and determining the position of said microphone by detecting the difference in arrival time of the acoustic signal at the two spaced locations to thereby triangulate the position of the microphone.
- 17. The method of operating a micromachined capacitive microphone of the type which includes a plurality of micromachined capacitive cells arranged in a two-dimensional array over a broad frequency band, said cells each comprising a membrane supported by an insulating support above a common conductive electrode with a conductive electrode on each of said membranes to form with said spaced common electrode a capacitor,
said method comprising connecting said cells in series with conductive connecting lines whereby said connecting lines and said capacitors form a high frequency transmission line whose length varies with changes in the capacitance of said cells and inductance of said lines, applying a DC voltage between the conductive electrodes of said cells and the common conductive electrode, applying a high frequency RF voltage to said high frequency transmission line, and determining the change in electrical length of the line responsive to a received acoustic signal to provide an output signal representative of the acoustic signal.
- 18. The method of claim 17 including the additional step of employing two parallel rows of connected microphones to form parallel transmission lines, applying a reference RF voltage to the input of one of said rows and determining from the difference in RF length of the output of said two lines the direction of the incoming acoustic wave.
- 19. A method as in claim 18 including an additional pair of parallel lines disposed at an angle to the first pair to determine the direction of the incoming acoustic signal.
RELATED APPLICATIONS
[0001] This application claims priority to provisional application Ser. No. 60/172,390 filed Dec. 17, 1999.
Provisional Applications (1)
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Number |
Date |
Country |
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60172390 |
Dec 1999 |
US |