JP2002218598A - Sound image localizing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sound image localizing device that is realized with a small memory capacity without the need for measuring the head impulse responses in every direction. SOLUTION: A sound image direction setting section 101 sets the direction in a three-dimensional space which allows a listener to perceive the sound image and calculates a side angle α and an elevating angle β from the set three-dimensional direction. Side angle control information is obtained from a side angle control information storage section 103 depending on the side angle αand stored in a convolution arithmetic section 106, elevating angle control information is obtained from an elevating angle control information storage section 104 depending on the elevating angle β and stored in the convolution arithmetic section 106, a headphone inverse characteristic information storage section 105 stores headphone inverse characteristic information to the convolution arithmetic section 106, coefficients stored in the convolution arithmetic section 106 are convoluted on the sound source signal to generate the right ear signal and the left ear signal, which are reproduced by a headphone.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an arbitrary set 3
The present invention relates to a sound image localization device that generates a sound image in a dimensional direction.

[0002]

2. Description of the Related Art A conventional sound image localization apparatus is disclosed, for example, in Japanese Patent No. 2741817.

FIG. 14 shows a configuration diagram of a conventional sound image localization apparatus.

As shown in FIG. 14, this sound image localization apparatus includes an A / D conversion unit 11, a convolution operation unit 12, a D /
An A conversion unit 13, a sound source storage unit 14, a spatial impulse response storage unit 15, a headphone reverse impulse response storage unit 16, and an input switch 17 are provided.

Next, the operation of the conventional sound image localization apparatus will be described.

The input of the A / D converter 11 is connected to a test sound source. The convolution operation unit 12 includes a left ear convolution operation unit (l) 12L and a right ear convolution operation unit (r) 1
Each output is converted into an analog signal by each channel of the D / A converter 13 having two channels, and is output to binaural headphones including an earplug type and an inner earphone type.

[0007] The convolution data in the spatial impulse response storage unit 15 and the convolution data in the headphone inverse impulse response storage unit 16 are selected by the user and set as filter coefficients of the convolution operation unit 12. Soil (t) of the spatial impulse response storage unit 15 is the median plane, the left ear, the i-th response, Soir (t) is the median plane, the right ear, the i-th response, Sdir (t) is the direction d, the left ear, The i-th response, H ⁻¹ i (t), represents the response of the headphone with the opposite characteristic.

The input of the convolution operation unit 12 can be connected to the digital conversion output of the A / D conversion unit 11 or the output of the sound source storage unit 14 by switching via a changeover switch 17.

As described above, even in the conventional sound image localization apparatus, the sound image can be localized by convoluting the spatial impulse response and the headphone reverse impulse response corresponding to the direction in which the sound image is to be localized in the sound source signal.

[0010]

However, in the above-described conventional sound image localization apparatus, a spatial impulse response, that is, a head impulse response must be measured for each direction in which a sound image is to be localized, and stored. In addition, there is a problem that not only a large amount of time and labor is required for the measurement but also a large storage capacity is required for the device.

The present invention has been made to solve such a conventional problem, and provides a sound image localization apparatus which can be realized with a small storage capacity without measuring head impulse responses in all directions. Is what you do.

[0012]

A sound image localization apparatus according to the present invention comprises: a sound image direction setting section for setting a direction in which a sound image is generated; and an angle conversion section for converting the set sound image direction into a lateral angle and a rising angle. A side angle control information storage unit that stores in advance the side angle control information corresponding to the side angle and outputs the side angle control information when the side angle is input from the angle conversion unit, and a rising angle control corresponding to the rising angle An elevation angle control information storage unit that stores information in advance and outputs the elevation angle control information when the elevation angle is input from the angle conversion unit, a storage unit for headphone reverse characteristic information, the side angle control information, and the elevation angle A convolution operation unit for convolving the angle control information and the headphone inverse characteristic information with the sound source signal.

Therefore, the sound image localization apparatus of the present invention converts a direction in which a sound image is to be localized into a lateral angle and an elevation angle, calls up the lateral angle control information and the elevation angle control information, and performs a convolution operation on the sound source signal. By doing so, the measurement can be easily performed without measuring the head impulse response in all directions, and the sound image can be localized with a small storage capacity.

