KR20210045375A - Mobile hearing aid comprising user adaptive digital filter - Google Patents

Abstract

The present invention relates to a mobile hearing aid including a user-adaptive digital filter, which includes a user's mobile device and a wired or wireless earphone or a wired/wireless bone conduction transducer connected to the mobile device. According to the present invention, the mobile hearing aid comprises: an equal-loudness curve data memory storing waveform data and equal-loudness curve data for each audible frequency; a DSP module receiving microphone input data through an audio interface, correcting the received data, and removing noise; and a short-distance communication unit providing audio data to a wireless earphone or a wireless bone conduction transducer through Bluetooth or NFC. Accordingly, the mobile hearing aid selects a processing band as a selective bandpass filter for an audible frequency band, performs gain compensation for each hearing loss band as a sub-band pass filter, and selectively operates on input signals above a noise level.

Description

Mobile hearing aid comprising user adaptive digital filter

The present invention relates to a mobile device of a user and a mobile hearing aid having a user adaptive digital filter including a wired earphone or a wireless earphone connected to the mobile device, or a wired/wireless bone conduction transducer.

As a background technology for the present invention, there is a sound reinforcement technology for mobile phones and other products for generating personalizing audio for users of Korean Patent Laid-Open Publication No. 10-2019-0027820 A shown in FIG. 1. This technology relates to the field of sound reinforcement for mobile phones and other products that provide audio to users, in particular personal hearing profile, environmental factors such as noise-induced hearing loss and personal It features a technology that enhances sound based on personal preference.

As another background technology for the present invention, there is a personal communication device having a hearing aid of Korean Patent Laid-Open Publication No. 10-2013-0133790 A shown in FIG. 2 and a method technology for providing the same. The technology includes an input for receiving an audio signal, a programmable processing means and an output for outputting a processed signal. Programmable processing means is arranged to perform a filtering operation on the digital version of the speech signal in a first signal path based on parameter setting, and to determine the parameter setting based on user preference, audible information, and information on the listening situation. Arranged to provide a control logic for, wherein the personal communication device is obtained and used through the speech environment analysis of the received speech signal and/or through the sensing means of the personal communication device, so that the programmable processing means is It is operable as a hearing loss compensation module arranged to output a compensated signal. Programmable processing means further has a second signal path parallel to the first signal path, the second signal path receiving the audio signal and the digital version of the parameter setting, the parameter setting and the audio signal And a module for calculating a transfer function arranged to determine filter coefficients of the filtering means based on the digital version of.

As another background technology for the present invention, there is a hearing aid capable of applying the environmental profile of Korean Patent Publication No. 10-1551665 B1 shown in FIG. 3, and a system and method technology for applying an environmental profile using the same. This technology includes a microphone into which external sound is input, a signal processing unit that processes signals input from the microphone, a receiver that reproduces signals processed by the signal processing unit, a memory that stores various information necessary for the operation of a hearing aid, and is input from the microphone. A hearing aid including an environmental profile optimization unit that analyzes a signal to search for and apply an environmental profile suitable for surrounding conditions, the hearing aid; Including a server capable of communicating with a hearing aid and storing an environmental profile according to the surrounding environment; by automatically applying an environmental profile suitable for the surrounding situation, the optimal sound can be provided through the hearing aid, and the environmental profile is extended. It is characterized by a system and method for applying an environmental profile to facilitate this so that more accurate and detailed sound can be provided.

KR 10-2004-0053134 A KR 10-2013-0133790 A KR 10-1551665 B1 KR 10-1551666 B1 KR 10-1623562 B1 KR 10-2019-0027820 A

ISO 226:2003 Acoustics-Normal equal-loudness level contours, 2003-08

The present invention provides a user adaptive digital filter that selects a processing band as a selection band pass filter for an audible frequency band, compensates for each hearing loss band as a sub-band pass filter, and selectively operates on an input signal having a noise level or higher. It is a problem to be solved to provide a equipped mobile hearing aid.

