CN214901287U - Audio device, programming device and audio system - Google Patents

Abstract

The utility model relates to an audio device, programming device and audio system. The audio device includes a first audio device body, a first port, a second audio device body, and a second port; the second port is connected with the first port and the second audio device main body respectively; the first port is connected with a programming device, and the programming device comprises a third port; the first port is connected with the third port, and the structure of the first port corresponds to that of the third port; when the programming device is communicated with the audio device, the communication signal sent by the programming device is transmitted to the audio device through the third port and the first port. Through the audio device, if the wireless communication module of the hearing aid fails or a device for managing the wireless communication module fails, the hearing aid can be ensured to realize a firmware upgrading function.

Description

Audio device, programming device and audio system

Technical Field

The utility model relates to an electronic equipment technical field especially relates to an audio device, programming device and audio system.

Background

With the increasing of high-intensity noise, the number of patients with hearing impairment is increased, and generally, when the hearing impairment occurs to the patients, most of the patients can choose to wear hearing aids to ensure normal hearing effects. In order to ensure that the patient wearing the hearing aid can feel the benefits of the new hearing aid technology, the hearing aid is generally upgraded with firmware during the technology update.

In the related art, a wireless communication module is generally disposed in a hearing aid, so that when firmware of the hearing aid is upgraded, upgrade software can be sent to the wireless communication module of the hearing aid in a computer terminal in a wireless communication manner, and sent to a processor in the hearing aid through the wireless communication module of the hearing aid, and finally, the processor completes the firmware upgrade of the hearing aid according to the upgrade software.

However, in the related art, when firmware upgrade is performed on the hearing aid, if the wireless communication module of the hearing aid fails or the device or software for managing the wireless communication module fails, it is difficult to ensure that the hearing aid implements the firmware upgrade function.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide an audio device, a programming device, and an audio system for solving the problem that it is difficult to ensure that the hearing aid realizes the firmware upgrade function if the wireless communication module of the hearing aid malfunctions or the device or software managing the wireless communication module malfunctions when the firmware upgrade is performed on the hearing aid.

An audio device includes a first audio device body, a first port, a second audio device body, and a second port; the second port is connected to the first port and the second audio device body, respectively;

the first port is connected with a programming device, and the programming device comprises a third port; the first port is connected to the third port, and the structure of the first port corresponds to the structure of the third port;

when the programming device is communicated with the audio device, the communication signal sent by the programming device is transmitted to the audio device through the third port and the first port.

The audio device comprises a first audio device body, a second audio device body, a first port and a second port, wherein the second port is respectively connected with the first port and the second audio device body; when the programming device is communicated with the audio device, the communication signal sent by the programming device is transmitted to the audio device through the third port and the first port. In the audio device, because the first port structure corresponds to the third port structure, the connection between the audio device and the programming device and the data transmission can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structures to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device for managing the wireless communication module fails.

In one embodiment, the first port is detachably connected to the second port, and the third port is detachably connected to the first port.

In this embodiment, the first port, the second port and the third port are detachably connected, so that when two audio device main bodies of the audio device are connected, the two audio device main bodies can be detached more conveniently; meanwhile, when the first audio device main body is connected with the programming device, the first audio device main body and the programming device can be detached conveniently.

In one embodiment, the structure of the third port is the same as the structure of the second port, and the structure of the second port corresponds to the structure of the first port.

In this embodiment, the third port is a port of the audio programming device, the second port is a port of the second audio device main body, and the two port blocks have the same structure, that is, the two ports are set to be the same, so that the port of the first audio device main body can be multiplexed, and thus, it is not easy for a user to perceive that the audio device is used for programming, which is convenient for the user to accept and improve user experience.

In one embodiment, the first port includes a first sub-port corresponding to the second port and a second sub-port corresponding to the third port.

In this embodiment, the first port includes two sub-ports, so that the first audio device main body is connected to the second audio device main body and the programming device respectively, so that a tester can debug and listen to audio conveniently, a program programming result of the programming device is quickly obtained through the audio, and efficiency of a program programming process is improved.

In one embodiment, the bayonet shape of the first subport does not correspond to the bayonet shape of the second subport; the first sub-port has a bayonet shape corresponding to the bayonet shape of the second port, and the second sub-port has a bayonet shape corresponding to the third port.

