WO2011075872A1 - Hearing aid structure of enabling selecting acoustical compensation curve and remote-control device for controlling hearing aid - Google Patents

Abstract

A hearing aid structure of enabling selecting acoustical compensation curve and a remote-control device for controlling the hearing aid, wherein the hearing aid structure, by means of using the memory storing multiple hearing compensation curve data and the digital signal processor, can equally process the received voice signal with the suited hearing compensation curve data stored in the memory by using the digital signal processor, so as to make the hearing-loss person obtain less distortion of voice signal. The hearing-loss person can also use the remote-control device to select the suited hearing compensation curve data to substitute the way of tuning after getting off the hearing aid structure.

Description

 Hearing aid structure with hearing compensation curve and its remote control

 The present invention relates to a hearing aid structure and a remote controller thereof that can select a hearing compensation curve, and more particularly to a hearing aid structure and a remote controller thereof for use in selecting a hearing compensation curve for improving the quality of a hearing aid. Background technique

 Hearing aids are commonly used for hearing loss in hearing loss or hearing loss, and because the hearing loss wears hearing aids almost all the time, and relies on hearing aids to keep the outside world Contact, therefore the quality of the hearing aid, such as: Whether it can truly transmit all the sounds of the outside world, the level of speech recognition, etc., will affect the quality of life of the hearing loss.

 Figure 1 is a graph of hearing. Figure 2 is a graph of the hearing compensation curve.

 As shown in Figure 1, each listener is required to use the audiologist to assist in the production of a hearing aid. By reading the audiogram, the type and extent of the hearing loss of the hearing loss can be assessed, for example: Hearing at high frequencies is noticeably reduced or overall hearing is declining...etc. The hearing compensation curve is then made for the type and extent of hearing impairment, and the hearing aid can be designed according to the hearing compensation curve so that the hearing aid can meet the needs of the hearing loss.

 However, during the hearing aid fitting process, there is often a poor communication between the audiologist and the hearing loss, or the prepared hearing curve does not fully reflect the hearing loss type of the hearing loss, so it is easy to cause hearing loss. The wearer does not achieve the desired effect after wearing the hearing aid, and the hearing aid is required to continuously adjust the hearing aid.

 In addition, as Harvey Di 1 Ion, author of HEARING AIDS, points out, when the same hearing curve is calculated in different ways, it will produce different results of the hearing compensation curve.

 As shown in Figure 2, the same hearing curve (shown in Figure 1) is calculated in three different ways: P0G0 II, DSL and NAL-RP, but three different hearing compensation curves are obtained, and three kinds of hearing. There is a significant difference between the compensation curves. For example, when calculated using the P0G0 II and NAL-RP methods, the resulting intensity gains (intensity gain) are 50 decibels (dB) and 80 decibels at a frequency of 4000 Hz, respectively. The calculation results of the way, the difference is as high as 30 decibels.

From this calculation, it can be seen that although the same hearing curve is used, when different calculation methods are selected, it will also have a considerable influence on the hearing compensation curve, so it is easy to make the hearing aid designed according to the hearing compensation curve not meet the requirements. The needs of the hearing loss. Summary of the invention

 It is an object of the present invention to provide a hearing aid structure and a remote controller thereof that can select a hearing compensation curve, and use a combination of a memory (or memory) and a digital signal processor, and store multiple arrays of hearing in the memory. The compensation curve data is used to provide the hearing loss to choose the appropriate hearing compensation curve, so it can better meet the actual use requirements of the hearing loss, and can avoid the error caused by different calculation methods.

 Another object of the present invention is to provide a hearing aid structure and a remote control thereof that can select a hearing compensation curve that uses digital means to adjust parameters in the structure of the hearing aid and is therefore more accurate than analog adjustments.

 A further object of the present invention is to provide a hearing aid structure and a remote controller thereof that can select a hearing compensation curve. Since the remote controller uses a wireless module to perform a telecommunications connection with the hearing aid, the hearing loss can be adjusted without removing the hearing aid structure. Therefore, it has the convenience of manipulating the hearing aid.

