1. A method of controlling a personal acoustic device comprising:
performing a first test of whether at least a first earpiece of the personal acoustic device is in position adjacent an ear of a user while in a normal power mode;
performing a second test of whether at least the first earpiece is in position adjacent an ear of the user while in a deeper low power mode;
awaiting at least an interval of time between instances of performing the second test while in the deeper low power mode;
entering the normal power mode in response to an indication from the second test that at least the first earpiece is in position adjacent an ear of the user; and
entering the deeper low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the first test over a first period of time,
wherein:
the first earpiece comprises:
a casing defining a cavity structured to be acoustically coupled to an ear canal of an ear of a user when the first earpiece is in position adjacent an ear of the user;
an outer microphone disposed on the casing so as to be acoustically coupled to an environment external to the casing; and
an inner microphone positioned within the cavity; and
the first test comprises:
altering an outer signal output by the outer microphone by imposing a transfer function that alters a sound represented by the outer signal in a manner similar to the manner in which a sound propagating from the environment external to the casing to the cavity is modified either (i) at a time when the ear piece is in the operating state of being positioned in the vicinity of an ear, or (ii) at a time when the ear piece is in the operating state of not being positioned in the vicinity of an ear; and
comparing a signal level of an inner signal output by the inner microphone to a signal level of the altered outer signal to determine whether or not the cavity is acoustically coupled to an ear canal of an ear of the user as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
2. The method of claim 1, wherein:
the first earpiece further comprises an acoustic driver positioned to acoustically output sounds into the cavity; and
the second test comprises:
operating the acoustic driver to acoustically output a test sound; operating the inner microphone to detect the test sound; and
comparing the test sound as acoustically output by the acoustic driver to the test sound as detected by the inner microphone to determine whether or not the cavity is acoustically coupled to the environment external to the casing as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
3. The method of claim 1, wherein the personal acoustic device comprises a motion sensor, and the second test comprises monitoring the motion sensor to determine whether or not a portion of the personal acoustic device has been moved as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
4. The method of claim 1, further comprising performing a function while in the normal power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
5. The method of claim 4, further comprising ceasing to perform the function while in the deeper low power mode.
6. The method of claim 1, further comprising:
performing the first test while in a lighter low power mode;
entering the normal power mode in response to an indication from the first test that at least the first earpiece is in position adjacent an ear of the user; and
entering the lighter low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from an instance of performing the first test while in the normal power mode,
wherein in the lighter low power mode less power is consumed than in the normal power mode, and
wherein in the deeper low power mode less power is consumed than in the lighter low power mode.
7. The method of claim 6, further comprising altering the manner in which a function is performed during normal power mode upon entering the lighter low power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
8. The method of claim 6, further comprising powering off the personal acoustic device in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the second test over a second period of time.
9. A method of controlling a personal acoustic device comprising:
performing a first test of whether at least a first earpiece of the personal acoustic device is in position adjacent an ear of a user while in a normal power mode;
performing a second test of whether at least the first earpiece is in position adjacent an ear of the user while in a deeper low power mode;
awaiting at least an interval of time between instances of performing the second test while in the deeper low power mode;
entering the normal power mode in response to an indication from the second test that at least the first earpiece is in position adjacent an ear of the user; and
entering the deeper low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the first test over a first period of time,
wherein:
the first earpiece comprises:
a casing defining a cavity structured to be acoustically coupled to an ear canal of an ear of a user when the first earpiece is in position adjacent an ear of the user;
an outer microphone disposed on the casing so as to be acoustically coupled to an environment external to the casing; and
an inner microphone positioned within the cavity; and
the first test comprises:
altering an input signal output by the inner microphone by imposing a first transfer function that alters a sound represented by the inner signal in a manner that reverses a second transfer function to which a sound propagating from the environment external to the casing to the cavity is modified either (i) at a time when the ear piece is in the operating state of being positioned in the vicinity of an ear, or (ii) at a time when the ear piece is in the operating state of not being positioned in the vicinity of an ear; and
comparing a signal level of an outer signal output by the inner microphone to a signal level of the altered inner signal to determine whether or not the cavity is acoustically coupled to an ear canal of an ear of the user as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
10. The method of claim 9, wherein:
the first earpiece further comprises an acoustic driver positioned to acoustically output sounds into the cavity; and
the second test comprises:
operating the acoustic driver to acoustically output a test sound; operating the inner microphone to detect the test sound; and
comparing the test sound as acoustically output by the acoustic driver to the test sound as detected by the inner microphone to determine whether or not the cavity is acoustically coupled to the environment external to the casing as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
11. The method of claim 9, wherein the personal acoustic device comprises a motion sensor, and the second test comprises monitoring the motion sensor to determine whether or not a portion of the personal acoustic device has been moved as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
12. The method of claim 9, further comprising performing a function while in the normal power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
13. The method of claim 12, further comprising ceasing to perform the function while in the deeper low power mode.
14. The method of claim 9, further comprising:
performing the first test while in a lighter low power mode;
entering the normal power mode in response to an indication from the first test that at least the first earpiece is in position adjacent an ear of the user; and
entering the lighter low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from an instance of performing the first test while in the normal power mode,
wherein in the lighter low power mode less power is consumed than in the normal power mode, and
wherein in the deeper low power mode less power is consumed than in the lighter low power mode.
15. The method of claim 14, further comprising altering the manner in which a function is performed during normal power mode upon entering the lighter low power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
16. The method of claim 14, further comprising powering off the personal acoustic device in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the second test over a second period of time.
