KR20160061857A - Apparatus and method for controlling sound using multipole sound object - Google Patents

Abstract

An apparatus and method for controlling a sound provided to a user using a multi-polar acoustic object are disclosed.
A method for controlling a sound includes: setting a multi-polar acoustic object including at least one sound source; And controlling a property of the sound source included in the multi-polar acoustic object according to a relative distance and direction between the multi-polar acoustic object and the user.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus and method for controlling multi-

The present invention relates to an apparatus and method for controlling a sound provided to a user using a multi-polar acoustic object.

Object-based audio technology is a technique that reproduces the position of a sound source according to a movement path of a sound source in the reproduction step by expressing the sound object as positional information related to one point sound source and a point sound source.

However, a sound object having a volume such as an automobile may include a plurality of different sound sources. Therefore, when the relative distance between the sound object and the user is less than a certain distance, the sound differs according to the direction, so that the sound object can not be accurately represented by a single point sound source.

In 2002, the Korea Electronics and Telecommunications Research Institute (KEITI) filed a patent for "3-D sound-scene processing method with extended sound source" to represent volume object. However, the " three-dimensional acoustic scene processing method having a sound source with a wide spatial extent "expresses the width or volume of the sound object in the multidimensional space by the x, y, and z coordinates and the direction of the directional vector perpendicular to the surface, It is a way to extend a single point source through low cross-correlation. That is, since one point sound source is duplicated, it is impossible to reproduce an acoustic object having a plurality of different sound sources and having a volume.

Therefore, there is a demand for a method capable of reproducing an acoustic object having a plurality of different sound sources and having a volume.

The present invention can provide an apparatus and method for reproducing accurate realism of a sound object having a volume using a multipolar acoustic object.

A method for controlling a sound according to an embodiment of the present invention includes: setting a multi-polar acoustic sound object including at least one sound source; And controlling a property of the sound source included in the multi-polar acoustic object according to a relative distance and direction between the multi-polar acoustic object and the user.

The setting of the sound control method according to an embodiment of the present invention may set the multi-pole sound object using one sound source and at least one directional characteristic of the sound source.

The step of controlling the sound control method according to an embodiment of the present invention may rotate the position of the sound source and the directional characteristic of the sound source based on the center of the multi-polar sound object when the multi-polar sound object rotates .

The step of controlling the sound control method according to an embodiment of the present invention may include a step of controlling the position of the sound source and the directionality characteristic of the sound source according to a position where the multi- Can be moved.

The step of controlling the sound control method according to an embodiment of the present invention may include a step of controlling the position of the sound source according to a relative distance between the changed multi-polar sound object and the user when the relative distance between the multi- Can be moved.

In the step of setting the sound control method according to an embodiment of the present invention, a plurality of sound sources may be arranged around the position of the multipurpose sound object, and the directional property of the plurality of sound sources may be used to set the multipurpose sound object.

The step of controlling the sound control method according to an embodiment of the present invention may control the volume of the multi-pole sound object by controlling the relative distance between the plurality of sound sources.

The step of controlling the sound control method according to an embodiment of the present invention may further include downmixing the plurality of sound sources into one sound source when the relative distance between the multi-sound source object and the user exceeds a threshold value, The at least one directional characteristic of one sound source may be used to represent the multi-polar acoustic sound object.

In the step of setting the sound control method according to an embodiment of the present invention, a plurality of sound sources may be arranged in a one-dimensional form to set the multi-pole sound object in the form of a line source.

In the step of setting the sound control method according to an embodiment of the present invention, a plurality of sound sources may be arranged in a two-dimensional form to set the multi-polar sound object in the form of a planar source.

In the step of setting the sound control method according to an embodiment of the present invention, a plurality of sound sources may be arranged in a three-dimensional form to set the multi-polar sound object in the form of a volume source.

According to an embodiment of the present invention, there is provided a sound control apparatus including: a multi-polar acoustic sound object setting unit for setting a multi-sound sound object including at least one sound source; And a sound source control unit for controlling an attribute of a sound source included in the multipoint sound object according to the relative distance and direction between the multipoint sound object and the user.

The multipoint sound object setting unit of the sound control apparatus according to an embodiment of the present invention may set the multipoint sound object using one sound source and at least one directional characteristic of the sound source.