 The object of the present invention and solving the technical problems thereof are achieved by the following technical solutions. A hearing aid structure for selecting a hearing compensation curve according to the present invention includes: a wireless receiving module receiving a first control signal; a regulating module generating a control signal; and a first sound receiving module receiving a first An analog to digital conversion module, the telecommunication is connected to the output end of the first sound receiving module, receives the first sound signal, and is converted to form a first digital signal; a first digital signal processing module, the telecommunication is connected to the wireless receiving The module and the analog-to-digital conversion module have: a first memory storing a plurality of arrays of hearing compensation curve data, and a first digital signal processor receiving the first control signal, the control signal, and the first number Signaling to select at least one set of the hearing compensation curve data, and performing equalization processing according to the selected at least one set of the hearing compensation curve data to form at least one second digital signal; a digital analog conversion module, the telecommunication connection first An output of the digital signal processing module receives at least one of the second digits And converting a signal to form at least one first analog signal; and a signal transmitting module electrically connecting the output of the digital-to-analog conversion module, receiving at least one of the first analog signals, and transmitting at least one second sound signal.

 The object of the present invention and solving the technical problems thereof can be further achieved by the following technical measures. The aforementioned hearing aid structure, wherein the wireless receiving module is a Bluetooth receiving module. The aforementioned hearing aid structure, wherein the wireless receiving module is an infrared receiving module. The aforementioned hearing aid structure, wherein the first sound pickup module is a directional microphone. The aforementioned hearing aid structure, wherein the first memory is a non-volatile memory. The aforementioned hearing aid structure, wherein the first digital signal processor comprises at least one digital amplifier, at least one equalizer and a noise canceller.

The aforementioned hearing aid structure, wherein the signal transmitting module has an amplifier and a shovel S? The object of the present invention and solving the technical problems thereof are also achieved by the following technical solutions. A remote control structure for a hearing aid for controlling a selectable hearing compensation curve according to the present invention includes: a user interface module for generating a second control signal; a second digital signal processing module, the telecommunication connection a user interface module, comprising: a second memory storing a plurality of arrays of hearing compensation curve data; and a second digital signal processor receiving the second control signal to select a set of the hearing compensation curve data, Forming a third digital signal, and the third digital signal is displayed on the user interface module; and a wireless transmitting module, the telecommunication connection is connected to the output end of the second digital signal processing module, receiving the third digital signal, and transmitting one The first control signal.

 The object of the present invention and solving the technical problems thereof can be further achieved by the following technical measures. The remote control structure described above further has a second sound pickup module that generates a second sound signal.

 The remote controller structure further has an analog-to-digital conversion module, and an input end thereof is electrically connected to the second sound receiving module to receive the second sound signal and converted into a fourth digital signal, the analog digital conversion module The output is in telecommunication connection with the second digital signal processing module.

 The remote controller structure described above, wherein the second memory is a non-volatile memory. The remote control structure described above, wherein the second digital signal processor comprises at least one digital amplifier, at least one equalizer and a noise canceller.

 The remote controller structure described above, wherein the wireless transmitting module is a Bluetooth transmitting module. The remote controller structure described above, wherein the wireless transmitting module is an infrared transmitting module. The present invention has significant advantages and advantageous effects over the prior art. With the above technical solution, the hearing aid structure and the remote controller of the present invention which can select the hearing compensation curve have at least the following advantages and beneficial effects:

 First, because the hearing compensation curve is stored in the structure of the hearing aid, the most suitable hearing compensation curve can be selected according to the actual environmental requirements, so that the hearing aid can better meet the needs of use and achieve the effect of effectively improving the quality of life of the hearing loss.

 Second, the hearing compensation curve can be selected directly from the control module on the hearing aid, or can be adjusted by the remote control method to achieve the convenience of manipulating the hearing aid.