Further, in the sound image localization apparatus of the present invention, the lateral angle control information stored in the lateral angle control information storage section is a binaural time difference, and the elevation angle control information stored in the elevation angle control information storage section. Is a median head impulse response.

Therefore, the sound image localization apparatus of the present invention converts the direction in which the sound image is to be localized into the lateral angle and the elevation angle, and the interaural time difference corresponding to the lateral angle and the median frontal impulse response corresponding to the elevation angle. Is called and the convolution operation is performed on the sound source signal, so that the measurement can be easily performed without measuring the head impulse responses in all directions, and the sound image can be localized with a small storage capacity.

Further, in the sound image localization apparatus according to the present invention, the lateral angle control information stored in the lateral angle control information storage unit is a binaural level difference, and the elevation angle control stored in the elevation angle control information storage unit. The information is a median head impulse response.

Accordingly, the sound image localization apparatus of the present invention converts the direction in which the sound image is to be localized into the lateral angle and the elevation angle, and the binaural level difference corresponding to the lateral angle and the median head impulse corresponding to the elevation angle. By calling the response and performing convolution operation on the sound source signal, measurement is easy without measuring the head impulse response in all directions, and
A sound image can be localized with a small storage capacity.

Further, in the sound image localization apparatus according to the present invention, the lateral angle control information stored in the lateral angle control information storage unit is a binaural time difference and a binaural level difference, and is stored in the elevation angle control information storage unit. The rising angle control information is a median head impulse response.

Therefore, the sound image localization apparatus of the present invention converts the direction in which the sound image is to be localized into the lateral angle and the elevation angle, and the binaural time difference corresponding to the lateral angle and the median corresponding to the interaural level difference and the elevation angle. By calling the plane impulse response and performing convolution operation on the sound source signal, the measurement can be easily performed without measuring the head impulse response in all directions, and the sound image can be localized with a small storage capacity. .

[0020]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a configuration diagram of a sound image localization apparatus according to an embodiment of the present invention.

The sound image localization apparatus of the present invention comprises: a sound image direction setting unit 101 for setting a direction in which a sound image is to be localized; an angle conversion unit 102 for converting a sound image direction into a lateral angle α and a rising angle β;
A side angle control information storage unit 103 for storing information for controlling a side angle of a sound image, a rising angle control information storage unit 104 for storing information for controlling a rising angle of a sound image, and a headphone reverse unit for storing reverse characteristic information of headphones. A characteristic information storage unit 105;
It is configured by a convolution operation unit 106 that takes a sound source signal as an input signal and convolves the side angle control information, the elevation angle control information, and the headphone reverse characteristic information with the input signal. Convolution operation unit 10
The output of No. 6 is output to headphones including an earplug type and an inner earphone type.

The lateral angle control information storage unit 103 stores the interaural time difference, the interaural level difference, or both the interaural time difference and the interaural level difference as the lateral angle control information. Is convolved with the sound source signal.

The elevation angle control information storage unit 104 stores the median head impulse response as elevation angle control information, and is convolved with the sound source signal by the convolution operation unit 106.

FIG. 2 shows an example in which the interaural time difference is used as the lateral angle control information.

FIG. 2 shows a standard adult value as the interaural time difference corresponding to the lateral angle of an adult, but when the listener is specified, the interaural time difference of the individual listener is measured. Then, the measured value can be given.

FIG. 3 shows an example in which the interaural level difference is used as the lateral angle control information.

FIG. 3 shows a standard adult value as the interaural level difference corresponding to the lateral angle of the adult. However, when the listener is specified, the interaural level difference of the individual listener is determined. Can be measured to give the measured value.

FIG. 4 shows an example in which the interaural time difference and the interaural level difference are used as lateral angle control information.

FIG. 4 shows a standard adult value as the interaural time difference and interaural level difference corresponding to the lateral angle of the adult. However, when the listener is specified, the listener's individual It is also possible to measure the interaural time difference and the interaural level difference and provide these measurements.

FIG. 5 shows an example in which the median head impulse response is used as the elevation angle control information.