The sound source control unit of the sound control apparatus according to an embodiment of the present invention can rotate the position of the sound source and the directivity characteristic of the sound source based on the center of the multi-sound source object when the multi-sound source object rotates.

The sound source control unit of the sound control apparatus according to an embodiment of the present invention controls the position of the sound source and the directionality characteristics of the sound source according to the position of rotation of the multi-sound source object when the multi- Can be moved.

The sound source control unit of the sound control apparatus according to an embodiment of the present invention controls the position of the sound source according to the relative distance between the changed multi-polar sound object and the user, Directional characteristics can be shifted.

The multipoint sound object setting unit of the sound control apparatus according to an embodiment of the present invention may arrange a plurality of sound sources around the positions of the multipole sound objects and set the multipole sound objects using the directivity characteristics of the sound sources .

The sound source control unit of the sound control apparatus according to an embodiment of the present invention can control the volume of the multi-pole sound object by controlling the relative distance between the plurality of sound sources.

The sound source control unit of the sound control apparatus according to an embodiment of the present invention downmixes the plurality of sound sources into one sound source and outputs the sound source and the one The at least one directional characteristic of the sound source of the multi-polar acoustic sound object may be used to represent the multi-polar acoustic sound object.

The multipoint sound object setting unit of the sound control apparatus according to an embodiment of the present invention can arrange a plurality of sound sources in a three-dimensional form to set the multipoint sound object in the form of a volume sound source.

According to an embodiment of the present invention, a sound object having a volume including a plurality of sound sources is set as a multi-sound sound object having a relative position and a directivity to each sound source, so that accurate realism of a sound object having a volume can be reproduced have.

1 is a block diagram of a sound control apparatus according to an embodiment of the present invention.
2 is an example of a multipurpose acoustic object set according to an embodiment of the present invention.
3 is an example in which a multipurpose acoustic object set according to an embodiment of the present invention is rotated based on a user.
FIG. 4 is an example in which a multipurpose acoustic object set according to an embodiment of the present invention rotates.
5 is an example in which a relative distance between a user and a multipurpose acoustic object set according to an embodiment of the present invention approaches.
6 is an example in which a relative distance between sound sources included in the multipurpose acoustic object set according to an embodiment of the present invention is changed.
FIG. 7 is an example in which a relative distance between a multipurpose acoustic object set according to an embodiment of the present invention and a user approaches and a relative distance between sound sources included in the multipurpose acoustic object changes.
8 is an example in which a relative distance between a user and a multipurpose acoustic object set according to an embodiment of the present invention is increased.
9 is an example of a multipurpose acoustic object according to an embodiment of the present invention.
10 is an example of a real object corresponding to a multipurpose acoustic object according to an embodiment of the present invention.
11 is a flowchart showing a sound control method according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sound control method according to an embodiment of the present invention can be performed by a sound control apparatus.

In the object - based sound control technology for real sound, the object sound source can not be determined as the only signal for the position of the object sound source. For example, a car sound can be recognized as a sound of a car, such as engine noise, exhaust sound, and the like. And, depending on the relative position between the user and the car, the user can hear the car sound differently. For example, if the user is located in front of the vehicle, the user may hear the engine noise greater than the exhaust sound.

That is, when a monopole sound source obtained at a fixed position is used as an object sound source corresponding to a car, the same car sound is heard irrespective of the relative position between the user and the car, so that the reality may be degraded.

Therefore, the sound control apparatus 100 according to an embodiment of the present invention is configured by a plurality of sound sources such as an automobile and sets a sound object having a volume as a multi-pole sound object to control the relative position between the user and the multi- It is possible to provide a realistic sound.

1 is a block diagram of a sound control apparatus according to an embodiment of the present invention.

When controlling a moving sound source or an interactive sound source by using an object-based sound control technique in which a signal of a sound object is extended from a single-pole to a multi-pole, the sound control apparatus 100 of the present invention can smoothly change a sound .

The sound control apparatus 100 may include a multi-polar sound object setting unit 110 and a sound source control unit 120 as shown in FIG.

The multipoint sound object setting unit 110 may set a multipoint sound object including at least one sound source.