In this embodiment, the two sub-ports on the first port, through different bayonet shapes, can prevent the problem of misconnection when second audio device main part and programming device are connected with the first audio device main part, promote the connection efficiency and the rate of accuracy of second port and third port and these two sub-ports.

In one embodiment, the first sub-port includes a first number of first connectors and the second sub-port includes a second number of second connectors.

In this embodiment, the two sub-ports of the first port respectively include connectors, which facilitates connection and communication between the first audio device body and the second audio device body and between the first audio device body and the programming device.

In one embodiment, the height of the first connector is different from the height of the second connector.

In this embodiment, the connector sub-ports of the second audio device main body and the programming device can be quickly distinguished by the different heights of the connectors of the two sub-ports on the first port, so that the port connection efficiency and accuracy are improved.

In one embodiment, the audio device is a hearing aid, the first audio device body is a hearing aid body, the second audio device body is a receiver body, and the programming device is a programmer.

In this embodiment, by refining the specific entities of each device, the functions of the devices can be conveniently implemented on the corresponding entities.

A programming device is connected with an audio device, the audio device comprises a first port and a second port, the programming device comprises a third port, the first port is respectively connected with the second port and the third port, and the structure of the first port corresponds to that of the third port.

The programming device is connected with an audio device comprising a first port and a second port, the programming device comprises a third port, and the third port corresponds to the first port in structure, so that the connection and data transmission between the audio device and the programming device can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structures to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device for managing the wireless communication module fails.

An audio system comprises the audio device and the programming device.

The audio system comprises the audio device with the first port and the second port and the programming device with the third port, and the third port corresponds to the first port in structure, so that the connection and data transmission between the audio device and the programming device can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structure to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device or software for managing the wireless communication module fails.

Drawings

FIG. 1 is a diagram illustrating an example of the structure of an audio device and programming device provided in one embodiment;

fig. 2 is a diagram showing a configuration example of a first port of an audio apparatus provided in another embodiment;

fig. 3 is a diagram showing a configuration example of a first port of an audio apparatus provided in another embodiment;

description of reference numerals:

an audio device: 10;

a first audio device main body: 101, a first electrode and a second electrode;

a first port: 102, and (b);

a first sub-port: 1021;

a second subport: 1022;

a second audio device main body: 103;

a second port: 104;

a programming device: 20;

a programming device main body: 201;

a third port: 202.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection or a removable connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

At present, in order to perform functions such as debugging and firmware upgrading on a hearing aid, in the conventional technology, a shell of the hearing aid is generally opened to expose a programming port on a circuit board inside the hearing aid, and then a wired programmer is used for connecting the hearing aid with the hearing aid through the programming port to complete programming of a hearing aid program, so that the debugging and firmware upgrading functions are realized; however, this is cumbersome and may result in a broken snap structure of the hearing aid housing during opening, and requires re-fitting of the hearing aid after programming is complete, which also increases the amount of maintenance personnel. In order to solve the problem, a wireless communication module is generally arranged in the hearing aid, so that debugging and upgrading software can be sent to the wireless communication module of the hearing aid in a wireless communication mode at a computer end when the hearing aid is debugged and upgraded, the debugging and upgrading software is sent to a processor in the hearing aid by the wireless communication module of the hearing aid, and finally, the debugging and upgrading of the firmware of the hearing aid are completed by the processor according to the debugging and upgrading software; however, when the hearing aid is debugged and firmware is upgraded by using the technology, if the wireless communication module of the hearing aid fails or the device or software for managing the wireless communication module fails, it is difficult to ensure that the hearing aid realizes the debugging and firmware upgrading functions. Certainly, the existing hearing aid is also provided with a programming port arranged near a battery compartment, when wired programming is needed, the battery compartment is opened to expose the programming port so as to realize connection, but at present, most of batteries of the existing hearing aids are basically rechargeable, and the battery compartment cannot be opened generally, so that difficulty is brought to wired programming; and the increased number of interfaces also presents design difficulties due to the small size of the hearing aid. Based on this, embodiments of the present application provide an audio device, a programming device, and an audio system, which may solve the above technical problems.

