WO2024198125A1 - Method for realizing intelligent voice interaction carried on sound-valley matrix - Google Patents

Abstract

The present invention provides a method for realizing intelligent voice interaction carried on a sound-valley matrix. The sound-valley matrix comprises a plurality of bar-shaped sound-producing loudspeaker apparatus units and at least one connecting component. Two adjacent bar-shaped sound-producing loudspeaker apparatus units are adapted to connect together by means of the connecting component so as to extend and expand bar-shaped sound-producing faces of the plurality of bar-shaped sound-producing loudspeaker apparatus units. The sound-valley matrix further comprises one microphone unit, and the microphone unit is adapted to be installed on the connecting component, and is adapted to receive a user instruction and to realize voice interaction by means of an AI module.

Description

Implementation method of intelligent voice interaction equipped with sound valley matrix Technical Field

The present invention relates to the field of human-computer voice interaction, and in particular to a method for realizing intelligent voice interaction based on a sound valley matrix formed by a linear sound-generating sound device.

Background Art

In recent years, the development of artificial intelligence (AI) technology has become increasingly mature, and people's demand for intelligent voice interaction has also increased. Intelligent voice interaction is not only used in smart speakers, smart homes and other fields, but has also gradually penetrated into more fields such as medical care, finance, and education. However, in existing intelligent voice interaction systems, the problem of output sound quality still exists, especially in noisy environments, the accuracy of voice recognition and the clarity of voice are greatly reduced.

In traditional speaker systems, the quality of sound depends largely on the quality of the speaker, while the size of the speaker directly affects the efficiency of space utilization. However, traditional speakers usually use point-like sound generation through voice coil vibration, which cannot provide continuous surface sound generation. In a complex environment, the interactive function of traditional intelligent voice interaction is limited by the speaker sound generation principle and the use space.

Summary of the invention

One advantage of the present invention is that it provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a speaker device that emits linear sound. The method for implementing intelligent voice interaction based on a sound valley matrix formed by a speaker device that emits linear sound can achieve a planar sound effect extending along the linear surface and has the function of intelligent voice interaction.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device. The method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device can interact with artificial intelligence (AI), which is conducive to the implementation of spatialized intelligent scenes.

Another advantage of the present invention is to provide a sound valley moment formed by a linear sound-generating speaker device. The invention discloses a method for realizing intelligent voice interaction equipped with an array. The method for realizing intelligent voice interaction equipped with a sound valley matrix formed by a speaker device based on linear sound emission can be conveniently set in various corners of the space, and cooperate with the principle of planar sound emission to provide a more three-dimensional and multi-faceted sound effect.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction using a sound valley matrix formed by a speaker device based on linear sound. The method provides a surface sound effect in a line sound field through a strip diaphragm, so as to achieve more three-dimensional and multi-faceted sound propagation in the air and can play mono or multi-channel sound source sound effects.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction using a sound valley matrix formed by a speaker device that emits linear sound. The method for implementing intelligent voice interaction using a sound valley matrix formed by a speaker device that emits linear sound generates sound through a strip diaphragm along the linear sounding surface to avoid mutual signal interference.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device. The method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device can be detachably arranged around or near a smart product to emit a more spatial sound effect, giving the user an improved sound experience.

Another advantage of the present invention is that it provides a method for implementing a sound valley matrix formed by a linear sound-emitting speaker device and equipped with intelligent voice interaction. The method for implementing a sound valley matrix formed by a linear sound-emitting speaker device and equipped with intelligent voice interaction can detachably connect the speaker units and the connecting components to each other to enhance its expandability and unlimited extension.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction with a sound valley matrix formed by a linear sound-emitting speaker device. The method for implementing intelligent voice interaction with a sound valley matrix formed by a linear sound-emitting speaker device can be applied to various scenarios to determine the distance between users and select a microphone for sound collection and interaction.

Another advantage of the present invention is that it provides a method for implementing a sound valley matrix formed by a linear sound-emitting speaker device and equipped with intelligent voice interaction. The method for implementing a sound valley matrix formed by a linear sound-emitting speaker device and equipped with intelligent voice interaction can distinguish the frequency of the emitted sound through a divider, set the bass part to a device suitable for bass output, and set the mid-high frequency part to a device suitable for mid-high frequency output, so as to give full play to the sound effect characteristics of each part.

Another advantage of the present invention is to provide a sound valley moment formed by a linear sound-generating speaker device. The method for realizing intelligent voice interaction equipped with an array, the method for realizing intelligent voice interaction equipped with a sound valley matrix formed by a speaker device based on linear sound generation can realize the splicing between the speaker units through various types of connecting components, realize different patterns and shapes, and form different sound field effects, thereby realizing the sound generation effects of various surface sound sources.

Another advantage of the present invention is that it provides a method for implementing a sound valley matrix formed by a speaker device based on a linear sound body and equipped with intelligent voice interaction. The method for implementing a sound valley matrix formed by a speaker device based on a linear sound body and equipped with intelligent voice interaction can simultaneously realize the working effects of the diaphragm sounding of a dynamic speaker and the planar diaphragm sounding or the electrostatic diaphragm sounding, thereby utilizing the diaphragm sounding of the dynamic speaker to compensate for the insufficient bass of the planar diaphragm sounding or the electrostatic diaphragm sounding to achieve a more full-frequency sound effect and reduce costs.

Another advantage of the present invention is that it provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device. The method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-emitting speaker device can be combined with light strips with different luminous effects to achieve different sound effects corresponding to different luminous effects, thereby bringing strong sound and light interactivity to users.

According to one aspect of the present invention, the present invention provides a method for implementing intelligent voice interaction with a sound valley matrix, which comprises the following steps:

(A) Arranging one or more sound valley matrices, each of the sound valley matrices comprising:

Multiple linear sound-emitting speaker units;

At least one connecting member, two adjacent linear sound-emitting speaker units are suitable for being connected through the connecting member so that the linear sound-emitting surfaces of the plurality of linear sound-emitting speaker units can be extended and expanded;

at least one microphone unit; and

1. AI module;

(B) receiving voice commands from the microphone unit;

(C) transmitting a signal to the AI module;

(D) The AI module controls the speaker unit to emit sound to feed back information to the user.

According to an embodiment of the present invention, the AI module accesses real-time information on the network and emits sound through the speaker unit to feed back information to the user.

According to an embodiment of the present invention, the AI module searches for answer information corresponding to the voice command on the network, and emits sound through the speaker unit to feed back the information to the user.

According to one embodiment of the present invention, the AI module performs network operations corresponding to the voice command. Shopping, and the speaker unit emits sound to feedback information to the user.

According to an embodiment of the present invention, the AI module plays the multimedia information from the network through the speaker unit based on the voice command.

According to one embodiment of the present invention, the AI module makes a call based on the voice instruction.

According to one embodiment of the present invention, the AI module sends an email based on the voice instruction.