At this time, the multipoint sound object setting unit 110 can set the multipoint sound object using one sound source and at least one directional characteristic of the sound source. At this time, the directivity characteristic of the sound source can be represented by the direction and size of the main lobe and the directivity pattern. Also, the directivity characteristic of the sound source may be represented by a gain value in each direction.

The multipoint sound object setting unit 110 arranges a plurality of different sound sources constituting the multipoint sound object around the position of the multipoint sound object, and outputs the multipoint sound object using the directivity characteristic of each sound source Can be set. At this time, the number of sound sources arranged around the position of the multipurpose sound object can be variably determined as needed.

At this time, the multipoint sound object setting unit 110 can set the multipoint sound object in the form of a line source in which a plurality of sound sources are arranged in a one-dimensional form. In addition, the multi-polar sound object setting unit 110 may set a multi-polar sound object in the form of a planar source by disposing a plurality of sound sources in a two-dimensional form. The multi-polar acoustic sound object setting unit 110 may set a multi-sound sound object in the form of a volume source by disposing a plurality of sound sources in a three-dimensional form. An example in which the multipoint sound object setting unit 110 arranges a plurality of sound sources will be described in detail with reference to FIG.

The sound source controller 120 may control the properties of sound sources included in the multi-sound source object according to the relative distance and direction between the multi-source sound object and the user. At this time, the sound source controller 120 determines the relative positions of the sound sources, the directional characteristics, and the relative positions of the sound sources according to the rotation of the multipurpose sound object, the position of the multi-pole sound object rotated based on the user, The distance can be controlled by controlling.

For example, when the multipurpose acoustic object rotates, the sound source controller 120 may rotate the position of the sound source and the directional characteristic of the sound source based on the center of the multipoint sound object. The operation when the multipurpose acoustic object rotates will be described in detail with reference to FIG.

In addition, when the multipoint sound object rotates with respect to the user, the sound source controller 120 may move the position of the sound source and the directivity characteristic of the sound source according to the position where the multipoint sound object is rotated. 3, the sound source controller 120 can move the position of the sound source and the directional characteristics of the sound source according to the position of the multi-polar sound object rotated based on the user.

When the relative distance between the multipurpose acoustic object and the user changes, the sound source controller 120 can move the position of the sound source and the directional characteristics of the sound source according to the relative distance between the changed multi-polar sound object and the user. At this time, when the relative distance between the multipurpose acoustic object and the user is narrowed, the sound source controller 120 can move the position of the sound source and the directivity characteristic of the sound source, as shown in FIG. In addition, when the relative distances between the multipurpose acoustic object and the user are distant from each other, the sound source control unit 120 may shift the position of the sound source and the directional characteristics of the sound source, as shown in FIG. When the relative distance between the multipurpose acoustic object and the user exceeds the threshold value, the sound source control unit 120 downmixes the plurality of sound sources into one sound source, and uses at least one directional characteristic of one sound source and one sound source To represent a multi-polar acoustic object.

In addition, the sound source control unit 120 may control the volume of the multipurpose sound object by controlling the relative distance between the sound sources. A specific process for controlling the volume of the multipurpose acoustic object will be described in detail with reference to FIG.

The sound control apparatus 100 according to the present invention can represent a special effect exploring the inside of a sound object including a plurality of sound sources such as an automobile and having a volume by setting a multi-pole sound object in a hierarchical structure. For example, the sound control apparatus 100 may move between the positions of the conductors in the orchestra or performers playing the musical instruments, and may provide audible sounds at the moved positions.

2 is an example of a multipurpose acoustic object set according to an embodiment of the present invention.

The multipoint sound object setting unit 110 may set a multipurpose sound object 210 having a volume at an arbitrary position with reference to the user 200 as shown in FIG. A plurality of sound sources 220, 230 and 240 constituting the multi-pole sound object can be arranged based on the center 211 of the multi-pole sound object. At this time, the sound source 220, the sound source 230, and the sound source 240 may have a relative position with respect to the center 211 of the multipurpose sound object, respectively. The sound source 220, the sound source 230, and the sound source 240 may have a directional pattern 221, a directional pattern 231, and a directional pattern 241, respectively.