Fig. 1 is a schematic diagram of the basic structure of an audio device and a programming device in one embodiment. Referring to fig. 1, the audio device 10 includes a first audio device body 101, a first port 102, a second audio device body 103, and a second port 104; the second port 104 is connected to the first port 102 and the second audio device main body 103, respectively; said first port 102 is connected to a programming device 20, said programming device 20 comprising a third port 202; the first port 102 is connected to the third port 202, and the configuration of the first port 102 corresponds to the configuration of the third port 202; when the programming device 20 communicates with the audio device, the communication signal transmitted by the programming device 20 is transmitted to the audio device through the third port 202 and the first port 102.

The shape of the first audio device main body 101 may be set according to actual conditions, and may be, for example, a cube, a rectangular parallelepiped, a sphere formed by an oval, or the like. Accordingly, the shape of the second audio device main body 103 may be set according to actual conditions, and may be, for example, a common earphone shape, a microphone shape, or the like.

The first port 102 may be disposed on the first audio device main body 101, so as to reduce the volume of the audio device main body and facilitate the carrying of the audio device; here, the first port 102 is provided in the first audio device main body 101, and it is understood that the first audio device main body 101 is integrated with the first port 102, and the first port 102 is opened on one side of the first audio device main body 101. Meanwhile, the first port 102 may be exposed outside the main body of the audio device, so that the audio device may be connected to the programming device 20 without being detached, the housing of the audio device may be protected, and the service life of the audio device may be prolonged.

The second port 104 is connected to the first port 102 and the second audio device main body 103, respectively, that is, the second audio device main body 103 and the first audio device main body 101 are connected through the second port 104 and the first port 102, where the second port 104 and the first port 102 may be fixedly connected or detachably connected.

In addition, the second port 104 is a port corresponding to the second audio device main body 103, the second port 104 and the second audio device main body 103 may be connected in a wired connection manner, that is, may be connected by a wire, and the wire may be covered with a hose or a hard tube to protect the wire.

The programming device 20 includes a third port 202 and a programming device main body 201, the programming device main body 201 may be, for example, a writer (hereinafter, both may be referred to as a programming device), the third port 202 may be disposed on the programming device 20 and connected to the programming device main body 201, and the connection mode may also be a wired connection, that is, the connection mode may be a connection through one electric wire, and the outside of the electric wire may be covered with a hose, a hard tube, or the like to protect the electric wire. Of course, the programming device 20 may further include another port, and the another port may be used to connect with a computer device or the like so as to receive a debugging program or a firmware upgrading program or the like sent by the computer device.

The audio device and the programming device 20 can be connected through the first port 102 and the third port 202, where the structure of the first port 102 corresponds to the structure of the third port 202, so that the programming device 20 and the first audio device main body 101 can be connected through the first port 102 and the third port 202. The corresponding structure here refers to two structures that can be connected to each other, for example, a corresponding structure may be composed of a male terminal and a female terminal as in the existing socket, and the male and female structures of the first port 102 and the third port 202 may be set arbitrarily, for example, the first port 102 may be a male terminal structure, the third port 202 may be a female terminal structure, and so on.

In the process of actually using the audio device, if the first audio device main body 101 and the second audio device main body 103 need to transmit audio data, the first port 102 and the second port 104 can be connected, so that the audio data sent by the first audio device main body 101 can be transmitted to the second audio device main body 103 through the first port 102 and the second port 104, and then the user can hear the audio data through the second audio device main body 103.

Similarly, if the programming device 20 needs to communicate with the audio device, the connection can be made through the first port 102 and the third port 202, so that the communication signal sent by the programming device 20 can be transmitted to the audio device, i.e., the first audio device main body 101, through the third port 202 and the first port 102. The communication signal here may be a communication signal constituted by a debugging program, a firmware upgrade software package program, or the like, which the programming device 20 debugs the audio device.

It should be noted that, here, the first port 102 may be connected to the second port 104 and the third port 202 at the same time, that is, the first port 102 includes two sub-ports that may be connected to the second port 104 and the third port 202, respectively. Here, the first port 102 includes two sub-ports, which may facilitate simultaneous connection of the second audio device body 103 and the programming device 20 with the first audio device body 101.