According to one embodiment of the present invention, the step is further included: the AI module controls the operation of the electronic device after receiving the signal, wherein the electronic device is a household device or an office device.

According to one embodiment of the present invention, the step is further included: determining the user's position to select the sound valley matrix of a neighboring user for voice interaction.

According to an embodiment of the present invention, the method further includes providing a lighting effect through a light source to achieve a sound and light synchronization effect.

The present invention also provides a sound valley matrix equipped with an intelligent voice interaction function, which includes:

Multiple linear sound-emitting speaker units;

At least one connecting member, two adjacent linear sound-emitting speaker units are suitable for being connected through the connecting member so that the linear sound-emitting surfaces of the plurality of linear sound-emitting speaker units can be extended and expanded;

a microphone unit; and

An AI module controls the speaker unit to emit sound to feed back information to the user.

According to an embodiment of the present invention, the connecting component includes a connecting shell, the connecting shell provides an installation space, and the microphone unit is suitable for being installed in the connecting shell to receive a user's voice signal instruction.

According to one embodiment of the present invention, the linear sound-emitting speaker device unit includes a shell, at least one strip diaphragm and at least one magnet assembly, the shell provides an installation space, the strip diaphragm and the magnet assembly are suitable for being installed in the shell, the strip diaphragm and the magnet assembly are arranged in parallel with each other, and when the strip diaphragm responds to the input of the sound source current signal, it vibrates under the action of the magnet assembly to produce sound effects.

According to one embodiment of the present invention, the magnet of the magnet assembly forms a magnetic pole surface facing the strip diaphragm, the strip diaphragm has a diaphragm surface facing the magnet assembly, the magnetic pole surface and the diaphragm surface are parallel to each other, and the linear extension direction of the magnet arrangement is staggered with the extension direction of the linear circuit.

According to one embodiment of the present invention, the linear sound-emitting speaker unit comprises a shell, at least one strip diaphragm and two driving electrodes, which are located on opposite sides of the strip diaphragm and drive the strip diaphragm implemented as an electrostatic diaphragm by changing polarity through voltage conversion.

According to an embodiment of the present invention, the housing includes a tubular outer shell and a bracket, and the strip-shaped diaphragm and the magnet assembly are mounted on the bracket and are located in the tubular outer shell.

According to one embodiment of the present invention, the bracket includes a base and a fixed frame, the magnet assembly is installed on the base, the strip diaphragm is installed on the fixed frame, and a vibration space is formed between the strip diaphragm and the base, the base has one or more air holes, and a connecting space is formed on the bottom side of the base, wherein the vibration space and the connecting space are connected through the air holes.

According to one embodiment of the present invention, it also includes one or more dynamic speakers, which are installed on the shell to respond to the input of the sound source current signal together with the strip diaphragm to simultaneously produce sound effects. When the linear sound-emitting speaker device includes a plurality of the dynamic speakers, the plurality of speakers formed by the dynamic speakers and the strip diaphragm are alternately arranged linearly.

According to one embodiment of the present invention, it also includes a subwoofer sound effect device, and also includes a crossover to input bass sound signals into the subwoofer sound effect device and mid-high frequencies into the linear sound-emitting speaker device unit, wherein the AI module is installed in the subwoofer device.

According to another aspect of the present invention, the present invention also provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-generating speaker device, comprising the following steps: (a1) user outputs instructions; (b1) receives instructions from a microphone unit; (c1) transmits signals to an AI module; (d1) accesses real-time information on the network; and (e1) feeds back information to the user.

According to one embodiment of the present invention, the step (d1) further includes the following steps: (d13) performing operations on behalf of the user.

According to an embodiment of the present invention, the step (e1) further includes the following steps: (e11) outputting to the user via voice.

According to an embodiment of the present invention, the step (e1) further includes the following steps: (e12) outputting light effects to the user to prompt the user.

According to another aspect of the present invention, the present invention provides a method for implementing intelligent voice interaction based on a sound valley matrix formed by a linear sound-generating speaker device, comprising the following steps: (a2) user outputs instructions; (b2) receives instructions from a microphone unit; (c2) transmits signals to an AI module; (d2) accesses real-time information on the network; (e2) learns user demand knowledge; and (f2) outputs feedback to the user.

According to one embodiment of the present invention, the step (e2) further includes the following steps: (e21) understanding user habits and filtering according to user habits.

According to an embodiment of the present invention, the step (f2) further includes the following steps: (f21) asking the user for additional requirements; and (f22) customizing a dedicated plan and providing feedback to the user.

According to another aspect of the present invention, the present invention provides a method for implementing intelligent voice interaction using a sound valley matrix formed by a linear sound-generating speaker, comprising the following steps: (a3) user outputting instructions; (b3) receiving instructions at a microphone unit; (c3) transmitting signals to an AI module; (d3) processing information; (e3) determining the user's position; (f3) transmitting to one of the sound valley matrices according to the user's position; and (g3) transmitting information through a predetermined sound valley matrix.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is an overall schematic diagram of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to a preferred embodiment of the present invention.

2 is an exploded schematic diagram of the sound valley matrix formed by the linear-type sound-generating speaker device according to the preferred embodiment of the present invention equipped with intelligent voice interaction.

3 is a side perspective view of the sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention, equipped with intelligent voice interaction.

4 is a schematic diagram of a strip-shaped diaphragm equipped with intelligent voice interaction in a sound valley matrix formed by a speaker device based on linear sound generation according to the preferred embodiment of the present invention.

5 is a schematic diagram of the installation status of the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction according to the preferred embodiment of the present invention.

6 is a schematic diagram of the installation status of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the second preferred embodiment of the present invention.

7 is an exploded schematic diagram of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the third preferred embodiment of the present invention.

8 is a schematic diagram of the installation status of the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction according to the preferred embodiment of the present invention.

FIG9 is a schematic diagram of one of the usage scenarios of the sound valley matrix formed by the linear sound-generating speaker device according to the above preferred embodiment of the present invention equipped with intelligent voice interaction.

FIG. 10 is a diagram of a speaker device based on a linear sound source according to the preferred embodiment of the present invention. The second schematic diagram of the usage scenarios of the completed Sound Valley Matrix equipped with intelligent voice interaction.

11 is a third schematic diagram of a usage scenario of the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction according to the above-mentioned preferred embodiment of the present invention.

12 is a schematic diagram of the installation status of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the fourth preferred embodiment of the present invention.

13 is a schematic diagram of an explosion state of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the fifth preferred embodiment of the present invention.

14 is a side perspective view of the sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention, equipped with intelligent voice interaction.

Figure 15 is a schematic diagram of a strip-shaped diaphragm equipped with intelligent voice interaction in a sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention.

16 is a schematic diagram of an explosion state of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the sixth preferred embodiment of the present invention.

Figure 17 is a schematic diagram of a strip-shaped diaphragm equipped with intelligent voice interaction in a sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention.

18 is a schematic diagram of an explosion state of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the seventh preferred embodiment of the present invention.