The present invention provides a mobile device of a user and a mobile hearing aid having a user adaptive digital filter equipped with a wired earphone or wireless earphone connected to the mobile device, or a wired/wireless bone conduction transducer, in which waveform data and isometric curves for each audible frequency are provided. An isometric curve data memory that stores data, a DSP module that receives microphone input data through an audio interface, corrects it, and removes noise, and a short-range communication unit that provides audio data such as Bluetooth or NFC to a wireless earphone or a wireless bone conduction converter. A mobile hearing aid equipped with a user adaptive digital filter, characterized in that consisting of, is provided as a means of solving the problem.

According to the mobile hearing aid equipped with a user adaptive digital filter of the present invention, a processing band is selected as a selection band pass filter for an audible frequency band, and gain compensation for each hearing loss band is performed as a sub-band pass filter, and an input signal having a noise level or higher. It provides a technical effect that operates selectively for.

FIG. 1 is a background art of the present invention, a configuration of sound reinforcement technology for mobile phones and other products that generate personalized audio for users
2 is another background technology for the present invention, a personal communication device having a hearing aid, and a method for providing the same
3 is another background technology for the present invention, a hearing aid capable of applying an environmental profile, and a system and method for applying an environmental profile using the same
Figure 4 is ISO 226:2003 normal equal-loudness level contours
Fig. 5 is a function of 40[phone] in the iso-auditory curve of ISO 226:2003
Figure 6 is a basic configuration of the present invention
7 is a diagram illustrating the configuration and operation relationship of the DSP module of the present invention.
Figure 8 is a connection relationship between a user's mobile device for correcting the auditory sensation of the present invention
Figure 9 is a configuration for calculating the filter coefficient by the mobile processor of the present invention
Fig. 10 is an operation configuration and operation relationship of a mobile hearing aid equipped with a user adaptive digital filter of the present invention.

The following content merely exemplifies the principles of the present invention. Accordingly, a person of ordinary skill in the field to which this technology belongs can implement the principles of the present invention and invent various devices included in the concept and scope of the present invention, although not clearly described or illustrated in the present specification. In addition, all conditional terms and examples listed in this specification are, in principle, clearly intended only for the purpose of understanding the concept of the present invention, and should be understood as not limiting to the embodiments and states specifically listed as described above. do. In addition, it is to be understood that all detailed descriptions listing specific embodiments as well as principles, aspects and embodiments of the present invention are intended to include structural and functional equivalents of these matters.

The above objects, features, and advantages will become more apparent through the following detailed description in connection with the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 shows normal equal-loudness level contours revised to ISO 226:2003 by the International Standard Organization (ISO). The iso-auditory curve in the drawing is the same size at different frequencies for the amount of sound detected at 1KHz when a sound at a constant sound pressure level (y-axis) is provided to the human hearing for each frequency (x-axis) of the audible frequency band. Shows the sound pressure level detected by. At this time, each curve is expressed in units of [phone] as a value of the sound pressure level at 1KHz, and the international standard is provided along with an approximation formula for calculating the value of each isosensory curve.

FIG. 5 shows a function of 40 [phone] showing sound pressure levels of different frequencies sensed at the same magnitude as the sound of 1 KHz sound pressure level 40 [dB] detected by hearing in the iso-hearing sensation curve of ISO 226:2003. . The table at the bottom of the drawing shows the sound pressure level calculated for each octave band according to the ISO 226:2003 iso-hearing curve of the 40 [phone] function.

For hearing with hearing loss with a sound of 40[dB] at a sound pressure level of 1KHz as the minimum detection value, a sound at a sound pressure level of about 43[dB] at 500Hz and a sound pressure level of 36[dB] at 4000Hz should be detected as the minimum value. However, in the case of hearing loss, it is distributed as sound with a higher sound pressure level than the ISO 226:2003 iso-hearing sensation curve for the minimum detection value at 1 kHz for each audible band frequency. Accordingly, in the present invention,

-A sine wave of 1KHz is provided to the user's hearing, adjusted to the smallest detectable size, and then input.