 In summary, the present invention is a hearing aid structure and a remote controller thereof that can select a hearing compensation curve, wherein the hearing aid structure is configured by a memory storing a plurality of arrays of hearing compensation curve data and used with a digital signal processor to make the hearing aid structure The received sound signal can be equalized by the digital signal processor and the matched hearing compensation curve data in the memory, whereby the listener can obtain the sound signal with less distortion. The hearing loss can also use the remote control to select the appropriate hearing compensation curve data, instead of removing the structure of the hearing aid structure adjustment, so that the function of the hearing aid structure can be more conveniently controlled. The invention has significant advances in technology and has obvious positive effects, and is a novel, progressive and practical new design.

The above description is merely an overview of the technical solution of the present invention, in order to more clearly understand the present invention. The above and other objects, features, and advantages of the present invention will be apparent from the description and appended claims. BRIEF DESCRIPTION OF THE DRAWINGS

 Figure 1 is a graph of hearing.

 Figure 2 is a graph of the hearing compensation curve.

 3 is a first block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention.

 4 is a second block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention.

 Figure 5 is a schematic diagram of an embodiment of an operational flow of a first digital signal processor of the present invention. Figure 6 is a third block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention.

 Figure 7 is a fourth block diagram of an embodiment of a hearing aid structure of an alternative hearing curve of the present invention.

 Figure 8 is a first block diagram of an embodiment of a remote control for controlling a selectable hearing compensation curve hearing aid of the present invention.

 Figure 9 is a second block diagram of an embodiment of a remote control structure for controlling a selectable hearing compensation curve hearing aid of the present invention.

 Figure 10 is a schematic illustration of an embodiment of the operational flow of a second digital signal processor of the present invention.

 Figure 11 is a schematic illustration of a third party block diagram of an embodiment of a remote control for controlling a selectable hearing compensation curve hearing aid of the present invention.

 100 hearing aid structure 200: remote control structure

 10: Wireless Receiver Module 20: Control Module

 21: First radio module 22: Second radio module

 30: Analog to Digital Converter Module 41: First Digital Signal Processing Module

411 first memory 412: first digital signal processor

413 Digital Amplifier 414: Noise Canceller

 415 equalizer 42: second digital signal processing module

421 second memory 422: second digital signal processor

423 Digital Amplifier 424: Noise Canceller

 425 Equalizer 50: Digital Analog Conversion Module

60: Signal Transmitter Module 601: Amplifier

602 Speaker 70: User Interface Module 80: Wireless transmission module Acou-1: First sound signal

Acou-2: second sound signal Ana-1 : first analog signal

 Ctr l -1: first control signal Ctrl _2: second control signal Dig_ l : first digital signal Di g-2: second digital signal

 Dig- 3: third digital signal Dig.4: fourth digital signal

 Op: Regulatory signal S10-S40: Steps The best way to achieve the invention

 In order to further explain the technical means and efficacy of the present invention for achieving the intended purpose of the invention, the hearing aid structure and the remote controller of the selectable hearing compensation curve according to the present invention are embodied in the following with reference to the accompanying drawings and preferred embodiments. The method, structure, characteristics and efficacy are described in detail later.

 <Hearing Aid Structure 100 Embodiment>

 3 is a first block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention. 4 is a second block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention. Figure 5 is a schematic diagram of an embodiment of an operational flow of a first digital signal processor of the present invention. Figure 6 is a third party block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention. Figure 7 is a fourth block diagram of an embodiment of a hearing aid structure of an alternative hearing compensation curve of the present invention.

 As shown in FIG. 3, the hearing aid structure 100 of the optional hearing compensation curve of the embodiment of the present invention includes: a wireless receiving module 10; a regulating module 20; a first sounding module 21; an analog to digital conversion module 30; The first digital signal processing module 41; a digital to analog conversion module 50; and a signal transmitting module 60.