Figure 19 is a side perspective view of the sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention, equipped with intelligent voice interaction.

Figure 20 is an overall schematic diagram of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the eighth preferred embodiment of the present invention.

Figure 21 is a side perspective view of the sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention, equipped with intelligent voice interaction.

Figure 22 is an exploded schematic diagram of the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction according to the preferred embodiment of the present invention.

Figure 23 is a side perspective view of the sound valley matrix formed by the linear sound-generating speaker device according to the preferred embodiment of the present invention, equipped with intelligent voice interaction.

Figure 24 is a side perspective view of a sound valley matrix formed by a speaker device based on linear sound generation and equipped with intelligent voice interaction according to the ninth preferred embodiment of the present invention.

FIG. 25 is a diagram of a speaker device based on a linear sound source according to a preferred embodiment of the present invention. Schematic diagram of the explosion of the Sound Valley Matrix equipped with intelligent voice interaction.

DETAILED DESCRIPTION

The following description is used to disclose the present invention so that those skilled in the art can implement the present invention. The preferred embodiments described below are only examples, and those skilled in the art may think of other obvious variations. The basic principles of the present invention defined in the following description may be applied to other embodiments, variations, improvements, equivalents, and other technical solutions that do not deviate from the spirit and scope of the present invention.

Those skilled in the art should understand that, in the disclosure of the present invention, the orientation or position relationship indicated by the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside", etc. are based on the orientation or position relationship shown in the drawings, which are only for the convenience of describing the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operate in a specific orientation. Therefore, the above terms should not be understood as limiting the present invention.

It is to be understood that the term "one" should be understood as "at least one" or "one or more", that is, in one embodiment, the number of an element may be one, while in another embodiment, the number of the element may be multiple, and the term "one" should not be understood as a limitation on the quantity.

As shown in Figures 1 to 5, a sound valley matrix formed by a speaker device based on linear sound emission according to a preferred embodiment of the present invention is illustrated. The sound valley matrix formed by the speaker device based on linear sound emission has the function of surface sound emission. Compared with the traditional voice coil sound emission device, the sound valley matrix formed by the speaker device based on linear sound emission changes from point sound emission to surface sound emission. The sound valley matrix formed by the speaker device based on linear sound emission realizes surface sound emission through the arrangement of linear diaphragms and circuits. The sound valley matrix formed by the speaker device based on linear sound emission is suitable for being arranged around or near various smart digital products and users to achieve the sound effect of three-dimensional surface sound emission.

The sound valley matrix formed by the speaker device based on the linear sound generation includes a plurality of speaker device monomers 1 for linear sound generation and one or more connecting components 9. The speaker device monomer 1 for linear sound generation is suitable for providing the function of surface sound generation. The connecting component 9 is suitable for providing the function of connecting two adjacent speaker device monomers 1 for linear sound generation. In other words, the speaker device monomer 1 for linear sound generation is connected to another speaker device monomer 1 for linear sound generation through the connecting component 9. The connecting component 9 is suitable for providing various connection methods to connect a plurality of speaker device monomers 1 for linear sound generation. The connecting component 9 receives the speaker device monomers 1 for linear sound generation on both sides and is installed in a fixed or detachable manner. Installed on the side of the smart product to achieve a three-dimensional multi-faceted sound effect. In this embodiment, an exemplary connection method of the connection member 9 is introduced, and the connection form of the connection member 9 is not limited by the present invention.

More specifically, the linear sound-emitting speaker unit 1 includes a shell 10, a strip diaphragm 20 and a magnet assembly 30. The shell 10 provides an installation space. In this embodiment, the strip diaphragm 20 is implemented in a linear shape and is installed on the shell 10 along a linear direction to achieve the surface sound of the linear sound-emitting speaker unit 1. In addition, the magnet assembly 30 is also arranged in a linear direction. When the strip diaphragm 20 responds to the signal input of the sound source current, an electromagnetic field is generated, which generates an attraction or repulsion effect with the magnetic pole of the magnet assembly 30 to drive the strip diaphragm 20 to vibrate and produce sound effects.

The connecting member 9 is suitable for being installed on both sides of the housing 10 to maintain mutual connection. Further, in this embodiment, one end of the connecting member 9 is connected to one of the linear sound-emitting speaker units 1 by plugging, and the other end is plugged into another linear sound-emitting speaker unit 1. The connecting member 9 is suitable for setting a circuit unit and electrically connected to the strip diaphragm 20 to achieve electroacoustic conversion.

The strip diaphragm 20 includes a diaphragm base 21, a conductive circuit 22 and a group of wiring terminals 23. In the present embodiment, the diaphragm base 21 is implemented as a strip film, the material of the diaphragm base 21 is plastic and when the diaphragm base 21 is in a taut state, a planar diaphragm is formed. The conductive circuit 22 is implemented as a lightweight metal material, such as aluminum foil, in the present embodiment. The conductive circuit 22 is attached to the diaphragm base 21 and is located in the space above the magnet assembly 30 so as to be located in the magnetic field formed by the magnet assembly 30. A group of wiring terminals 23 are electrically connected to the conductive circuit 22 to provide electrical energy to the conductive circuit 22 and input a signal of a sound source current into the conductive circuit 22, thereby providing a current input for sound-to-electricity conversion.

In this embodiment, the conductive circuit 22 includes at least one linear circuit 221. The linear circuit 221 extends along the length direction of the strip diaphragm 20. That is to say, the linear circuit 221 extends along the length direction of the shell 10. And the linear circuit 221 is always located in the magnetic field environment of the magnet assembly 30. When the linear sound-emitting speaker unit 1 is installed, the linear circuit 221 is always located directly above the magnet assembly 30. When a sound source current signal is input to a set of the wiring terminals 23, an electromagnetic field is generated, which produces an attraction or repulsion effect with the magnetic poles of the magnet assembly 30 to drive the strip diaphragm 20 to vibrate and produce sound effects.

The magnet assembly 30 includes at least one magnet 31 arranged in a linear direction. In this embodiment, the magnet assembly 30 includes an integral long strip magnet. The magnet 21 can generate a magnetic field, and the magnet 21 itself has magnetic properties. The magnet 21 has the property of attracting ferromagnetic materials such as iron, nickel, cobalt and other metals. The magnet 21 can be implemented as a permanent magnet, or it can be a magnetized body with a certain magnetism after magnetization.

It is worth mentioning that the linear circuit 221 is disposed above the magnet 31, and the linear circuit 221 does not contact the magnet 31, so as to keep the linear circuit 221 under the magnetic field of the magnet 31. In other words, the magnetic assembly 30 generates a magnetic field to act on the linear circuit 221 and make the strip diaphragm 20 vibrate to generate sound effects.