-Using a function of the ISO 226:2003 iso-auditory curve corresponding to the input minimum size, the sound pressure level of different audible frequencies is converted and provided,

-A mobile hearing aid equipped with a user-adaptive digital filter that corrects the user's hearing by setting the coefficient of the digital filter by setting the difference between the sound pressure level of different audible frequencies and the minimum audible gain input from the user as the compensation gain in the corresponding frequency band. to provide. The audible frequency band of the present invention may be set to an octave band or a 1/3 octave band over a band of 20Hz to 20KHz.

The present invention is a user-adaptive method that performs auditory correction and removes unnecessary noise by converting the sound pressure level at different frequencies according to the iso-hearing curve of ISO 226:2003 by receiving pressure from the user at the minimum detected sound pressure level at 1KHz. It provides a mobile hearing aid equipped with a digital filter.

Figure 6 shows the basic configuration of the present invention. The mobile hearing aid provided with a user adaptive digital filter of the present invention has a mobile device 100 of the user and a wired earphone or wireless earphone connected to the mobile device 100, or a wired/wireless bone conduction transducer as a basic configuration.

The mobile device 100 of the present invention includes a mobile processor 102 that performs overall control of the mobile device 100; and a mobile communication unit 104; An isometric curve data memory 105 for storing waveform data and isometric curve data for each audible frequency; An audio interface 108 for A/D conversion of microphone input, receiving speaker and earphone output data, D/A conversion, and outputting; A DSP module 120 that receives microphone input data through the audio interface 108, corrects the hearing sense, and removes noise; A minimum sensing volume input unit 110 that reads waveform data for each audible frequency from the isosensory curve data memory 105 by the mobile processor 102 and outputs it through the audio interface 108 to receive the minimum audible gain from the user; It consists of; a short-range communication unit 112 for providing audio data such as Bluetooth or NFC to a wireless earphone or a wireless bone conduction transducer.

FIG. 7 shows the configuration and operation relationship of the DSP module 120 in a mobile hearing aid equipped with a user adaptive digital filter of the present invention. The DSP module 120 of the present invention includes an input frame memory 124 for storing A/D conversion data of sound input to a microphone through the audio interface 108; And, in the data of the input frame memory 124 A selection band pass filter 126 for selectively passing a band of the signal to be processed for the target signal; A sub-band pass filter (128) which adjusts and passes a gain for each octave band or 1/3 octave band with respect to the band of the signal to be processed; An output frame memory (134) that stores the filtered signal data of the sub-band pass filter (128) and provides it to the audio interface (108) or the short-range communication unit (112) to transmit sound to a user; It consists of

The center frequencies of the selected band pass filter 126 and the sub-band pass filter 128 and the gain of the pass signal are adjusted by filter coefficients, and the filter coefficients are calculated from the mobile processor 102 to obtain a filter coefficient storage unit 122 ), the characteristics of the selection band pass filter 126 and the sub band pass filter 128 are determined.

The filtered signal data of the sub-band pass filter 128 is supplied to the band signal integrating unit 130 to calculate the size of the filtered signal data, and the output of the band signal integrating unit 130 determines a threshold level. Whether the size of the signal data supplied to the unit 132 and calculated by the sub-band pass filter 128 is equal to or greater than a threshold level is provided to the mobile processor 102 and is determined. The mobile processor 102 determines that the data in the output frame memory 134 is valid when the size of the signal data calculated by the sub-band pass filter 128 is equal to or greater than the threshold level, and the audio interface 108 or the short-range communication unit ( 112), and if the size of the signal data calculated by the sub-band pass filter 128 is less than or equal to the threshold level, it is determined as noise and all data in the output frame memory 134 is deleted, and the audio interface 108 or The sound through the short-range communication unit 112 is processed as silence.

Therefore, the DSP module 120 selects a processing band with the selection band pass filter 126 for the audible frequency band, and the gain compensation for each hearing loss band is performed using the sub-band pass filter 128, and the input signal having a noise level or higher is compensated for. It has a feature that operates selectively for.