At this time, the multipoint sound object setting unit 110 sets the position of the multipurpose sound object using a rectangular coordinate system based on x, y, and z axes, or a spherical coordinate system based on r, q, A sound source 220, a sound source 230, and a sound source 240. [0033] FIG.

The sound source controller 120 controls the sound source 220, the sound source 230 and the sound source 240 according to the relative distance and direction between the multi-polar sound object and the user, the directional pattern 221 of the sound source 220, The directional pattern 231 of the sound source 240 and the directional pattern 241 of the sound source 240 can control the relative distance and directionality of the sound source 220, the sound source 230, and the sound source 240 according to the direction of the multi- Can produce this variable sound.

3 is an example in which a multipurpose acoustic object set according to an embodiment of the present invention is rotated based on a user.

The multipurpose sound object 210 may be rotated clockwise with respect to the user 200 as shown in FIG. At this time, the multipulse acoustic object 210 can be moved from the position shown at 310 to the position shown at 320.

3, the sound source control unit 120 maintains a relative position between the sound source 220, the sound source 230, and the sound source 240 and the center 211 of the multi-sound source object 210, 220, the sound source 230, and the sound source 240 can be moved. That is, the relative positions between the sound source 220, the sound source 230, and the sound source 240 and the center 211 of the multi-polar sound object 210 shown in 310, the sound source 220, the sound source 230, And the sound source 240 and the center 211 of the multipurpose acoustic object 210 may be the same.

However, the relative direction between the sound source 220, the sound source 230, and the sound source 240 and the user 200 may be changed according to the movement of the multipurpose sound object 210. Therefore, the gain according to the directivity pattern 221 of the sound source 220, the directivity pattern 231 of the sound source 230, and the directivity pattern 241 of the sound source 240 can be changed. The gain can be determined according to the direction of the directional pattern of the sound source and the angle difference between virtual lines connecting the user's multi-polar acoustic objects.

For example, an angle between the direction of the directional pattern 221 of the user 200 shown in 310 and the direction of the directional pattern 221 of the sound source 220 is shown between 320 and the direction of the directional pattern 221 of the sound source 220, It can be different from the angle. 3, the gain 311 of the directivity pattern 221 of the sound source 220 shown in 310 is different from the gain 321 of the directivity pattern 221 of the sound source 220 shown in FIG. can do.

The angle between the direction of the directional pattern 231 of the user 230 and the direction of the directional pattern 231 of the sound source 230 shown at 310 is also shown at 320, Can be different. 3, the gain 312 of the directional pattern 231 of the sound source 230 shown in 310 is different from the gain 322 of the directional pattern 231 of the sound source 230 shown in FIG. can do.

The angle between the direction of the directional pattern 241 of the user 240 and the direction of the directional pattern 241 of the sound source 240 shown at 310 is shown at 320, Can be different. 3, the gain 313 of the directional pattern 241 of the sound source 240 shown at 310 is different from the gain 323 of the directional pattern 241 of the sound source 240 shown in FIG. can do.

At this time, the sound source 220, the sound source 230, and the sound source 240 are synthesized by the changed gain 321, the gain 322, and the gain 323, 210). ≪ / RTI >

FIG. 4 is an example in which a multipurpose acoustic object set according to an embodiment of the present invention rotates.

The sound source control unit 120 can move the sound source 220, the sound source 230, and the sound source 240 from the position shown in 410 to the position shown in FIG. The sound source controller 120 can rotate the positions of the sound source 220, the sound source 230, and the sound source 240 with respect to the center of the multipoint sound object 210.

At this time, the relative direction between the sound source 220, the sound source 230, and the sound source 240 and the user 200 may be changed according to the change of the position of the sound source 220, the sound source 230, and the sound source 240 . Therefore, the gain according to the directivity pattern 221 of the sound source 220, the directivity pattern 231 of the sound source 230, and the directivity pattern 241 of the sound source 240 can be changed.

The sound source 220 and the sound source 220 are controlled by the gain of the directional pattern 221 of the changed sound source 220, the gain of the directional pattern 231 of the sound source 230 and the gain of the directional pattern 241 of the sound source 240. [ The sound source 230, and the sound source 240 may be combined to provide the user with sounds corresponding to the multi-polar sound object 210 rotated as 420.

5 is an example in which a relative distance between a user and a multipurpose acoustic object set according to an embodiment of the present invention approaches.