As the median head impulse response, an adult standard one may be used, or when the listener is specified, the median head impulse response of the individual listener is measured and the measurement is performed. You can give it a value.

Next, the operation of the sound image localization apparatus according to the embodiment of the present invention will be described with reference to FIGS.

In FIG. 1, a sound image direction setting unit 101 sets a three-dimensional direction in which a sound image is to be localized. The coordinate system for setting the three-dimensional direction may be arbitrary. Angle converter 102
Side angle α and rise angle β at which a person perceives the three-dimensional sound image direction
Convert to

FIG. 6 is a diagram showing the relationship between the lateral angle α and the rising angle β expressing the three-dimensional direction and the polar coordinates (azimuth angle ψ and elevation angle θ). As shown in FIG. When the direction is set by the polar coordinates (azimuth angle ψ and elevation angle θ) used in the setting, the angle is converted into the side angle α and the ascending angle β using Expression (1). α = arccos (sinψcosθ) β = arcsin (sinθ / (sin 2 θ + cos 2 ψcos 2 θ) 1/2) (1) side direction side angle control information corresponding to the alpha, i.e. side angle alpha
Either the interaural time difference or the interaural level difference corresponding to
Alternatively, both are called from the lateral direction control information storage unit 103 and stored in the convolution operation unit 106. Further rise angle β
Is stored in the ascending angle control information storage unit 1, that is, the median head impulse response corresponding to the ascending angle β.
04, and stored in the convolution operation unit 106.
Further, the inverse characteristic information of the headphone used at the time of listening is retrieved from the headphone inverse characteristic information storage unit 105 and stored in the convolution operation unit 106. The convolution operation unit 106 performs a convolution operation on the sound source signal and the side angle control information, the side angle control information, and the inverse characteristic information of the headphones to create a right ear signal and a left ear signal, and output the signals to the headphones.

Next, an example in which sound image localization in a three-dimensional direction is performed based on the side angle control information and the rising angle control information will be described.

FIGS. 7 to 13 show three-dimensional sound image localization using the listener's own binaural time difference as lateral angle control information and the listener's own median head impulse response as elevation angle control information. The result of having performed the following is shown.

FIGS. 7 to 13 show the localization results for each elevation angle at which the sound image is to be localized. The horizontal axis is the presentation side angle at which the sound image is to be localized, and the vertical axis is the response after the listener perceives the sound image. The answer is the side direction.

FIG. 7 shows a case where the rising angle is 0 degree, and FIG.
FIG. 9 shows a case where the ascending angle is 30 degrees, and FIG.
FIG. 10 shows a case where the rising angle is 90 degrees, FIG. 11 shows a case where the rising angle is 120 degrees, and FIG.
2 shows a case where the rising angle is 150 degrees, and FIG. 13 shows a case where the rising angle is 180 degrees.

In each figure of the rising angles, the answers are distributed in the vicinity of the diagonal line, and the presentation side angle and the answer side angle match well. In addition, not only the interaural time difference but also the binaural level difference is used as the lateral angle control information.
Alternatively, even when both the interaural time difference and the interaural level difference are used, three-dimensional sound image localization can be realized.

If the three-dimensional space is divided into m directions in the horizontal direction and n directions in the vertical direction, and the sound image is localized in any of m × n combinations, the conventional sound image localization apparatus has Although head impulse responses are required in all directions of the mxn combination, the sound image localization apparatus of the present invention requires m pieces of lateral angle control information, that is, any of the interaural time difference information and the interaural level difference information. Either or both, a head impulse response in the n-direction in the median plane is sufficient, and a sound image can be localized without measuring head impulse responses in all directions and with a small storage capacity.

[0042]

According to the sound image localization apparatus of the present invention, a sound image direction setting unit for setting a direction in which a sound image is generated, an angle conversion unit for converting the set sound image direction into a lateral angle and a rising angle, Corresponding side angle control information is stored in advance, and the side angle control information storage unit that outputs the side angle control information when the side angle is input from the angle conversion unit, and the elevation angle control information corresponding to the elevation angle is stored in advance. The rising angle control information storage unit that outputs the rising angle control information when the rising angle is input from the angle conversion unit, a headphone reverse characteristic information storage unit, the side angle control information and the rising angle control information, A convolution operation unit for convolving the headphone inverse characteristic information with the sound source signal.

