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A method of acoustically fitting a hearing aid comprises providing a plurality of audible tones, each having a predetermined frequency through stereo headphones. The tones are provided at specific sound pressure in each ear. The patient changes the relative sound pressure in each ear until a perceiv

A method of acoustically fitting a hearing aid comprises providing a plurality of audible tones, each having a predetermined frequency through stereo headphones. The tones are provided at specific sound pressure in each ear. The patient changes the relative sound pressure in each ear until a perceived direction of source of the tone is in front of the patient. The amplification or attenuation requirements of a hearing aid are modified based on the difference in the sound pressures required for the left and right ears of the patient for perceived directional sameness for each frequency band-pass channel.

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1. A method of acoustically fitting a hearing aid, comprising; providing through stereo headphones simultaneously to both ears of a patient a plurality of individual audible tones, each audible tone having at least one predetermined frequency wherein each individual audible tone is provided at a pre

1. A method of acoustically fitting a hearing aid, comprising; providing through stereo headphones simultaneously to both ears of a patient a plurality of individual audible tones, each audible tone having at least one predetermined frequency wherein each individual audible tone is provided at a predetermined sound pressure to each ear;allowing the patient to change the sound pressure for each individual audible tone from the predetermined sound pressure in at least one ear to a second sound pressure in the at least one ear until the individual audible tone for a given predetermined sound pressure is perceived to be substantially binaurally balanced between both ears;recording the second sound pressure for each individual audible tone of the plurality of audible tones; andmodifying an amplification or attenuation requirement for each frequency band of a hearing aid so that sound pressure produced by the hearing aid in each frequency band is perceived by the patient to be substantially binaurally balanced between both ears. 2. The method of claim 1, further comprising changing the predetermined sound pressure in at least one ear of the patient by changing an azimuth of a head of the patient by facing a perceived sound source of each of the plurality of audible tones. 3. The method of claim 1, further comprising simultaneously changing the predetermined sound pressure in both ears of the patient by simultaneously increasing the sound pressure in one ear as the sound pressure in the other ear is decreased at substantially the same rate. 4. The method of claim 1, further comprising changing the predetermined sound pressure in at least one ear by altering the predetermined sound pressure through a user input. 5. The method of claim 2, further comprising automatically altering the predetermined sound pressure in at least one ear as the patient changes the azimuth of the head. 6. The method of claim 5, further comprising detecting changes in azimuth of the head by providing an azimuth detector coupled to the stereo headphones worn by the patient and using the detected change in azimuth to alter a relative sound pressure of each tone in each ear of the patient. 7. The method of claim 1, further comprising determining a loudness discomfort level of the patient for each frequency to be tested and programming a hearing aid to limit or attenuate sounds that exceed the loudness discomfort level. 8. The method of claim 7, further comprising detecting a minimum audible level of the patient for each frequency to be tested in order to determine a dynamic range of hearing of the patient and testing the patient at the plurality of tones within the dynamic range. 9. The method of claim 1, further comprising interpolating the difference in the sound pressures for frequencies that are between the plurality of tones and modifying the amplification or attenuation requirements of the hearing aid based on the interpolated difference. 10. The method of claim 1, further comprising testing the patient while wearing hearing aids and programming the hearing aids during the testing to coordinate binaurally balanced hearing so that balance sensed for all frequencies and gain compensation channels of the hearing aids results in perceived binaural balance between both ears for all frequency bands of the hearing aids. 11. The method of claim 8, further comprising retesting the patient at the plurality of tones while wearing hearing aids to obtain relative sound pressures required for perceived binaural balance for all frequencies and sound pressures within the dynamic range of hearing of the patient. 12. The method of claim 1, further comprising programming a plurality of families of coordinated hearing compensation curves into the hearing aid to provide perceived binaural balance at a variety of overall user adjusted sound pressure or volume levels. 13. The method of claim 12, further comprising programming the hearing aid to automatically switch between the plurality of families of coordinated hearing compensation curves in order to provide perceived binaural balance at a plurality of patient adjustable amplification levels based on patient user changes to the hearing aid volume. 