 The wireless receiving module 10 described above may be a Bluetooth receiving module, an infrared receiving module or other wireless device. The setting of the wireless receiving module 10 can be used to receive and output a first control signal Ctr l _ l, and the first control signal Ctr l _l is a digital signal, and the Bluetooth receiving module in the wireless receiving module 10 can use the CSR company. The model BC5MM chip produced.

 The above-mentioned control module 20 can be a ancestor, by pressing to generate a control signal 0p, and the control signal Op is a digital signal.

 The first sound module 21 is configured to receive a first sound signal Acou_l, and the first sound signal Acou-1 is an analog signal. The first radio module 21 can be a directional microphone for receiving the first sound signal Acou_l from a specific direction, so that background noise in other directions is ignored, for example: when the listener is in a noisy environment The directional microphone can enhance the first sound signal Acou-1 sent by the interlocutor in a specific direction, thereby improving the voice recognition power.

The above analog to digital conversion module 30, which can be composed of an analog to digital converter, and simulates The digital conversion module 30 is connected to the output of the first sound module 21 for receiving the analog first sound signal Acou-1 and converting the first sound signal Acou-1 into a first digital signal Dig-1.

 The first digital signal processing module 41 is electrically connected to the output ends of the wireless receiving module 10, the regulating module 20, and the analog-to-digital converting module 30, and as shown in FIG. 4, the first digital signal processing module 41 has: a memory 411; and a first digital signal processor 412.

 The first memory 411 is configured to store multi-array hearing compensation curve data, and the first memory 411 can be a non-volatile memory, such as a read only memory (ROM), a flash memory (F1 ash memory) ... …Wait. By means of the non-volatile memory, all of the data stored in the first memory 411 can remain intact when the power supply in the hearing aid structure 100 is depleted.

 Each set of hearing compensation curve data stored in the first memory 411 is individually matched with the type and degree of hearing loss of each listener, and each set of hearing compensation curve data is composed of a plurality of parameters. For example: frequency, intensity, etc. In order to meet the needs of the listener in different places, the first memory 411 stores multiple arrays of hearing compensation curve data, so the listener can choose to use the appropriate hearing compensation curve data according to the demand.

 As shown in FIG. 5, the first digital signal processor 412 is configured to: receive the first control signal, the regulation signal, and receive the first digital signal (step S10); and form a second digital signal (step S20). .

 Receiving the first control signal, the control signal, and the receiving the first digital signal (step S10): as shown in FIG. 4, the output ends of the wireless receiving module 10 and the control module 20 are electrically connected to the first digital signal processing module 41. Therefore, when the first control signal Ctr l_1 or the control signal Op is input to the first digital signal processor 412 of the first digital signal processing module 41, the first digital signal processor 412 is based on the first control signal Ctrl_1 or the control signal Op. Select at least one set of hearing compensation curve data. For example: When the hearing loss of the left and right ears of the hearing loss is different, two different sets of hearing compensation curves can be selected to meet the needs of both ears of the hearing loss.

 Since the output of the analog-to-digital conversion module 30 is also electrically coupled to the first digital signal processing module 41, the first digital signal Dig_1 is also input to the first digital signal processor 412 of the first digital signal processing module 41.

Forming a second digital signal as described above (step S20): as shown in FIG. 4, the first digital signal processor 412 can select at least one set of hearing compensation curve data according to the first control signal Ctrl_l or the control signal Op, and The first digital signal Dig_l is equalized by the selected hearing compensation curve data, thereby forming at least one second digital signal Dig_2. As shown in FIG. 6, the first digital signal processor 412 includes at least one digital amplifier 413, a noise canceller 414, and at least one equalizer 415. The first digital signal Dig_l is amplified by the digital amplifier 413, and the background noise in the first digital signal Dig-1 is reduced by the noise canceller 414 to highlight the speech data, and the equalizer 415 is used to the first digital signal Dig-1. Equalizing and matching according to the first control signal Ctr l - 1 or At least one set of hearing compensation curve data selected by the control signal Op is equalized to form at least one second digital signal Di g_2. The noise canceler 414 can use the model FM2010 chip produced by Forte Media, and the equalizer 415 can use the Model 3014 chip produced by Texas Instruments.