In this embodiment, unlike traditional speakers, the linear sound-generating speaker unit 1 does not need to use a voice coil and drum paper to generate sound. The linear sound-generating speaker unit 1 enables the strip diaphragm 20 to vibrate and generate sound through the interaction of the magnetic field of the linear circuit 221 and the magnet assembly 30. And because the strip diaphragm and the magnet assembly 30 are both arranged in a linear shape. The expansion and extension direction of the sound effect is brought closer along the linear direction. And the strip diaphragm 20 generates sound on a linear surface and extends along the linear direction. Finally, a surface-type sound effect is formed, which is different from the point-like sound effect of traditional speakers. The sound effect of the linear sound-generating speaker unit 1 is more expandable, which is different from the sound of traditional speakers that are limited by the end face area of the voice coil and cannot expand the sound effect.

That is to say, the strip diaphragm 20 does not need to be connected to the driving structure of the voice coil. The magnet assembly 30 is arranged in a long strip shape below the strip diaphragm 20. The magnet assembly 30 provides a magnetic field direction that matches the strip diaphragm 20, so that the strip diaphragm 20 can effectively interact with the surrounding magnetic field. And the condition for emitting sound is only that the strip diaphragm 20 is located in the magnetic field environment of the magnet assembly 30. And different from the point-like sound-emitting structure of traditional speakers, the linear sound-emitting speaker device monomer 1 provided by the present invention is more likely to form a three-dimensional multi-faceted sound effect in space, and the sound based on the same linear surface can reduce mutual interference in the sound frequency band.

As shown in FIG4 , the linear circuit 221 is implemented as two rows of spaced-apart circuits. The magnet 31 is arranged between the two rows of the linear circuits 221. The linear circuit 221 is preferably located at a position where the magnetic field strength of the magnet 31 is the strongest. This makes the linear circuit 221 at a place where the effect of the driving action of the magnet 31 is the strongest. As shown in the figure, the linear circuit 221 is bent to provide two linear circuits 221, and the linear circuit 221 extends as a whole and is electrically connected to the wiring terminals 23 at both ends. And it is electrically connected to the circuit unit in the connecting member 9 through the wiring terminals 23. When the connecting member When the connecting member 9 is installed on both sides of the linear speaker unit 1 , the connection terminal 23 is hidden between the linear speaker unit 1 and the connecting member 9 .

In particular, the strip diaphragm 20 is implemented as a planar diaphragm, and the music signal is input in the form of an electric current, and the planar magnetic diaphragm interacts with the magnetic field to cause the diaphragm to reciprocate and generate sound waves. In another embodiment, the strip diaphragm 20 can also be implemented in the form of an electrostatic diaphragm. The strip diaphragm 20 can generate sound effects by electrostatically driving the diaphragm.

The housing 10 includes a shell 11 and a bracket 12. The strip diaphragm 20 and the magnet assembly 30 are assembled to the bracket 12. The shell 11 is implemented as a tubular shell. The shell 11 has a strip accommodating cavity 110. The strip accommodating cavity 110 is located inside the shell 11 and is in a hollow state to provide an installation space. The bracket 12, the strip diaphragm 20 and the magnet assembly 30 are all located inside the shell 11.

The strip diaphragm 20 and the magnet assembly 30 match the length of the housing 11. The cross-sectional shape of the tubular shell of the housing 11 is tubular or annular, and the cross-sectional shape of the housing 11 is not limited by the present invention. As long as the strip accommodating cavity 110 can be formed inside and accommodate the bracket 12, the strip diaphragm 20 and the magnet assembly 30, it is sufficient.

Specifically, the bracket 12 includes a base 121 and a fixing frame 122. The magnet 31 is fixed to the base 121, and the strip diaphragm 20 is fixed to the fixing frame 122. The base 121 also has a positioning groove 1211. The positioning groove 1211 is suitable for fixing the magnet 31. In other words, the shape of the positioning groove 1211 matches the shape of the magnet 31. In other words, the magnet 31 is suitable for being snapped into the positioning groove 1211. The fixing frame 122 extends and protrudes from the edge of the base 121 to keep the strip diaphragm 20 installed in the space above the magnet assembly 30.

The support 12 further has a vibration space 123, and the vibration space 123 is located between the strip-shaped diaphragm 20 and the base 121. In other words, the vibration space 123 is formed between the magnet assembly 30 and the strip-shaped diaphragm 20.

The support 12 also has a plurality of air holes 124 and a connecting space 125. The air holes 124 connect the vibration space 123 and the connecting space 125. When the strip diaphragm 20 vibrates, the air in the vibration space 123 is agitated to facilitate the propagation of air. In this embodiment, the vibration space 123 in the upper space of the base 121 is connected to the connecting space 125 on the bottom side of the base 121.

The strip diaphragm 20 forms a strip diaphragm surface 200 , and the magnet assembly 30 forms a magnetic pole surface 300 . Preferably, the strip-shaped diaphragm surface 200 and the magnetic pole surface 300 are maintained parallel to each other, and the magnetic field formed by the magnet assembly 30 acts on the strip-shaped diaphragm surface 200 .

The housing 10 includes an additional element 13, and the additional element 13 is used to fix the housing 10 to the surface of the environment. That is, the linear sound-emitting speaker unit 1 is fixed to the surface of the environment through the additional element 13. The additional element 13 can be various installation elements, such as screws, nuts and other snap-on structures. In this embodiment, the additional element 13 is arranged at the bottom of the housing 10, and the additional element 13 can also be arranged on both sides of the housing 10 to facilitate the installation of the linear sound-emitting speaker unit 1.

The linear sound-emitting speaker unit 1 may further include a light source 40. The light source 40 is suitable for providing a lighting effect to achieve a sound-light synchronization effect. The linear sound-emitting speaker unit 1 is suitable for achieving a sound-light coordination scene by matching different sound effects with different lighting effects, thereby providing users with a sound-light interactive experience.

More specifically, as shown in Figures 2 and 3, the light source 40 includes a pair of light strips 41. In this embodiment, the light strip 41 is implemented as an LED light-emitting element, and the light strip 41 can provide different colored light lighting effects according to the strength of the sound source current signal input by the strip diaphragm 20. Specifically, when the linear sound-emitting speaker unit 1 receives human voice input, the interactive effect of the voice can be fed back through the state change of the light source 40 to meet different application requirements. The light strip 41 is installed on both sides of the bottom of the base 121. The light strip 41 is arranged in the connecting space 125. The light source 40 can also be installed elsewhere, such as on the housing 11.

The housing 11 also has a plurality of through holes 111. The through holes 111 are arranged on the circumference of the housing 11 to connect the strip-shaped accommodating cavity 110 with the external space. The light effect emitted by the lamp source 40 can be projected to the outside through the through holes 111. The sound effect generated by the strip-shaped diaphragm 20 can also be output to the outside through the through holes 111.

Unlike traditional speakers, the linear sound-emitting speaker device monomers 1 can be combined with each other through the connecting member 9 for easy assembly. That is to say, the linear sound-emitting speaker device monomers 1 can be conveniently assembled by combining and assembling through the connecting member 9. In other words, the linear sound-emitting speaker device monomers 1 are combined into the sound valley matrix formed by the linear sound-emitting speaker device through the connecting member 9. Through the mutual combination of the linear sound-emitting speaker device monomers 1 and the connecting member 9, the sound valley matrix formed by the linear sound-emitting speaker device can be detachably connected to each other and can be detachably installed at a predetermined position to achieve sound propagation with better spatial effects.