Of course, the first port 102 may include one sub-port, and the second port 104 and the third port 202 may be multiplexed, so that when the connection is performed, the third port 202 may be detached from the connection when the first port 102 is connected to the second port 104, or the second port 104 may be detached from the connection when the first port 102 is connected to the third port 202. Here, the first port 102 includes one sub-port, and the second audio device main body 103 and the programming device 20 share the same sub-port, so that the hardware cost of the whole audio device can be saved.

Alternatively, the audio device may be a hearing aid, the first audio device main body 101 may be a hearing aid main body, the second audio device main body 103 may be a receiver main body, and the programming device 20 may be a programmer. The detailed entities of each device are detailed here, and the functions of the devices can be conveniently realized on the corresponding entities.

The audio device in the embodiment comprises a first audio device body, a second audio device body, a first port and a second port, wherein the second port is respectively connected with the first port and the second audio device body; when the programming device is communicated with the audio device, the communication signal sent by the programming device is transmitted to the audio device through the third port and the first port. In the audio device, because the first port structure corresponds to the third port structure, the connection between the audio device and the programming device and the data transmission can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structures to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device for managing the wireless communication module fails.

In another embodiment, in addition to the above embodiment, the first port 102 is detachably connected to the second port 104, and the third port 202 is detachably connected to the first port 102.

Here, the first port 102 and the second port 104 are detachably connected, that is, the first audio device body and the second audio device body are detachably connected; here, the first port 102 is detachably connected to the third port 202, that is, the first audio device body is detachably connected to the programming device body.

The detachable connection here may comprise a screw connection, a snap connection, a bayonet connection, a hinge connection or the like. Here, the connection between the first port 102 and the second port 104 may be the same as or different from the connection between the first port 102 and the third port 202. Preferably, the present embodiment is generally configured in the same connection manner, for example, all connection manners are bayonet connection manners, so that the connection between the ports is facilitated and the difference is not easily perceived by a user, thereby improving the user experience and contributing to reducing the manufacturing cost.

In this embodiment, the first port, the second port and the third port are detachably connected, so that when two audio device main bodies of the audio device are connected, the two audio device main bodies can be detached more conveniently; meanwhile, when the first audio device main body is connected with the programming device, the first audio device main body and the programming device can be detached conveniently.

In another embodiment, in addition to the above-described embodiments, the structure of the third port 202 is the same as that of the second port 104, and the structure of the second port 104 corresponds to that of the first port 102.

Here, the third port 202 is a port of an audio programming device, the second port 104 is a port of a second audio device body, and the structure of the third port 202 is the same as that of the second port 104, which means that the shapes of the two ports or the connection structures inside the ports are the same, that is, the two ports are the same port, and both can be connected with the same first port 102, so as to realize the function of multiplexing the first port 102.

In addition, the structure of the second port 104 corresponds to the structure of the first port 102, and may correspond to the structure of the first port 102 and the structure of the third port 202, where the structure corresponds to two structures that can be connected to each other, for example, a structure corresponding to an existing socket may be composed of a male plug and a female plug, where the male and female structures of the first port 102 and the second port 104 may be arbitrarily set, for example, the first port 102 may be a male plug structure, the second port 104 may be a female plug structure, and so on.

In this embodiment, the third port is a port of the audio programming device, the second port is a port of the second audio device main body, and the two port blocks have the same structure, that is, the two ports are set to be the same, so that the port of the first audio device main body can be multiplexed, and thus, it is not easy for a user to perceive that the audio device is used for programming, which is convenient for the user to accept and improve user experience.

In another embodiment, a basic structure diagram of the first port 102 of the audio device is provided, and referring to fig. 2, the first port 102 includes a first sub-port 1021 and a second sub-port 1022, the first sub-port 1021 corresponds to the second port 104, and the second sub-port 1022 corresponds to the third port 202.

The structure of the first sub-port 1021 and the structure of the second sub-port 1022 may be the same or different. The shape of the first sub-port 1021 and the shape of the second sub-port 1022 may be the same or different. Preferably, the structure and shape of the first sub-port 1021 and the second sub-port 1022 are the same, so that the structural change of the audio device is not easily perceived by a user, and the user experience is improved. The shape of the first sub-port 1021 and the shape of the second sub-port 1022 may be set according to practical situations, and may be, for example, a rectangle, a circle, an ellipse, a square, a goat-horn shape, and the like.