The multipulse acoustic object 210 is moved from the position shown at 510 to the position shown at 520 so that the relative distance between the multipurpose acoustic object 210 and the user can be reduced.

5, the sound source control unit 120 maintains a relative position between the sound source 220, the sound source 230, and the sound source 240 and the center 211 of the multi-sound source object 210, 220, the sound source 230, and the sound source 240 can be moved. That is, the relative position between the sound source 220, the sound source 230, the sound source 240, and the center 211 of the multi-polar sound object 210 shown in 510 and the sound source 220, sound source 230, And the sound source 240 and the center 211 of the multipurpose acoustic object 210 may be the same.

Also, as the relative distance between the user 200 and the sound source 220, the sound source 230, and the sound source 240 approaches, the sizes of the sound source 220, the sound source 230, and the sound source 240 are changed The user may feel that the size of the sound source is increasing.

When the relative distance between the user 200 and the sound source 220, the sound source 230, and the sound source 240 is long, the user can not recognize the position difference between the sound source 220, the sound source 230, May be difficult to identify. Accordingly, the user may feel that the relative distance between the sound source 220, the sound source 230, and the sound source 240 is close to each other. The closer the relative distance between the user 200 and the sound source 220, the sound source 230 and the sound source 240 becomes closer to each other, the more the user moves between the sound source 220, the sound source 230, The difference can be more clearly identified. At this time, the user identifies the difference in position between the sound source 220, the sound source 230, and the sound source 240, which are distant from each other, so that the relative position between the sound source 220, the sound source 230, It can be seen that the relative distance between the sound source 220, the sound source 230, and the sound source 240 is increased even though the distance has not changed.

In reality, when an object including a plurality of sound sources approaches the user, the user can feel the increase in the size of the sound source and the relative distance between the sound sources without changing the sound source.

5, the sound source control unit 120 maintains a relative position between the sound source 220, the sound source 230, and the sound source 240 and the center 211 of the multi-sound source object 210, 220, the sound source 230, and the sound source 240, it is possible to provide realistic sound to the user.

6 is an example in which a relative distance between sound sources included in the multipurpose acoustic object set according to an embodiment of the present invention is changed.

6 is a view showing an example in which the relative distance between the multipurpose acoustic object 210 and the user 200 is changed without changing the position of the multipurpose acoustic object 210 by changing the volume of the multipurpose acoustic object 210 Yes.

The sound source control unit 120 may decrease the volume of the multi-pole sound object 210 shown at 610 as shown in FIG.

Specifically, the sound source control unit 120 may reduce a relative distance between the sound source 220, the sound source 230, and the sound source 240. At this time, the volume of the multipurpose acoustic object 210 may be reduced to 620 as the relative distance between the sound source 220, the sound source 230, and the sound source 240 decreases. Also, the sound source controller 120 may reduce the size of each of the sound source 220, the sound source 230, and the sound source 240 according to the volume reduction of the multipurpose sound object 210.

At this time, when the relative distance between the sound source 220, the sound source 230, and the sound source 240 decreases and the size of each of the sound source 220, the sound source 230, and the sound source 240 decreases, The relative distance between the acoustic object 210 and the user increases.

The sound source control unit 120 may increase the relative distance between the sound source 220, the sound source 230, and the sound source 240. At this time, the volume of the multipurpose acoustic object 210 may be increased to 630 as the relative distance between the sound source 220, the sound source 230, and the sound source 240 increases. The sound source controller 120 may also increase the size of each of the sound source 220, the sound source 230, and the sound source 240 according to the volume of the multipurpose sound object 210.

At this time, when the relative distance between the sound source 220, the sound source 230, and the sound source 240 increases and the size of each of the sound source 220, the sound source 230, and the sound source 240 increases, It can be felt that the relative distance between the acoustic object 210 and the user decreases.

That is, the sound source control unit 120 controls the volume of the multipurpose sound object 210 so that the user can feel the relative distance between the multipurpose sound object 210 and the user increases or decreases without changing the position of the multipurpose sound object 210 Can be provided.

FIG. 7 is an example in which a relative distance between a multipurpose acoustic object set according to an embodiment of the present invention and a user approaches and a relative distance between sound sources included in the multipurpose acoustic object changes.