FIG. 8 is a diagram illustrating a connection relationship between a user's mobile device 100 for correcting hearing in a mobile hearing aid equipped with a user adaptive digital filter of the present invention.

First, the waveform data of 1 KHz is read from the isometric curve data memory by the mobile processor 102, stored in the output frame memory 134, and transmitted to the user's hearing through the audio interface 108 or the short-range communication unit 112. Subsequently, the user of the mobile device 100 inputs a minimum detection level of 1 KHz through the minimum detection volume input unit 110 and provides the input to the mobile processor 102. The mobile processor 102 retrieves and reads the isometric curve data corresponding to the minimum detection level from the isometric curve data memory, and converts the gain on the isometric curve with respect to the frequencies of other bands of the corresponding isometric curve data to obtain waveform data for each band. It is read, stored in the output frame memory 134, and transmitted to the user's hearing through the audio interface 108 or the short-range communication unit 112. Subsequently, the user of the mobile device 100 inputs the minimum detection level for each frequency through the minimum detection volume input unit 110 and provides the input to the mobile processor 102. The mobile processor 102 stores a difference value between the minimum sensing level for each frequency and a gain on an isosensory curve as an auditory correction gain.

The mobile processor 102 performing the above process for the selected audible frequency band, based on the stored auditory correction gain, the filter coefficients of the selection band pass filter 126 and the sub band pass filter 128 of the DSP module 120 Is calculated and stored in the filter coefficient storage unit 122.

Accordingly, through the above configuration and operation, the user can set the selection band pass filter 126 and the sub band pass filter 128 for compensating for hearing loss. At this time, the selection band pass filter 126 may be selectively set for an audible frequency band of 20 Hz to 20 KHz, for example, 500 Hz to 4 KHz as an audio band, and the detailed band pass filter 128 is an octave band or 1/ It can be set to a 3-octave band.

9 shows a configuration for calculating the filter coefficient by the mobile processor 102 of the present invention.

S100: First, set the center frequency to 1KHz and start calculating the filter coefficient.

S110: First, the mobile processor 102 reads the waveform data from the isometric curve data memory 106 as a center frequency waveform, stores it in the output frame memory 134, and stores the user through the audio interface 108 or the short-range communication unit 112. It is transmitted through the hearing of the person.

S120: Then, the user of the mobile device 100 inputs the minimum detection level through the minimum detection volume input unit 110 and provides the input to the mobile processor 102.

S130: The mobile processor 102 calculates filter coefficients of the selection band pass filter 126 and the sub band pass filter 128 based on the input minimum detection level.

S140: Subsequently, the mobile processor 102 retrieves and reads the isometric curve data corresponding to the minimum detection level input from the isometric curve data memory, and converts the gain on the isometric curve with respect to the frequencies of other bands of the corresponding isometric data. Each waveform data is read and repeated from S110.

In the above configuration, the filter coefficients of the selection band pass filter 126 and the sub band pass filter 128 are;

S132: Determine the center frequency and bandwidth of each band for determining the coefficient of the filter,

S133: input the center frequency to calculate the gain for each band,

S134: Calculate the contribution function of the gain for each band as a matrix,

S135: Decompose the singular value of the contribution matrix for each band (Singular Value Decomposition, SVD),

S136: The transformation matrix and filter coefficient are calculated and stored in the filter coefficient storage unit 122.

The above filter coefficient calculation and storage process is characterized in that a gain compensation for each band of the sub-band pass filter 128 of the octave band or 1/3 octave band is given to the audible frequency band set by the selection band pass filter 126. Have.

FIG. 10 is a diagram illustrating an operation configuration and an operation relationship of a mobile hearing aid equipped with a user adaptive digital filter of the present invention. A mobile hearing aid equipped with a user adaptive digital filter of the present invention configured as described with reference to FIGS. 7 to 9 of the previous drawings can operate with the illustrated configuration.