More specifically, the connecting member 9 includes a connecting shell 91 and a pair of connecting ends 92. The connecting shell 91 provides an installation space, and the connecting ends 92 are integrally connected to both sides of the connecting shell 91. The connecting member 9 is also provided with a circuit unit 93, and the circuit unit 93 is installed inside the connecting shell 91. The connecting shell 91 has an inner cavity 94 to accommodate the circuit unit 93, and the connecting member 9 also includes a cover 95, which covers the upper opening of the connecting shell 91 to hide the circuit unit 93 inside the connecting member 9.

In particular, the connecting member 9 further includes a microphone unit 96, which is disposed on the connecting housing 91 and installed outside the connecting housing 91 to facilitate the microphone unit 96 to receive output signals transmitted by the user. The microphone unit 96 is electrically connected to the connection terminal 23.

In the present embodiment, the connection between the linear sound-emitting speaker device monomer 1 and the connecting member 9 is determined by the connecting end 92. The connecting end 92 is suitable for being plugged into one side of the housing 11, and the other side is suitable for being plugged into the housing 11 of another linear sound-emitting speaker device monomer 1. In other words, the linear sound-emitting speaker device monomer 1 is interconnected through the plugging of the housing 11 and the connecting end 92, and is interconnected with another linear sound-emitting speaker device monomer 1 through the connecting member 9. Further, the linear sound-emitting speaker device monomer 1 realizes the matrix arrangement connection of the linear sound-emitting speaker device monomer 1 through the connection method of the connecting member 9. Specifically, in the present embodiment, the linear sound-emitting speaker device monomer 1 is connected to the second linear sound-emitting speaker device monomer 1 by being plugged into the connecting member 9. It is easy to understand that the second linear sound-emitting speaker unit 1 can be connected to the third linear sound-emitting speaker unit 1 through the connecting member 9. Therefore, the number of the linear sound-emitting speaker units 1 in the sound valley matrix formed by the linear sound-emitting speaker device is at least two, but can also be three or even more. The number of the linear sound-emitting speaker units 1 is not limited by the present invention.

The two adjacent linear sound-emitting speaker units 1 are connected by the connecting member 9 so that the linear sound-emitting surface can be infinitely extended, and the sound valley matrix of the present invention can be conveniently assembled in a modular manner through these linear sound-emitting speaker units 1.

Further, when the connecting member 9 is connected to both ends of the housing 11 by plugging, the circuit unit 93 is electrically connected to the wiring terminals 23. In this embodiment, the number of the wiring terminals 23 is implemented as eight pairs, and each eight pairs of the wiring terminals 23 are distributed on both sides of the housing 11. Two pairs are electrically connected to the conductive circuit 22, two pairs are electrically connected to the light source 40, and two pairs are electrically connected to the circuit Unit 93, and the other two pairs are electrically connected to the microphone unit 96. The wiring terminal 23 is electrically connected to the circuit unit 93, and is suitable for being electrically connected to another linear sound-generating speaker unit 1 through the connecting member 9. The linear sound-generating speaker units 1 are spliced together through the connecting member 9 to form various patterns and shapes, forming different sound field effects, thereby achieving the purpose of various surface sound sources.

The installation method of the sound valley matrix formed by the speaker device based on the linear sound is introduced as an example. First, the speaker device unit 1 for linear sound is assembled. When assembling the strip diaphragm 20, the strip diaphragm 20 is fixed on the fixed frame 122 in a taut state. When assembling the magnet assembly 30, the magnet 31 of the magnet assembly 30 is assembled in the positioning groove 1211. Among them, the strip diaphragms 20 are spaced apart from each other in the magnet assembly 30. That is, the magnetic pole surface 300 at the top of the magnet assembly 30 and the strip diaphragm surface 200 at the bottom of the strip diaphragm 20 are arranged parallel to each other. When assembling the light source 40, the light bar 41 is assembled on the bracket 12 and is located at the lower part of the magnet assembly 30. When the housing 10 is finally assembled, the bracket 12 composed of the strip diaphragm 20, the magnet assembly 30 and the light source 40 is assembled in the tubular housing 11. The linear speaker unit 1 is made into a whole. The connecting member 9 is assembled, and the connecting end 92 at one end of the connecting member 9 is plugged into one end of the housing 11, and the other end is plugged into the housing 11 of another linear speaker unit 1.

In this embodiment, the two ends of the connecting member 9 are connected to the two adjacent linear sound-emitting speaker units 1 by plugging. In other variant embodiments, the two ends of the connecting member 9 can also connect the two adjacent linear sound-emitting speaker units 1 by screwing, snapping, bonding, etc. As shown in FIG6 , a sound valley matrix formed by a linear sound-emitting speaker device according to a variant embodiment provided by the present invention is shown. The sound valley matrix formed by the linear sound-emitting speaker device includes a plurality of linear sound-emitting speaker units 1 and one or more connecting members 9. The linear sound-emitting speaker unit 1 is suitable for providing a surface sound function. The connecting member 9 is suitable for providing a function of connecting two linear sound-emitting speaker units 1. That is, the linear sound-emitting speaker unit 1 is connected to another linear sound-emitting speaker unit 1 through the connecting member 9. The connecting member 9 is suitable for providing various connection methods to connect a plurality of linear sound-emitting speaker units 1. The connecting member 9 receives the linear sound-generating speaker unit 1 on both sides and is installed around or near the smart product in a detachable manner to achieve a three-dimensional multi-faceted sound effect.

In this embodiment, compared with the above embodiment, the speaker device based on the linear sound generation is formed The connection method between the linear sound-emitting speaker device monomer 1 and the connecting member 9 in the sound valley matrix is changed. Specifically, the connecting member 9 is implemented as a flexible connecting wire or a connecting belt to connect the linear sound-emitting speaker device monomers 1 on both sides. Compared with the above embodiment, the wire connection method makes the matrix connection between the linear sound-emitting speaker device monomer 1 and another linear sound-emitting speaker device monomer 1 not affected by the installation position. In other words, the installation of the sound valley matrix formed by the linear sound-emitting speaker device is not affected by the installation environment.

As shown in FIGS. 7 and 8, another variant embodiment provided by the present invention is a sound valley matrix formed by a speaker device based on linear sound. The sound valley matrix formed by the speaker device based on linear sound includes a plurality of speaker devices 1 for linear sound and a connecting member 9. The speaker device 1 for linear sound is suitable for providing a surface sound function. The connecting member 9 is suitable for providing a function of connecting two speaker devices 1 for linear sound. In other words, the speaker device 1 for linear sound is connected to another speaker device 1 for linear sound through the connecting member 9. The connecting member 9 is suitable for providing various connection methods to connect a plurality of speaker devices 1 for linear sound. The connecting member 9 receives the speaker devices 1 for linear sound on both sides and is installed on the sides of the smart product and the user in a detachable manner to achieve a stereoscopic multi-faceted sound effect.