The multipulse acoustic object 210 is moved in the direction of the user 200 as shown at 710 so that the relative distance between the multipurpose acoustic object 210 and the user can be approximated.

At this time, the sound source controller 120 may increase the volume of the multi-pole sound object 210, such as 720, or decrease the volume of the multi-pole sound object 210, such as 730.

Specifically, the sound source controller 120 may move the sound source 220, the sound source 230, and the sound source 240 according to the movement of the multipurpose sound object 210. The sound source control unit 120 may increase the relative distance between the sound source 220, the sound source 230, and the sound source 240. At this time, the volume of the multipurpose acoustic object 210 may be increased to 720 as the relative distance between the sound source 220, the sound source 230, and the sound source 240 increases. The sound source controller 120 may also increase the size of each of the sound source 220, the sound source 230, and the sound source 240 according to the volume of the multipurpose sound object 210.

At this time, as the relative distance between the sound source 220, the sound source 230, and the sound source 240 increases and the size of each of the sound source 220, the sound source 230, and the sound source 240 increases, The relative distance between the multipurpose acoustic object 210 and the user is more reduced than when the relative position between the sound source 220 and the sound source 230 and between the sound source 240 and the center of the multipurpose acoustic object 210 is maintained .

That is, when the multipurpose sound object 210 moves in the direction of the user 200, the sound source controller 120 moves the position of the sound source 220, the sound source 230, and the sound source 240, The sound source 230, and the sound source 240, it is possible to provide a feeling that the user is approaching the multi-polar acoustic sound object 210 more rapidly.

Also, the sound source controller 120 may reduce the relative distance between the sound source 220, the sound source 230, and the sound source 240. At this time, the volume of the multipurpose acoustic object 210 may be reduced to 730 as the relative distance between the sound source 220, the sound source 230, and the sound source 240 decreases. Also, the sound source controller 120 may reduce the size of each of the sound source 220, the sound source 230, and the sound source 240 according to the volume reduction of the multipurpose sound object 210.

At this time, as the relative distance between the sound source 220, the sound source 230, and the sound source 240 decreases and the size of each of the sound source 220, sound source 230, and sound source 240 decreases, The relative distance between the multipurpose acoustic object 210 and the user may be felt to be smaller than when the relative position between the sound source 220 and the sound source 230 and between the sound source 240 and the center of the multipurpose acoustic object 210 is maintained .

That is, when the multipurpose sound object 210 moves in the direction of the user 200, the sound source controller 120 moves the position of the sound source 220, the sound source 230, and the sound source 240, By reducing the relative distance between the sound source 230 and the sound source 240, it is possible to provide the user with the feeling that the multipurpose sound object 210 approaches more slowly.

8 is an example in which a relative distance between a user and a multipurpose acoustic object set according to an embodiment of the present invention is increased.

The multipulse acoustic object 210 is moved from the position shown at 810 to the position shown at 820 so that the relative distance between the multipurpose acoustic object 210 and the user can be increased.

8, the sound source control unit 120 maintains a relative position between the sound source 220, the sound source 230, and the sound source 240 and the center 211 of the multi-sound source object 210, 220, the sound source 230, and the sound source 240 can be moved. That is, the relative positions between the sound source 220, the sound source 230, the sound source 240 and the center 211 of the multi-electrode sound object 210 shown in 810, the sound source 220, the sound source 230, And the sound source 240 and the center 211 of the multipurpose acoustic object 210 may be the same.

In addition, as the relative distance between the user 200 and the sound source 220, the sound source 230, and the sound source 240 increases, the size of the sound source 220, the sound source 230, The user may feel that the size of the sound source is decreasing.

When the relative distance between the multipurpose acoustic object 210 and the user moves to a position where the relative distance between the user and the multipurpose acoustic object 210 exceeds a threshold value as shown in 830, the sound source control unit 120 may include a sound source 220, 230, and a sound source 240 to a sound source 831. [ At this time, the sound source 831 may have a directional pattern 221 of the sound source 220, a directional pattern 231 of the sound source 230, and a directional pattern 241 of the sound source 240, have.

9 is an example of a multipurpose acoustic object according to an embodiment of the present invention.

The multipoint sound object setting unit 110 may set the multipurpose sound object 900 in a shape different from that of FIG.