The mobile hearing aid equipped with the user adaptive digital filter of the present invention A/D converts the sound input to the microphone through the audio interface 108 and stores it in the input frame memory 124, and the input frame memory 124 The data of is selectively filtered through a selection band pass filter 126 to a band of a signal to be processed. The filtered signal data compensates for hearing loss by adjusting the gain for each octave band or 1/3 octave band for the user through the sub-band pass filter 128, and the output frame memory 134 by the mobile processor 102 It is stored and provided to the audio interface 108 or the short-range communication unit 112 to be transmitted to the user as a sound compensated for the hearing loss.

At this time, the filtered signal data of the sub-band pass filter 128 is supplied to the band signal integrating unit 130 to calculate the size of the filtered signal data, and the output of the band signal integrating unit 130 is at a threshold level. When the size of the signal data supplied to the determination unit 132 and calculated by the sub-band pass filter 128 is less than or equal to the threshold level, it is determined as noise and all data in the output frame memory 134 is deleted, and the audio interface 108 B, so that the sound through the short-range communication unit 112 is processed as silence.

According to the mobile hearing aid provided with the user adaptive digital filter of the present invention described above, a processing band is selected as a selection band pass filter for an audible frequency band, and gain compensation for each hearing loss band is performed as a sub-band pass filter. It provides a technical feature that selectively operates on an input signal above the noise level.

The mobile hearing aid technology having a user adaptive digital filter of the present invention has been described with reference to limited embodiments and drawings, but the present invention is not limited thereto, and those of ordinary skill in the art to which the present invention pertains. It goes without saying that various modifications and variations are possible within the scope of the technical spirit of the present invention and the claims to be described below.

100: mobile device 102: mobile processor
104: mobile communication unit 106: isometric curve data memory
108: audio interface 110: minimum sensing volume input unit
112: short-range communication unit 120: DSP module
122: filter coefficient storage unit 124: input frame memory
126: optional band pass filter 128: detailed band pass filter
130: band signal integrating unit 132: threshold level determining unit
134: output frame memory

Claims (10)