Here, the first sub-port 1021 is used for connection with the second port 104, that is, connection of the first audio device main body and the second audio device main body is achieved. The first sub-port 1021 corresponds to the second port 104, so that when the first audio device main body and the second audio device main body are connected, seamless connection between the two device main bodies can be realized, and a user can hear audio data transmitted by the first audio device main body through the second audio device main body.

Here, the second sub-port 1022 is used for connection with the third port 202, i.e., connection of the first audio device main body and the programming device is achieved. The second sub-port 1022 corresponds to the third port 202, so that when the first audio device main body is connected to the programming device, seamless connection between the two audio devices and the programming device can be realized, the audio device can communicate with the programming device, a communication signal sent by the programming device can be transmitted to the audio device, and functions of debugging, firmware upgrading and the like of the audio device can be realized.

In this embodiment, the first port includes two sub-ports, so that the first audio device main body is connected to the second audio device main body and the programming device respectively, so that a tester can debug and listen to audio conveniently, a program programming result of the programming device is quickly obtained through the audio, and efficiency of a program programming process is improved.

In another embodiment, in addition to the above embodiment, the bayonet shape of the first sub-port 1021 does not correspond to the bayonet shape of the second sub-port 1022; the first sub-port 1021 has a bayonet shape corresponding to the bayonet shape of the second port 104, and the second sub-port 1022 has a bayonet shape corresponding to the third port 202.

Here, the bayonet shape of the first sub-port 1021 and the bayonet shape of the second sub-port 1022 do not correspond to each other, so that the two sub-ports can be distinguished conveniently and quickly, a second audio device body and a programming device are prevented from being mistakenly connected with the first audio device body (for example, being plugged into the wrong sub-port), and the connection efficiency and accuracy of the second port 104 and the third port 202 with the two sub-ports are improved.

For example, here, the bayonet shape of the first sub-port 1021 and the bayonet shape of the second sub-port 1022 may be any one of a triangle, a square, a rectangle, a trapezoid, an arch, a circle, an ellipse, and the like, as long as the bayonet shape of the first sub-port 1021 and the bayonet shape of the second sub-port 1022 do not correspond, i.e., are not the same bayonet shape.

In addition, the bayonet shape of the first sub-port 1021 and the bayonet shape of the second port 104 correspond to each other, which may facilitate connection of the first audio device main body and the second audio device main body. The bayonet shape of the second sub-port 1022 corresponds to the bayonet shape of the third port 202, which may facilitate the connection of the first audio device body and the programming device.

In this embodiment, the two sub-ports on the first port, through different bayonet shapes, can prevent the problem of misconnection when second audio device main part and programming device are connected with the first audio device main part, promote the connection efficiency and the rate of accuracy of second port and third port and these two sub-ports.

In another embodiment, a basic structure diagram of the first port 102 of another audio device is provided, and referring to fig. 3, on the basis of the above embodiment, the first sub-port 1021 includes a first number of first connectors, and the second sub-port 1022 includes a second number of second connectors.

The connector may be a pin on the sub-port, and the first number and the second number of the pin on the two sub-ports may be equal or may not be equal. Preferably, the first number and the second number are equal, so that the structural change on the first port 102 of the audio device is not easily perceived by the user, and the use experience of the user is improved. Likewise, the second port 104 and the third port 202 may include receptacles thereon corresponding to the pins on the respective sub-ports.

In addition, two connectors formed from pin pins typically have a height, a logo, and the like. As for the height of the connector, optionally, the height of the first connector and the height of the second connector are different. Here, the heights of the pins in the first connector are generally the same, and the heights of the pins in the second connector are generally the same, that is, the heights of the pins in the first connector are different from the heights of the pins in the second connector, which facilitates hardware design and appearance.

As to the identifier of the connector, optionally, the identifier of the first connector and the identifier of the second connector are different. The identification may include a type, a code, an insertion direction, and the like of the connector, where the insertion direction refers to a direction in which each jack on the port is inserted into the first sub-port 1021 or the second sub-port 1022 when the second port 104 or the third port 202 is connected to the first sub-port 1021 or the second sub-port 1022.