In this embodiment, compared with the above-mentioned embodiment, the structure of the connecting member 9 in the sound valley matrix formed by the speaker device based on the linear sound is changed. In this embodiment, the connecting member 9 is implemented in a right angle shape. That is to say, when the speaker device monomer 1 for linear sound is connected to another speaker device monomer 1 for linear sound through the connecting member 9, the speaker device monomer 1 for linear sound is perpendicular to the speaker device monomer 1 for linear sound. In other words, the arrangement directions of the speaker device monomer 1 for linear sound and the speaker device monomer 1 for linear sound are perpendicular to each other when installed. The sound valley matrix formed by the speaker device based on the linear sound of this embodiment can avoid the limitation of the installation position by the bending type of the connecting member 9.

It is worth mentioning that the sound valley matrix formed by the linear sound-generating speaker device is also equipped with the function of intelligent voice interaction. Furthermore, the microphone unit 96 is implemented as a carrier of intelligent voice interaction. The microphone unit 96 is located outside the connecting shell 91 to receive the voice signal transmitted by the user. In this embodiment, the microphone unit 96 is implemented as an intelligent voice interaction function equipped with an AI module. In other words, the user can output the required voice to the microphone unit 96 and feedback to the AI module equipped with the microphone unit 96 to obtain the experience of intelligent voice interaction. The AI module has a variety of functions to serve users. For example, access to the latest real-time information, performing operations on behalf of users, and private customization. Secretary assistant, etc.

More specifically, as shown in FIG. 9 to FIG. 11 , several application scenarios of the implementation method of the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction are exemplarily introduced:

As shown in FIG9 , the sound valley matrix formed by the speaker device based on linear sound generation is suitable for use in scenes such as bedrooms and living rooms. Due to the detachability and convenience of the sound valley matrix formed by the speaker device based on linear sound generation, it can be installed around the bedroom, for example: around the TV, around the sofa for watching TV, around the front, etc. The surrounding arrangement of the sound valley matrix formed by the speaker device based on linear sound generation is suitable for judging the distance of the user, so as to select one of the sound valley matrices formed by the speaker device based on linear sound generation equipped with intelligent voice interaction to receive sound and further provide feedback to the user.

Furthermore, when the user just gets home from get off work and wants to know which team he is following has won, he outputs a voice output. The sound valley matrix formed by the linear sound-emitting speaker device equipped with intelligent voice interaction installed around the TV receives the user's voice output, accesses network information in real time, turns on the TV and plays the information the user requires.

In addition, following the above example application scenario, when the user outputs voice information requesting takeout, the sound valley matrix formed by the linear sound-emitting speaker device equipped with intelligent voice interaction receives the user's voice output, and performs operations on behalf of the user to perform online shopping according to the user's requirements.

As shown in Figure 10, the sound valley matrix formed by the speaker device based on linear sound is suitable for being applied to the scene of the blind path. The sound valley matrix formed by the speaker device based on linear sound equipped with intelligent voice interaction is suitable for being installed on both sides of the blind path. For example, when a blind person walks on the blind path, when the sound valley matrix formed by the speaker device based on linear sound equipped with intelligent voice interaction is output to inquire about the geographical location, the sound valley matrix formed by the speaker device based on linear sound receives the voice output of the blind user, accesses real-time network data for positioning, and outputs the current location to the user, as well as the route conditions in meters ahead.

When a vehicle is parked on the blind path ahead, the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction outputs warning information to the user to remind the user of the danger ahead. Since the sound valley matrix formed by the linear sound-generating speaker device has the light bar 41, the light bar 41 flashes brightly around the blocked blind path, such as a red alarm color, to remind the surrounding management personnel to clear the blind path in time, so as to facilitate the use of the blind path and avoid inconvenience or even injury to the blind due to accumulation on the road surface.

Similarly, the sound valley matrix formed by the linear sound-generating speaker device equipped with intelligent voice interaction is also It can be installed on both sides of airports, high-speed rail stations, and music passages to receive users' inquiries about road conditions and locations, access real-time information based on real-time positioning, and provide feedback to users.

As shown in Figure 11, the sound valley matrix formed by the speaker device based on linear sound is suitable for being applied to classroom scenes. The sound valley matrix formed by the speaker device based on linear sound equipped with intelligent voice interaction is suitable for being installed on the periphery of the classroom space, on both sides of the blackboard, on the side of the desk, etc. The scattered installation method makes the sound effect provided by the sound valley matrix formed by the speaker device based on linear sound more three-dimensional. For example, the teacher can output a training signal to the sound valley matrix formed by the speaker device based on linear sound equipped with intelligent voice interaction. That is, the teaching content is prepared for the AI module, and the AI module accesses network information and learns in real time. When teaching in the classroom, the teacher outputs a signal instruction, and the sound valley matrix formed by the speaker device based on linear sound equipped with intelligent voice interaction that has been trained receives the signal and feeds back to the students according to the predetermined training content. The AI module has become an assistant to the teacher, reducing the pressure on the teacher.

The following examples illustrate the application scenarios of the sound valley matrix formed by the linear sound-generating speaker device. When the user is in a home environment, the specified furniture is operated by voice output. For example: when the temperature is high in summer, the user needs to cool down and specifies the air conditioner to perform cooling adjustment through voice commands. After receiving the command, the AI module passes it to the sound valley matrix installed at the air conditioner. While intelligently adjusting the air conditioner temperature, the sound valley matrix feeds back the adjusted status: temperature, timing and other information. And through intelligent analysis by the AI module, ask the user if he needs an iced drink. After the user feedback, the demand signal is transmitted to the sound valley matrix installed in the refrigerator, and the operation is performed according to the demand signal.

In particular, the AI module can intelligently analyze the user's preferences and ask the user whether he needs to purchase the user's favorite drinks through the network through the sound valley matrix. For example, the user sends a request to the AI module for mineral water with a limited price and a request to stock the refrigerator within one day. The AI module can access network information and filter out mineral water that is close to the user's address and within the specified price, place an order according to the quantity provided by the user, and pay.

For example, when a user needs to go on a business trip, the user can ask the AI module to book a hotel. The AI module can filter out suitable hotels based on the location of the intended destination and the user's price requirements. And according to the user's instructions, it provides ways to send emails and make phone calls to ensure the reservation of the room and confirm additional additional precautions. After confirmation, the sound valley matrix will feedback to the user that the order has been submitted, and detailed order data will be fed back to the user, such as: detailed hotel location, surrounding food recommendations, hotel hours, room number, price, precautions, etc. After the user has confirmed, the AI module will ask the user for return tickets and other required information. And screen on the network platform based on the relevant information provided by the user. Select, check, pay, and transmit the final order information to the user's smart device.