In the mobile hearing aid provided with a user adaptive digital filter having a user's mobile device 100 and a wired earphone or wireless earphone connected to the mobile device 100, or a wired/wireless bone conduction transducer,
The mobile device 100,
A mobile processor 102 that performs overall control of the mobile device 100; And,
A mobile communication unit 104;
An isometric curve data memory 105 for storing waveform data and isometric curve data for each audible frequency;
An audio interface 108 for A/D conversion of microphone input, receiving speaker and earphone output data, D/A conversion, and outputting;
A DSP module 120 that receives microphone input data through the audio interface 108, corrects the hearing sense, and removes noise;
A minimum sensing volume input unit 110 that reads waveform data for each audible frequency from the isosensory curve data memory 105 by the mobile processor 102 and outputs it through the audio interface 108 to receive the minimum audible gain from the user;
A short-range communication unit 112 for providing audio data such as Bluetooth or NFC to a wireless earphone or a wireless bone conduction transducer;
Mobile hearing aid equipped with a user adaptive digital filter, characterized in that consisting of
The method of claim 1, wherein the DSP module (120),
An input frame memory 124 for storing A/D conversion data of sound input to the microphone through the audio interface 108; And,
A selection band pass filter 126 for selectively passing a band of a signal to be processed with respect to the data in the input frame memory 124;
A sub-band pass filter (128) which adjusts and passes a gain for each octave band or 1/3 octave band with respect to the band of the signal to be processed;
An output frame memory (134) that stores the filtered signal data of the sub-band pass filter (128) and provides it to the audio interface (108) or the short-range communication unit (112) to transmit sound to a user;
Mobile hearing aid equipped with a user adaptive digital filter, characterized in that consisting of
The method of claim 2, wherein the DSP module (120),
The center frequencies of the selection band pass filter 126 and the sub band pass filter 128 and the gain of the pass signal are adjusted as filter coefficients,
The filter coefficients are calculated from the mobile processor 102 and stored in the filter coefficient storage unit 122.
The method of claim 2, wherein the DSP module (120),
The filtered signal data of the sub-band pass filter 128 is supplied to the band signal integrating unit 130,
Calculate the size of the filtered signal data,
The output of the band signal integrating unit 130 is supplied to the threshold level determining unit 132,
A mobile hearing aid having a user adaptive digital filter, characterized in that the mobile processor 102 determines whether or not the size of the signal data calculated by the sub-band pass filter 128 is equal to or greater than a threshold level.
The method of claim 2, wherein the mobile processor (102),
When the size of the signal data calculated by the sub-band pass filter 128 is greater than or equal to the threshold level,
The data in the output frame memory 134 is determined to be valid and provided to the audio interface 108 or the short-range communication unit 112,
When the size of the signal data calculated by the sub-band pass filter 128 is less than or equal to the threshold level,
A mobile hearing aid equipped with a user adaptive digital filter, characterized in that the sound through the audio interface 108 or the short-range communication unit 112 is processed as silence by determining as noise and deleting all data in the output frame memory 134
The method of claim 3, wherein the mobile processor (102),
Set the center frequency to 1KHz,
The waveform data is read from the isometric curve data memory 106 as a center frequency waveform, stored in the output frame memory 134, and transmitted to the user's hearing through the audio interface 108 or the short-range communication unit 112
The user inputs the minimum detection level through the minimum detection volume input unit 110 and provides it to the mobile processor 102,
The mobile processor 102 calculates filter coefficients of the selection band pass filter 126 and the detailed band pass filter 128 based on the input minimum detection level,
The isometric curve data corresponding to the minimum detection level input from the isometric curve data memory 106 is retrieved and read, and the gain on the isometric curve is converted for the frequencies of the other bands of the corresponding isometric data, and waveform data is read out for each band With the waveform as the center frequency,
Characterized in that it is configured to read the waveform data from the isometric curve data memory 106 as a center frequency waveform, store it in the output frame memory 134, and transmit it to the user's hearing through the audio interface 108 or the short-range communication unit 112. Mobile Hearing Aid Equipped with User-Adaptable Digital Filter
The method of claim 6, wherein the filter coefficient is;
The mobile processor 102 determines the center frequency and bandwidth for each band for determining the coefficient of the filter, then inputs the center frequency for calculating the gain for each band, calculates the contribution function of the gain for each band as a matrix, and Mobile hearing aid equipped with a user-adaptive digital filter, characterized in that the singular value decomposition (SVD) of each contribution matrix is decomposed, the transformation matrix and the filter coefficient are calculated and stored in the filter coefficient storage unit 122
The method of claim 7, wherein the filter coefficient is;
For the audible frequency band set by the selective band pass filter 126
Mobile hearing aid with a user adaptive digital filter, characterized in that it is configured to provide a gain compensation for each band of the sub-band pass filter 128 of the octave band or 1/3 octave band
The mobile hearing aid according to claim 1, wherein the mobile hearing aid has a user adaptive digital filter.
A/D conversion of the sound input to the microphone through the audio interface 108 and storing it in the input frame memory 124,
The data of the input frame memory 124 is selectively filtered through a selection band pass filter 126 to selectively filter a band of a signal to be processed,
The filtered signal data compensates for hearing loss by adjusting a gain for each octave band or 1/3 octave band for the user through the detailed band pass filter 128,
User adaptive digital filter, characterized in that it is stored in the output frame memory 134 by the mobile processor 102 and provided to the audio interface 108 or the short-range communication unit 112 to deliver the sound compensated for the hearing loss to the user. Mobile hearing aid equipped with
The mobile hearing aid according to claim 9, wherein the mobile hearing aid has a user adaptive digital filter.
The filtered signal data of the sub-band pass filter 128,
It is supplied to the band signal integrating unit 130 to calculate the size of the filtered signal data,
The output of the band signal integrating unit 130 is supplied to the threshold level determining unit 132
When the size of the signal data calculated by the sub-band pass filter 128 is less than the threshold level, it is determined as noise and all data in the output frame memory 134 is deleted, and Mobile hearing aid equipped with a user adaptive digital filter, characterized in that the sound is processed to be silent

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