 The first digital signal processor 412 can select at least one set of hearing compensation curve data through the wireless receiving module 10 or the regulating module 20 to provide a more flexible manipulation mode for the hearing loss, and can be adapted according to the actual needs of the hearing loss person. Use the hearing aid structure 100. Moreover, since the hearing aid structure 100 can provide different hearing compensation curves according to the degree of hearing loss of the left and right ears, the effect of effectively improving the quality of life of the hearing loss can be achieved.

 As shown in FIG. 6, the digital-to-analog conversion module 50 is electrically connected to the output end of the first digital signal processing module 41 for receiving at least one second digital signal Dig-2, and the digital-to-analog conversion module 50 can be converted by digital simulation. The device is configured to convert at least one second digital signal Dig_2 into at least one first analog signal Ana-1.

 The signal sending module 60 is connected to the output end of the digital-to-analog conversion module 50 to receive at least one first analog signal Ana-1 output by the digital-to-analog conversion module 50 and at least one first analog signal Ana- Ι Converted into at least one sound signal, and sends the sound signal to the ear of the hearing loss. For example: The signal transmitting module 60 can send two sound signals and send them to the left and right ears respectively.

 As shown in FIG. ,, the signal transmitting module 60 further has an amplifier 601 and a speaker 602. After the amplifier 601 is used to amplify the first analog signal Ana-1, the speaker 602 can convert and output an audio signal, thereby providing A clearer voice of the hearing loss.

 The communication problems between the hearing loss and the hearing teacher appearing during the fitting process of the hearing aid structure 100, as well as the different hearing compensation curve data caused by different calculation methods, can be selected by the hearing loss person to select the hearing compensation curve data to reduce The effects of the fitting process and the quality of the hearing aid structure 100 can be improved.

 The first digital signal processing module 41 used by the hearing aid structure 100, which can also select the hearing compensation curve, is fully digitalized, and the advantage of full digitization is that the hearing aid structure 100 can be controlled by software and controlled by digital means for more precise control. The parameters in each set of hearing compensation curves. In addition, the all-digital design can also reduce the size of the hearing aid structure 100, thereby achieving power saving and efficiency.

<Remote Control Structure 200 Embodiments>

8 is a first block diagram of an embodiment of a remote control for controlling a selectable hearing compensation curve hearing aid of the present invention. 9 is a second block diagram of an embodiment of a remote control for controlling a selectable hearing compensation curve hearing aid of the present invention. 10 is a schematic diagram of an embodiment of an operational flow of a second digital signal processor of the present invention. Figure 11 is a type of the present invention A third-party block diagram of an embodiment of a remote control for controlling a selectable hearing compensation curve hearing aid.

 As shown in FIG. 8, the remote control structure 200 for controlling the selectable hearing compensation curve hearing aid of the embodiment of the present invention includes: a user interface module 70; a second digital signal processing module 42; and a wireless transmitting module 80. .

 The user interface module 70 provides an interface for the listener to control the remote controller structure 200. Therefore, the user interface module 70 can include at least one screen and a plurality of buttons, or a screen and a stylus. . Through the user interface module 70, the listener can manually control the remote control structure 200 to generate a second control signal Ctrl_2, which can be controlled by pressing a button or using a stylus to write on the screen.

The second digital signal processing module 42 is telecommunications connected to the user interface module 70, and as shown in FIG. 9, the second digital signal processing module 42 has: a second memory 421; and a second digital signal processor. ⁴²² . .

 The second memory 421 described above stores multi-array hearing compensation curve data, and each set of hearing complement curve data is composed of ^ parameters, such as: frequency Γ intensity...etc. The second memory 421 can be a non-volatile memory such as read only memory (ROM), 'f flash memory, and the like.

 As shown in FIG. 10, the second digital signal processor 422 is configured to perform the steps of: receiving a second control signal (step S30); and forming a third digital signal (step S40).