For example, the multipoint sound object setting unit 110 may set the multipurpose sound object 900 as one sound source 910 as the point source shown in Case 1.

The multipoint sound object setting unit 110 may set the multipurpose sound object 900 as a plurality of sound sources 910 having a one-dimensional shape such as a line source shown in Case 2 .

The multipoint sound object setting unit 110 may set the multipurpose sound object 900 as a plurality of sound sources 910 in a two-dimensional form such as a planar source shown in Case 3 .

In addition, the multipoint sound object setting unit 110 may set the multipurpose sound object 900 as a plurality of sound sources 910 having a three-dimensional shape such as a volume source shown in Case 4 (Case 4) .

10 is an example of a real object corresponding to a multipurpose acoustic object according to an embodiment of the present invention.

The sound control apparatus 100 may be configured as a multipurpose sound object, such as a car 1000, with sound objects having a plurality of sound sources and having a volume. As shown in FIG. 10, the automobile 1000 may generate different sound sources such as the engine noise 1010 and the exhaust sound 1020 in one object.

The sound controller 100 may set the sound source according to the position where the engine noise 1010 is generated and the position where the exhaust sound 1020 is generated based on the center of the automobile 1000 to set the multipurpose sound object. At this time, the position of the sound source corresponding to the engine noise 1010 and the position of the sound source corresponding to the exhaust sound 1020 can be changed according to the movement and rotation of the automobile 1000.

The user can recognize the direction and the position of the automobile by the change of the position of the sound source corresponding to the engine noise 1010 and the position of the sound source corresponding to the exhaust sound 1020.

For example, when the user recognizes that the size of the sound source corresponding to the engine noise 1010 is larger than the size of the sound source corresponding to the exhaust sound 1020, the user can recognize that the position where the engine noise 1010 occurs is the exhaust sound 1020 Can be judged to be closer to the user than the position where it occurs. At this time, the position where the engine noise 1010 is generated based on the automobile 1000 may be located in front of the position where the exhaust sound 1020 is generated.

Therefore, the user can recognize that the vehicle is moving in the direction of the user.

11 is a flowchart showing a sound control method according to an embodiment of the present invention.

In step 1110, the multipoint sound object setting unit 110 may set a multipoint sound object including at least one sound source.

At this time, the multipoint sound object setting unit 110 can set the multipoint sound object using one sound source and at least one directional characteristic of the sound source. The multipoint sound object setting unit 110 arranges a plurality of different sound sources constituting the multipoint sound object around the position of the multipoint sound object, and outputs the multipoint sound object using the directivity characteristic of each sound source Can be set. At this time, the number of sound sources disposed around the position of the multipurpose sound object can be variably determined as needed.

In step 1120, the sound source controller 120 may control the attributes of the sound source included in the multi-sound source object according to the relative distance and direction between the multi-source sound object and the user. At this time, the sound source controller 120 determines the relative positions of the sound sources, the directional characteristics, and the relative positions of the sound sources according to the rotation of the multipurpose sound object, the position of the multi-pole sound object rotated based on the user, The distance can be controlled by controlling.

For example, when the multipurpose acoustic object rotates, the sound source controller 120 may rotate the position of the sound source and the directional characteristic of the sound source based on the center of the multipoint sound object. In addition, when the multipoint sound object rotates with respect to the user, the sound source controller 120 may move the position of the sound source and the directivity characteristic of the sound source according to the position where the multipoint sound object is rotated. When the relative distance between the multipurpose acoustic object and the user changes, the sound source controller 120 can move the position of the sound source and the directional characteristic of the sound source according to the relative distance between the changed multi-polar sound object and the user.

In addition, the sound source control unit 120 may control the volume of the multipurpose sound object by controlling the relative distance between the sound sources.