In this embodiment, the two sub-ports of the first port respectively include connectors, which facilitates connection and communication between the first audio device body and the second audio device body and between the first audio device body and the programming device. In addition, through different heights and marks of the connectors of the two sub-ports on the first port, the second audio device main body and the connecting sub-ports of the programming device can be distinguished quickly, and the connecting efficiency and the accuracy of the ports are improved.

In the above embodiments, audio devices are described, wherein programming devices are also mentioned, which will be further described below.

In another embodiment, a programming device is provided, the programming device 20 is connected to an audio device 10, the audio device 10 includes a first port 102 and a second port 104, the programming device 20 includes a third port 202, the first port 102 is connected to the second port 104 and the third port 202, respectively, and the structure of the first port 102 corresponds to the structure of the third port 202.

For the port setting of the programming device 20, the port setting of the audio device 10, and the connection between the programming device 20 and the audio device 10, reference may be made to the description of the above embodiments, and details are not repeated here.

The programming device is connected with an audio device comprising a first port and a second port, the programming device comprises a third port, and the third port corresponds to the first port in structure, so that the connection and data transmission between the audio device and the programming device can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structures to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device for managing the wireless communication module fails.

The above embodiments describe audio devices and programming devices, wherein the audio devices and programming devices may be implemented as audio systems, which are further described below.

In another embodiment, an audio system is provided, said audio system comprising an audio apparatus 10 as described above and a programming apparatus 20 as described above.

Here, the audio device 10 and the programming device 20 can be connected, and for details of the programming device 20 and the audio device 10 in the audio system, reference may be made to the description of the above embodiments, which are not described herein again.

The audio system comprises the audio device with the first port and the second port and the programming device with the third port, and the third port corresponds to the first port in structure, so that the connection and data transmission between the audio device and the programming device can be realized through the two ports; in addition, because the communication signal of the programming device can be transmitted to the audio device through the first port and the third port corresponding to the structures to realize the firmware upgrading function of the audio signal without the participation of a wireless communication module of the audio device, the audio device can be ensured to realize the firmware upgrading function even if the wireless communication module of the audio device fails or a device for managing the wireless communication module fails.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An audio device, characterized in that the audio device comprises a first audio device body, a first port, a second audio device body and a second port; the second port is connected with the first port and the second audio device main body respectively;

the first port is connected with a programming device, and the programming device comprises a third port; the first port is connected with the third port, and the structure of the first port corresponds to that of the third port;

when the programming device is communicated with the audio device, the communication signal sent by the programming device is transmitted to the audio device through the third port and the first port.

2. The audio device as claimed in claim 1, wherein the first port is detachably connected to the second port, and the third port is detachably connected to the first port.

3. The audio device of claim 2, wherein the structure of the third port is the same as the structure of the second port, the structure of the second port corresponding to the structure of the first port.

4. The audio device according to claim 3, wherein the first port comprises a first sub-port and a second sub-port, the first sub-port corresponding to the second port, the second sub-port corresponding to the third port.

5. The audio device of claim 4, wherein the bayonet shape of the first sub-port does not correspond to the bayonet shape of the second sub-port; the bayonet shape of the first sub-port corresponds to the bayonet shape of the second port, and the bayonet shape of the second sub-port corresponds to the third port.

6. The audio device of claim 5, wherein the first sub-port comprises a first number of first connectors and the second sub-port comprises a second number of second connectors.

7. The audio device of claim 6, wherein a height of the first connector and a height of the second connector are different.

8. The audio device according to any one of claims 1 to 7, wherein the audio device is a hearing aid, the first audio device body is a hearing aid body, the second audio device body is a receiver body, and the programming device is a writer.

9. A programming device is characterized in that the programming device is connected with an audio device, the audio device comprises a first port and a second port, the programming device comprises a third port, the first port is respectively connected with the second port and the third port, and the structure of the first port corresponds to that of the third port.

10. An audio system, characterized in that the audio system comprises the audio apparatus of any one of claims 1-8 and the programming apparatus of claim 9.

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