 Receiving the second control signal (step S30): as shown in FIG. 9, receiving the second control signal Ctrl-2 generated by the user interface module 70 by the second digital signal processor 422, and processing the second digital signal The 422 can select a set of hearing compensation curve data from the second memory 421 according to the second control signal Ctrl-2. That is to say, through the user interface module 70, the listener can manually select a set of hearing compensation curve data.

 Forming a third digital signal as described above (step S40): as shown in FIG. 9, after receiving the second control signal Ctrl-2, the second digital signal processor 422 processes the second control signal Ctrl-2 to form a first The third digital signal Dig-3, and the third digital signal Dig-3 will be displayed on the screen of the user interface module 70, so that the listener can confirm the issued version according to the content displayed on the user interface module 70. The second control signal Ctrl-2 has been received and processed by the second digital signal processing module 42, so that the effect of human-computer interaction can be achieved.

 As shown in FIG. 11, the remote control structure 200 can further include a second sound module 22 and an analog-to-digital conversion module 30, wherein the second sound module 22 can be a microphone, and can receive a second sound signal Acou-2. The second sound signal Acou-2 is an analog signal.

Since the remote control structure 200 can be close to the sound source by the second sound collection module 22, the second sound signal Acou_2 which is the most direct and undistorted can be captured at a close distance, thereby contributing to the remote controller structure 200. The most suitable first control signal Ct rl _ l is generated.

 The input end of the analog-to-digital conversion module 30 is electrically connected to the second sound collection module 22 for receiving the second sound signal Acou_2 and converting the second sound signal Acou-2 into a fourth digital signal Dig-4. Since the output of the analog-to-digital conversion module 30 is electrically connected to the second digital signal processing module 42, the fourth digital signal Dig_4 is transmitted to the second digital signal processing module 42 so that the fourth digital signal Di g_4 can pass the second number. The signal processing module 42 performs processing.

 As shown in FIG. 11, the second digital signal processor 422 includes at least one digital amplifier 423, a noise canceller 424, and at least one equalizer 425 for converting the second control signal Ct r 1 - 2 to the third Digital signal Di g-3.

 The speech data is highlighted by the digital amplifier 423 in the second digital signal processing module 42 to amplify the fourth digital signal Dig_4, and by using the noise canceller 424 to reduce the background noise in the fourth digital signal Dig-4.

 When only the fourth digital signal Dig_4 is input to the second digital signal processing module 42, the second digital signal processor 422 automatically selects a suitable set of hearing compensation curve data and listens to it by the equalizer 425. The compensation curve data is equalized to the fourth digital signal Dig-4 to form a third digital signal Dig_3.

 When the second control signal Ctrl-2 and the fourth digital signal Dig-4 are simultaneously input to the second digital signal processing module 42, the equalizer 425 is matched with the hearing compensation curve selected by the second control signal Ctrl-2. Data, the fourth digital signal Dig_4 is equalized to generate a third digital signal Dig_3.

 The noise canceller 424 can use the model FM2010 chip produced by ForteMedia, and the equalizer 42 can use the model 3014 chip produced by Texas Instruments.

 The wireless transmitting module 80 is electrically connected to the output end of the second digital signal processing module 42 for receiving the third digital signal Dig-3 from the second digital signal processing module 42 and converting the third digital signal Dig_3 into a first A control signal Ctr l _l is sent. The wireless transmitting module 80 can be a Bluetooth transmitting module, an infrared transmitting module or other wireless device, wherein the Bluetooth transmitting module can use the model BC5MM chip produced by CSR.

 When the listener changes the environment, for example: From the restaurant to the road, because the surrounding sound signal has undergone a large change, the listener may need to adjust the parameters in the hearing aid structure 100, for example: Specifying a certain frequency Wide sound signal to enhance speech recognition.