14. The method of claim 1, further comprising programming a delay correction for individual frequency band-pass channels in the hearing aid in order to sharpen a binaural balance sensed by the patient. 15. The method of claim 1, further comprising coordinating sound amplification and timing corrections for different band-pass frequency channels in the hearing aid. 16. The method of claim 1, further comprising providing an autonomous interface for the patient by using a personal computer to allow the patient to establish initial comfortable hearing levels, loudness discomfort levels and threshold of hearing levels and to measure a perceived directional source relative to a predetermined directional source. 17. A method of acoustically fitting a hearing aid, comprising; providing a plurality of discrete audible tones through stereo headphones to a left and a right ear of a patient, each audible tone having a predetermined frequency and sound pressure and each predetermined frequency corresponding to one or more frequency bands of a hearing aid to be acoustically fitted;having the patient change the sound pressure in at least one ear until the sound pressure in both ears is perceived to be substantially binaurally balanced between both ears;determining a differential sound pressure for each tone between the left and right ears of the patient at the changed sound pressure;modifying a gain compensation of a hearing aid associated with each frequency band of the hearing aid based on the differential sound pressure to achieve substantially the same perceived binaural balance in both ears for all of the frequency bands of the hearing aid. 18. The method of claim 17, further comprising programming the gain compensation of the hearing aid to obtain perceived binaural balance for all frequencies and sound pressures within a dynamic range of hearing of the patient. 19. The method of claim 17, further comprising testing the patient with hearing aids and programming the hearing aids during the testing to coordinate binaurally balanced hearing so that balanced sensed for all frequencies and gain compensation channels of the hearing aids results in perceived balance. 20. The method of claim 17, further comprising programming a plurality of families of coordinated hearing compensation curves into the hearing aid to provide perceived binaural balance at a variety of overall user adjusted sound pressure or volume levels. 21. The method of claim 20, further comprising programming the hearing aid to automatically switch between the plurality of families of coordinated hearing compensation curves in order to provide perceived binaural balance at a plurality of patient adjustable amplification levels based on patient user changes to the hearing aid volume. 22. The method of claim 17, further comprising programming delay correction for individual frequency band-pass channels in the hearing aid in order to sharpen a directional response sensed by the patient wearing the hearing aid. 23. The method of claim 17, further comprising coordinating sound amplification and timing corrections for different band-pass frequency channels in the hearing aid. 24. The method of claim 17, further comprising providing an autonomous interface for the patient by using a personal computer to allow the patient to establish initial comfortable hearing levels, loudness discomfort levels and threshold of hearing levels and to measure the perceived directional source relative to a predetermined directional source. 25. The method of claim 17, further comprising providing audio encoding to program the hearing aids through the hearing aid receivers, by using one of Time Domain Audio Frequency Shift Keying, Audio Pulse Position Modulation, Audio Pulse Code Modulation or Audio Pulse Width Modulation during the hearing aid fitting process. 26. The method of claim 25, further comprising providing a hearing aid with a serial number, keying system or encryption technology so that programming is individualized for a particular hearing aid and cannot be performed by an unauthorized fitting system or individual. 27. The method of claim 17, further comprising providing a fiber optic waveguide to a hearing aid receiver during the fitting process, using the fiber optic waveguide to determine a spectral profile response in a specific custom hearing aid acoustical environment and using compensating information derived from the fiber optic waveguide measurements for a hearing aid receiver. 28. The method of claim 17, further comprising providing the plurality of tones in the form of at least one of pure tones, warbled tones, swept tones, band-pass noise, pulsed pure tones, pulsed warbled tones, pulsed swept tone, pulsed band-pass noise, chirped pure tones, chirped warbled tones, chirped swept tones, and chirped band-pass noise. 29. The method of claim 17, further comprising providing a programmable first-in-first-out digital storage device in the hearing aid for providing programmable delays that provide perceived binaural balance for each frequency band-pass channel of the hearing aid. 30. The method of claim 17, further comprising detecting an initial head azimuth of the patient and having the patient change the initial head azimuth to a second head azimuth until the patient is facing a perceived directional source of each tone, wherein the relative sound pressure of each tone in each ear is automatically changed as the patient changes head azimuth to create the audible sensation that the tone is emanating from a specific direction or becoming more binaurally balanced between both ears.