Accordingly, the sound image localization apparatus of the present invention converts the direction in which the sound image is to be localized into the lateral angle and the elevation angle, calls the lateral angle control information and the elevation angle control information, and performs a convolution operation on the sound source signal. By doing so, the measurement can be easily performed without measuring the head impulse response in all directions, and the sound image can be localized with a small storage capacity.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a sound image localization device according to an embodiment of the present invention.

FIG. 2 is a diagram showing an example in which a binaural time difference is used as lateral angle control information;

FIG. 3 is a diagram showing an example in which a binaural level difference is used as lateral angle control information;

FIG. 4 is a diagram showing an example in which an interaural time difference and an interaural level difference are used as lateral angle control information.

FIG. 5 is a diagram showing an example in which a median head impulse response is used as rise angle control information;

FIG. 6 shows a lateral angle α and a rising angle β expressing a three-dimensional direction.
Diagram showing the relationship between and the polar coordinates (azimuth angle ψ and elevation angle θ)

FIG. 7 is a diagram showing a result of performing sound image localization in a three-dimensional direction with a rising angle of 0 degree.

FIG. 8 is a diagram showing a result of performing sound image localization in a three-dimensional direction with an ascending angle of 30 degrees.

FIG. 9 is a diagram showing a result of performing sound image localization in a three-dimensional direction with a rising angle of 60 degrees.

FIG. 10 is a diagram showing a result of performing sound image localization in a three-dimensional direction with an ascending angle of 90 degrees.

FIG. 11 is a diagram illustrating a result of performing sound image localization in a three-dimensional direction with an ascending angle of 120 degrees.

FIG. 12 is a diagram showing a result of performing sound image localization in a three-dimensional direction with a rising angle of 150 degrees.

FIG. 13 is a diagram showing a result of performing sound image localization in a three-dimensional direction with a rising angle of 180 degrees.

FIG. 14 is a configuration diagram of a conventional sound image localization apparatus.

[Explanation of symbols]

 Reference Signs List 11 A / D conversion unit 12 Convolution operation unit 13 D / A conversion unit 14 Sound source storage unit 15 Spatial impulse response storage unit 16 Headphone reverse impulse response storage unit 101 Sound image direction setting unit 102 Angle conversion unit 103 Side angle control information storage unit 104 Rise angle control information storage unit 105 Headphone reverse characteristic storage unit 106 Convolution operation unit

Claims (4)

[Claims] 1. A sound image direction setting unit for setting a direction in which a sound image is generated, an angle conversion unit for converting the set sound image direction into a lateral angle and a rising angle, and a lateral angle control information corresponding to the lateral angle in advance. A side angle control information storage unit that stores and outputs the side angle control information when the side angle is input from the angle conversion unit, and stores in advance the ascending angle control information corresponding to the ascending angle and the ascending angle from the angle converting unit. A rising angle control information storage unit that outputs the rising angle control information when an angle is input; a storage unit for headphone reverse characteristic information; and a sound source that stores the side angle control information, the rise angle control information, and the headphone reverse characteristic information. A sound image localization device comprising: a convolution operation unit that performs a convolution operation on a signal. 2. The lateral angle control information stored in the lateral angle control information storage unit is a binaural time difference, and the elevation angle control information stored in the elevation angle control information storage unit is a median plane head impulse response. The sound image localization apparatus according to claim 1, wherein: 3. The lateral angle control information stored in the lateral angle control information storage unit is a binaural level difference, and the elevation angle control information stored in the elevation angle control information storage unit is a median head impulse response. The sound image localization apparatus according to claim 1, wherein: 4. The lateral angle control information stored in the lateral angle control information storage unit is a binaural time difference and a binaural level difference, and the elevation angle control information stored in the elevation angle control information storage unit is a median. 2. The sound image localization apparatus according to claim 1, wherein the sound head localization is a face head impulse response.