At this time, the listener can select a suitable set of hearing compensation curves through the remote interface structure 200 of the hand, through the user interface module 70, via the second digital signal processing module 42 and the wireless transmitting module 80, so that the remote controller structure The 200 can transmit the first control signal Ctr l _ l to the hearing aid structure 100, so that the hearing aid structure 100 can be adjusted instantly according to the needs of the listener. Because the hearing aid structure 100 can be controlled by the remote control structure 200, the user does not need to remove the hearing aid 100 during the adjustment process, thereby making it easier for the hearing lossr to use the hearing aid 100. In addition, receiving the sound signal from the sound source by the second sound collection module 22 of the remote controller structure 200 can also help the hearing lossr to use the hearing aid structure 100 more effectively.

 The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the present invention. The skilled person can make some modifications or modifications to the equivalent embodiments by using the above-disclosed technical contents without departing from the technical scope of the present invention. It is still within the scope of the technical solution of the present invention to make any simple modifications, equivalent changes and modifications to the above embodiments.

Claims

Rights request

A hearing aid structure capable of selecting a hearing compensation curve, characterized in that it comprises: a wireless receiving module, receiving a first control signal;

 a control module that generates a control signal;

 a first sound module, receiving a first sound signal;

 An analog to digital conversion module, the telecommunication is connected to the output end of the first sound receiving module, receives the first sound signal, and is converted to form a first digital signal;

 a first digital signal processing module, the telecommunications connection to the wireless receiving module and the analog to digital conversion module, comprising: a first memory storing a plurality of arrays of hearing compensation curve data; and a first digital signal processor receiving The first control signal, the control signal and the first digital signal are selected to select at least one set of the hearing compensation curve data, and are equalized according to the selected at least one set of the hearing compensation curve data to form at least one second Digital signal;

 a digital-to-analog conversion module, telecommunications connected to the output of the first digital signal processing module, receiving at least one of the second digital signals, and converting to form at least one first analog signal;

 A signal transmitting module is connected to the output end of the digital-to-analog conversion module, receives at least one of the first analog signals, and transmits at least one sound signal.

 2. A hearing aid structure according to claim 1 wherein said wireless receiving module is a Bluetooth receiving module.

 3. The hearing aid structure of claim 1 wherein said wireless receiving module is an infrared receiving module.

 4. A hearing aid structure according to claim 1 wherein said first sound module is a directional microphone.

 5. A hearing aid structure according to claim 1 wherein said first memory is a non-volatile memory.

 6. The hearing aid structure of claim 1 wherein said first digital signal processor comprises at least one digital amplifier, at least one equalizer, and a noise canceller.

 7. The hearing aid structure of claim 1 wherein said signal transmitting module has an amplifier and a speaker.

 8. A remote control structure for a hearing aid for controlling a selectable hearing compensation curve, characterized in that it comprises:

 a user interface module, generating a second control signal;

a second digital signal processing module, the telecommunications device is connected to the user interface module, and has: a second memory storing a plurality of arrays of hearing compensation curve data; and a second digital signal processor receiving the second control signal , selecting a set of hearing compensation curve data, and forming a third digital signal, and the third digital signal is displayed on the user interface module; a wireless transmitting module, the telecommunication connection is connected to the output end of the second digital signal processing module, receiving the third digital signal and transmitting a first control signal.

 9. The remote controller structure of claim 8 further comprising a second sound module for generating a second sound signal.

 The remote controller structure according to claim 9, further comprising an analog to digital conversion module, wherein the input end is electrically connected to the second sound receiving module to receive the second sound signal and converted into a fourth The digital signal, the output of the analog to digital conversion module is electrically connected to the second digital signal processing module.

 11. The remote controller structure of claim 8 wherein said second memory is a non-volatile memory.

 12. The remote controller structure of claim 8, wherein the second digital signal processor comprises at least one digital amplifier, at least one equalizer, and a noise canceller.

 13. The remote controller structure according to claim 8, wherein the wireless transmitting module is a Bluetooth transmitting module.

 14. The remote controller structure according to claim 8, wherein said wireless transmitting module is an infrared transmitting module.