As shown in FIG12 , in this variant embodiment, the connecting member 9 is suitable for connecting a subwoofer device 8 at one end and connecting to the linear sound-emitting speaker device monomer 1 at the other end. That is, the linear sound-emitting speaker device monomer 1 is connected to the subwoofer device 8 through the connecting member 9, and the AI module can be inside the subwoofer device 8.

In particular, in this embodiment, the circuit unit 93 in the connecting member 9 is provided with a frequency divider. The frequency divider is suitable for distinguishing sound signals and transmitting low-frequency sound signals to the subwoofer device 8, which outputs sound effects; and transmitting medium and high-frequency sound signals to the linear sound-emitting speaker device monomer 1 for output. Since the subwoofer device 8 and the linear sound-emitting speaker device monomer 1 are more suitable for outputting sound effects within their respective sound ranges, the overall effect of the output sound effect of this embodiment is the best, which can bring the best experience to users.

As shown in FIG. 13 to FIG. 15 , the main difference between this modified embodiment and the above-mentioned embodiment is that the shape of the magnet assembly is changed.

In this embodiment, the conductive circuit 22 includes a plurality of columns of linear circuits 221 , which are integrally connected, such as three columns of linear circuits 221 , and each column of the linear circuits 221 is arranged to be staggered with respect to an adjacent column of the magnets 31 .

As shown in FIG. 16 and FIG. 17 , the main difference between this modified embodiment and the above-mentioned embodiment is that the shape of the magnet assembly 30 is changed.

In this embodiment, the conductive circuit 22 includes a plurality of line portions 220, the plurality of line portions 220 are electrically connected, and each of the line portions 220 includes one or more linear lines 221. For example, in the example shown in FIG. 16 , the conductive circuit 22 includes four line portions 220, each of the line portions 220 includes four linear lines 221, and the four linear lines 221 extend integrally and are connected, such as extending in a runway-like shape.

As shown in FIG. 18 and FIG. 19 , the main difference between this modified embodiment and the above-mentioned embodiment is that the number and arrangement of the strip-shaped diaphragms 20 are changed.

The linear sound-emitting speaker unit 1 includes a shell 10, two strip diaphragms 20 and a magnet assembly 30, wherein the two strip diaphragms 20 are linear and are installed on the shell 10 along a linear direction and are located on opposite sides of the magnet assembly 30, and the magnet assembly 30 is also arranged along a linear direction, wherein when the two strip diaphragms 20 respond to the input of the sound source current signal, they vibrate under the action of the magnetic field of the magnet assembly 30 to produce sound effects.

The two strip diaphragms 20 are driven by the same magnet assembly 30 to work simultaneously, or they can work alternately and periodically, or when one of the strip diaphragms 20 can no longer be used, the other strip diaphragm 20 can be started, thereby extending the service life of the linear sound-emitting speaker device.

As shown in FIG. 20 and FIG. 23 , the main variation of this variant embodiment from the above-mentioned embodiment lies in the overall structural change of the linear sound-emitting speaker unit 1. The linear sound-emitting speaker unit 1 also includes a shell 50. The strip diaphragm 20 is installed in the shell 50 in a linear shape. The shell 50 includes a first shell portion 51 and a second shell portion 52. The first shell portion 51 is installed on the upper part of the second shell portion 52. The strip diaphragm 20 is installed in the first shell portion 51. The magnet assembly 30 is installed in the second shell portion 52. The shell 50 also includes a connecting structure 53, and the connecting structure 53 is suitable for connecting the first shell portion 51 and the second shell portion 52.

The first housing portion 51 has at least one fixing protrusion 511 and at least one through hole 512. The second housing portion 52 has at least one positioning groove 521. The fixing protrusion 511 is arranged at the bottom of the first housing portion 51. The through hole 512 is arranged at the side of the first housing portion 51 to serve as a vent. The positioning groove 521 is arranged at the top side of the second housing portion 52.

The linear speaker unit 1 further comprises a driving assembly 70, which is also arranged in a linear direction. When the strip diaphragm 20 responds to the input of the sound source current signal, it vibrates under the action of the driving assembly 70 to produce sound effects.

In this embodiment, the driving assembly 70 includes a plurality of driving electrodes 71, and the driving electrodes 71 extend in a strip shape. The driving motor 71 is converted into polarity by a transformer to alternately act on the strip diaphragm 20 implemented as an electrostatic diaphragm through suction, thereby generating sound effects by vibrating the air.

As shown in FIG. 24 and FIG. 25, the main difference between these two variant embodiments and the above-mentioned embodiment is that the overall structure of the linear sound-generating speaker unit 1 is changed. The linear sound-generating speaker unit 1 also includes at least one dynamic speaker 60. In this embodiment, the dynamic speaker 60 is arranged on both sides of the strip diaphragm 20. The dynamic speaker 60 includes a drum paper 61, a voice coil 62 and a magnetic return system 63. The drum paper 61 is connected to the housing 10. When the sound source current signal is input into the voice coil 62, it drives the drum paper 61 to vibrate under the action of the magnetic return system 63 to produce sound effects.

It can be understood that in the embodiment of FIG. 23 of the present invention, the vibration sound-generating device based on the strip diaphragm 20 and the magnet assembly 30 and the dynamic speaker 60 are matched with each other to provide a more full-frequency sound effect. In other words, the vibration sound-generating device based on the strip diaphragm 20 and the magnet assembly 30 is suitable for The dynamic speaker 60 can provide mid- and high-frequency sounds, and the drum paper 61 has a higher stroke, so that the dynamic speaker 60 can supplement the mid- and low-frequency sound effects, so that the linear sound-generating speaker unit 1 of the present invention can produce relatively full-band sound effects along the linear surface. In addition, the drum paper 61 and the strip diaphragm 20 can be made of roughly the same material, the drum paper 61 of the dynamic speaker 60 is connected to the voice coil 62, and the conductive circuit 22 of the strip diaphragm 20 is disposed on the diaphragm base 21.

As shown in Figure 25, in this embodiment, the linear sound-emitting speaker device unit 1 includes a shell 10, two strip diaphragms 20, two magnet assemblies 30 and three dynamic speakers 60, wherein each of the strip diaphragms 20 is linear and is installed on the shell 50 along a linear direction, and the corresponding magnet assemblies 30 are also arranged along a linear direction, wherein when the strip diaphragm 20 responds to the input of the sound source current signal, it vibrates under the action of the magnetic field of the magnet assembly 30 to produce sound effects, and when the sound source current signal is input into the voice coil 62 of each of the dynamic speakers 60, it electromagnetically interacts with the magnetic return system 63 to drive the drum paper 61 to vibrate and thus produce sound effects.