The present invention can reproduce the accurate sense of the sound by setting a volume object including a plurality of sound sources as a multi-sound object having a relative position and a directivity of each sound source. For example, when a multi-polar acoustic object approaches the user, the user can provide a plurality of sounds included in the multi-polar acoustic object to be spatially distinguishable according to the volume of the magnified sound. Also, it is possible to reproduce the accurate sound image of the sound source included in the multipoint sound object by controlling the position of the sound source according to the relative position between the multipoint sound object and the user.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

110: Multipole acoustic object setting unit
120: Sound source control unit

Claims (20)

Setting a multi-polar acoustic sound object including at least one sound source; And
Controlling a property of a sound source included in the multi-pole sound object according to the relative distance and direction between the multi-pole sound object and the user
≪ / RTI > The method according to claim 1,
Wherein the setting step comprises:
And setting the multi-polar acoustic object using one sound source and at least one directional characteristic of the sound source. The method according to claim 1,
Wherein the controlling comprises:
And rotating the directional characteristic of the sound source based on a center of the multi-polar acoustic object when the multi-polar acoustic object rotates. The method according to claim 1,
Wherein the controlling comprises:
And moving the direction of the sound source and the directional characteristic of the sound source according to a position where the multi-polar sound object rotates when the multi-polar sound object rotates with respect to the user. The method according to claim 1,
Wherein the controlling comprises:
Wherein the position of the sound source and the directivity characteristic of the sound source are shifted according to a relative distance between the multi-sound source object and the user when the relative distance between the multi-sound source object and the user changes. The method according to claim 1,
Wherein the setting step comprises:
A method of controlling an acoustic control apparatus, comprising: arranging a plurality of sound sources around a position of a multi-pole acoustic object; and setting the multi-pole acoustic object using directional characteristics of the plurality of sound sources. The method according to claim 6,
Wherein the controlling comprises:
And controlling the relative distance between the plurality of sound sources to control the volume of the multi-pole sound object. The method according to claim 6,
Wherein the controlling comprises:
And when the relative distance between the multipurpose acoustic object and the user exceeds a threshold value, downmixing the plurality of sound sources into one sound source, and using the at least one directional characteristic of the one sound source and the one sound source, / RTI > The method according to claim 1,
Wherein the setting step comprises:
A sound control method for arranging a plurality of sound sources in a one-dimensional form to set the multi-sound source object in a form of a line source. The method according to claim 1,
Wherein the setting step comprises:
A method of controlling an acoustic control system, comprising: arranging a plurality of sound sources in a two-dimensional form to set the multi-pole sound object in the form of a planar source. The method according to claim 1,
Wherein the setting step comprises:
A sound control method for arranging a plurality of sound sources in a three-dimensional form to set the multi-pole sound object in the form of a volume source. A multipurpose sound object setting unit for setting a multipurpose sound object including at least one sound source; And
A sound source control unit for controlling an attribute of a sound source included in the multi-pole sound object according to the relative distance and direction between the multi-
And a sound control unit. 13. The method of claim 12,
Wherein the multi-polar acoustic sound object setting unit comprises:
And setting the multi-pole sound object using one sound source and at least one directional characteristic of the sound source. 13. The method of claim 12,
The sound source control unit,
And rotating the directional characteristic of the sound source based on the center of the multi-polar acoustic object when the multi-polar acoustic object rotates. 13. The method of claim 12,
The sound source control unit,
Wherein the position of the sound source and the directivity characteristic of the sound source are shifted according to a position where the multipoint sound object is rotated when the multipoint sound object rotates with respect to the user. 13. The method of claim 12,
The sound source control unit,
Wherein the position of the sound source and the directivity characteristic of the sound source are shifted according to a relative distance between the multi-sound source object and the user when the relative distance between the multi-sound source object and the user changes. 13. The method of claim 12,
Wherein the multi-polar acoustic sound object setting unit comprises:
Wherein a plurality of sound sources are arranged around a position of a multipurpose acoustic object and the directional characteristics of the plurality of sound sources are used to set the multipurpose sound object. 18. The method of claim 17,
The sound source control unit,
And controlling the relative distance between the plurality of sound sources to control the volume of the multi-pole sound object. 18. The method of claim 17,
The sound source control unit,
And when the relative distance between the multipurpose acoustic object and the user exceeds a threshold value, downmixing the plurality of sound sources into one sound source, and using the at least one directional characteristic of the one sound source and the one sound source, . 13. The method of claim 12,
Wherein the multi-polar acoustic sound object setting unit comprises:
A sound control apparatus for arranging a plurality of sound sources in a three-dimensional form to set the multi-pole sound object in the form of a volume sound source.

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