17. A method of controlling a personal acoustic device comprising:
performing a first test of whether at least a first earpiece of the personal acoustic device is in position adjacent an ear of a user while in a normal power mode;
performing a second test of whether at least the first earpiece is in position adjacent an ear of the user while in a deeper low power mode;
awaiting at least an interval of time between instances of performing the second test while in the deeper low power mode;
entering the normal power mode in response to an indication from the second test that at least the first earpiece is in position adjacent an ear of the user; and
entering the deeper low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the first test over a first period of time,
wherein:
the first earpiece comprises:
a casing defining a cavity structured to be acoustically coupled to an ear canal of an ear of a user when the first earpiece is in position adjacent an ear of the user;
an outer microphone disposed on the casing so as to be acoustically coupled to an environment external to the casing; and
an inner microphone positioned within the cavity; and
the first test comprises:
analyzing a difference between a first transfer function representing the manner in which a sound emanating from an acoustic noise source in the environment external to the casing changes as it propagates from the noise source to the inner microphone and a second transfer function representing the manner in which the sound changes as it propagates from the noise source to the outer microphone by deriving a third transfer function that is at least indicative of the difference between the first and second transfer functions.
18. The method of claim 17, wherein:
the personal acoustic device comprises an adaptive filter having a plurality of taps to compare the sounds detected in the environment external to the casing to the sounds detected within the cavity;
the first test comprises operating the adaptive filter using a first quantity of the taps and at a first sampling rate; and
the second test comprises operating the adaptive filter using a second quantity of the taps and at a second sampling rate.
19. The method of claim 18, wherein the second quantity of taps is less than the first quantity of taps.
20. The method of claim 18, wherein the second sampling rate is lower than the first sampling rate.
21. The method of claim 17, wherein:
the first earpiece further comprises an acoustic driver positioned to acoustically output sounds into the cavity; and
the second test comprises:
operating the acoustic driver to acoustically output a test sound; operating the inner microphone to detect the test sound; and
comparing the test sound as acoustically output by the acoustic driver to the test sound as detected by the inner microphone to determine whether or not the cavity is acoustically coupled to the environment external to the casing as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
22. The method of claim 17, wherein the personal acoustic device comprises a motion sensor, and the second test comprises monitoring the motion sensor to determine whether or not a portion of the personal acoustic device has been moved as an indication of whether at least the first earpiece is in position adjacent an ear of the user.
23. The method of claim 17, further comprising performing a function while in the normal power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
24. The method of claim 23, further comprising ceasing to perform the function while in the deeper low power mode.
25. The method of claim 17, further comprising:
performing the first test while in a lighter low power mode;
entering the normal power mode in response to an indication from the first test that at least the first earpiece is in position adjacent an ear of the user; and
entering the lighter low power mode in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from an instance of performing the first test while in the normal power mode,
wherein in the lighter low power mode less power is consumed than in the normal power mode, and
wherein in the deeper low power mode less power is consumed than in the lighter low power mode.
26. The method of claim 25, further comprising altering the manner in which a function is performed during normal power mode upon entering the lighter low power mode, the function being selected from a group consisting of: providing feedforward-based ANR, providing feedback-based ANR, acoustically outputting electronically provided audio into the cavity, signaling another device that the personal acoustic device is in position such that at least the first earpiece is adjacent an ear of the user, and transmitting audio detected by a communications microphone of the personal acoustic device to another device.
27. The method of claim 25, further comprising powering off the personal acoustic device in response to a lack of indication that at least the first earpiece is in position adjacent an ear of the user from plural instances of performing the second test over a second period of time.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. An impedance control device for tuning a device under test comprising
a first terminal port arranged for connecting a device under test,
a second terminal port arranged for connecting a termination,
a first signal path for a signal travelling between said first and said second terminal port,
first coupling means arranged for picking up a part of said signal travelling in said first signal path,
a second signal path arranged for receiving said part of said signal from said first coupling means, said second signal path comprising a correction circuit for adapting as a function of frequency the amplitude and phase of said received part of said signal,
second coupling means arranged for coupling back into said first signal path an adapted signal outputted by said correction circuit,
an attenuator and phase shifter for applying attenuation and phase shifting on said signals travelling between said first and said second terminal port.
2. The impedance control device as in claim 1, wherein said attenuator and said phase shifter are a part of said first signal path.
3. The impedance control device as in claim 1, wherein said attenuator and said phase shifter are positioned outside the signal path between the first and second coupling means.
4. The impedance control device as in claim 1, wherein said correction circuit comprises filtering means for adapting the amplitude and phase of said received part of said signal.
5. The impedance control device as in claim 4, wherein said correction circuit further comprises an amplification means.
6. The impedance control device as in claim 4, wherein said correction circuit comprises digital synthesis means for correcting the amplitude and phase response of said impedance control device as function of the frequency.
7. The impedance control device as in claim 6, wherein said digital synthesis means is implemented at least in part with a field programmable gate array.
8. The impedance control device as in claim 6, wherein said correction circuit comprises a processing unit for correcting the amplitude and phase response of the impedance control device as function of the frequency.
9. A vector network analyser comprising an impedance control device, the impedance control device comprising:
a first terminal port arranged for connecting a device under test,
a second terminal port arranged for connecting a termination,
a first signal path for a signal travelling between said first and said second terminal port,
first coupling means arranged for picking up a part of said signal travelling in said first signal path,
a second signal path arranged for receiving said part of said signal from said first coupling means, said second signal path comprising a correction circuit for adapting as a function of frequency the amplitude and phase of said received part of said signal,
second coupling means arranged for coupling back into said first signal path an adapted signal outputted by said correction circuit,
an attenuator and phase shifter for applying attenuation and phase shifting on said signals travelling between said first and said second terminal port.