It can be understood that the vibration sound-generating device based on the strip diaphragm 20 and the magnet assembly 30 and the dynamic coil speaker 60 are arranged alternately, which not only ensures the superiority of the strip diaphragm 20 in the medium and high frequencies, but also makes up for the disadvantage of insufficient low frequencies of the strip diaphragm 20. The annular magnet of the dynamic coil speaker 60 replaces the use of a large number of bar-shaped magnets 31 of the magnet assembly 30, thereby greatly reducing the cost and increasing the audio performance of the entire linear sound-generating speaker device.

The dynamic speaker 60, the strip diaphragm 20 and the magnet assembly 30 can be assembled on the bracket 12 and accommodated in the tubular outer shell 11 of the shell 10. The connecting terminals of the voice coil 62 of the dynamic speaker 60 and the connecting terminals of the strip diaphragm 20 can be connected in series to form a response to the same input sound source current signal to generate low-mid frequency sounds and high-mid frequency sounds respectively, so that the generated sound effect can cover a wider frequency band.

It can be understood that the linear sound-emitting speaker device may also include a plurality of the dynamic coil speakers 60 and one or more electrostatic diaphragm speaker devices in the embodiments of FIGS. 19 to 20 .

It is worth noting that the above embodiments all include at least one connecting member 9. In each variant embodiment, the linear sound-emitting speaker device monomer 1 is exemplarily plugged into the connecting member 9. The linear sound-emitting speaker device monomer 1 can also be connected to the connecting member 9 by other means such as a connecting wire or a connecting belt, and connected to another linear sound-emitting speaker device monomer 1 through the connecting member 9, thereby forming a stereoscopic multi-faceted sound effect of the sound valley matrix formed by the linear sound-emitting speaker device. Therefore, the connection method of the connecting member 9 is not limited by the present invention.

It can be understood that the connecting member 9 is not limited to the above-mentioned method. For example, the end of the linear sound-emitting speaker device monomer 1 can have a protrusion, and the ends of two adjacent linear sound-emitting speaker device monomers 1 are matched with each other and connected through the two protrusions so that the two adjacent linear sound-emitting speaker device monomers 1 form a whole, thereby extending the linear sound-emitting surface.

It is worth noting that the above embodiments all include at least one microphone sub-unit 96. In each variant embodiment, the microphone unit 96 is installed outside the connection housing 91. The microphone unit 96 can also be connected to the connection housing 91 by other means such as wire connection, external connection, etc. The installation method of the microphone unit 96 is not limited by the present invention.

It should be understood by those skilled in the art that the embodiments of the present invention described above and shown in the accompanying drawings are only examples and do not limit the present invention. The purpose of the present invention has been fully and effectively achieved. The functional and structural principles of the present invention have been demonstrated and explained in the embodiments, and the embodiments of the present invention may be deformed or modified in any way without departing from the principles.

Claims (19)

The method for implementing the intelligent voice interaction of the sound valley matrix is characterized by comprising the following steps: (A) Arranging one or more sound valley matrices, each of the sound valley matrices comprising: Multiple linear sound-emitting speaker units; At least one connecting member, two adjacent linear sound-emitting speaker units are suitable for being connected through the connecting member so that the linear sound-emitting surfaces of the plurality of linear sound-emitting speaker units can be extended and expanded; at least one microphone unit; and 1. AI module; (B) receiving voice commands from the microphone unit; (C) transmitting a signal to the AI module; (D) The AI module controls the speaker unit to emit sound to feed back information to the user. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 1, the AI module accesses real-time information on the network and speaks through the speaker unit to feedback information to the user. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 2, the AI module searches for answer information corresponding to the voice command on the network, and speaks through the speaker unit to feedback information to the user. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 2, the AI module performs online shopping based on the voice command, and sounds through the speaker unit to feedback information to the user. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 2, the AI module plays the multimedia information from the network through the speaker unit based on the voice command. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 2, the AI module makes a call based on the voice command. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 2, the AI module sends an email based on the voice command. The method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 1, further comprising the step of: the AI module controls the operation of the electronic device after receiving the signal, wherein the electronic device is Home or office equipment. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 1, it also includes the step of determining the user's position to select the sound valley matrix of the adjacent user for voice interaction. According to the method for implementing the sound valley matrix equipped with intelligent voice interaction according to claim 1, it also includes the step of providing a lighting effect through a light source to achieve the effect of sound and light synchronization. The sound valley matrix equipped with intelligent voice interaction function is characterized by including: Multiple linear sound-emitting speaker units; At least one connecting member, two adjacent linear sound-emitting speaker units are suitable for being connected through the connecting member so that the linear sound-emitting surfaces of the plurality of linear sound-emitting speaker units can be extended and expanded; a microphone unit; and An AI module controls the speaker unit to emit sound to feed back information to the user. According to the sound valley matrix of claim 11, the connecting component includes a connecting shell, the connecting shell provides an installation space, and the microphone unit is suitable for being installed in the connecting shell to receive the user's voice signal instructions. According to the sound valley matrix of claim 11, the linear sound-emitting speaker unit comprises a shell, at least one strip diaphragm and at least one magnet assembly, the shell provides an installation space, the strip diaphragm and the magnet assembly are suitable for being installed in the shell, the strip diaphragm and the magnet assembly are arranged in parallel with each other, and when the strip diaphragm responds to the input of the sound source current signal, it vibrates under the action of the magnet assembly to produce sound effects. The sound valley matrix according to claim 13, wherein the magnets of the magnet assembly form a pole face facing the strip diaphragm, the strip diaphragm has a diaphragm face facing the magnet assembly, the pole face and the diaphragm face are parallel to each other, and the linear extension direction of the magnet arrangement is offset from the extension direction of the linear circuit. According to the sound valley matrix according to claim 11, the linear sound-emitting speaker unit comprises a shell, at least one strip diaphragm and two driving electrodes, which are located on opposite sides of the strip diaphragm and change polarity through voltage conversion to drive the strip diaphragm implemented as an electrostatic diaphragm. The sound valley matrix according to any one of claims 11 to 15, wherein the shell comprises a tubular outer shell and a bracket, the strip diaphragm and the magnet assembly are mounted on the bracket and are located in the tubular outer shell. The sound valley matrix according to claim 16, wherein the bracket includes a base and a fixed frame, the magnet assembly is mounted on the base, the strip diaphragm is mounted on the fixed frame, and a vibration space is formed between the strip diaphragm and the base, the base has one or more air holes, and a connecting space is formed on the bottom side of the base, wherein the vibration space and the connecting space are connected through the air holes. The sound valley matrix according to any one of claims 11 to 15 further includes one or more dynamic speakers, which are installed on the shell to respond to the input of the sound source current signal together with the strip diaphragm to simultaneously produce sound effects, wherein when the linear sound-emitting speaker device includes a plurality of the dynamic speakers, the plurality of speakers formed by the dynamic speakers and the strip diaphragm are arranged alternately and linearly. According to any one of claims 11 to 15, the sound valley matrix further includes a subwoofer sound effect device, and also includes a crossover to input bass sound signals into the subwoofer sound effect device and mid-high frequencies into the linear sound-emitting speaker device unit, wherein the AI module is installed in the subwoofer device.