JP6937334B2 - Acoustic signal formers, acoustic receivers, and acoustic systems - Google Patents

Description

The present invention relates to an acoustic signal forming device, an acoustic receiving device, and an acoustic system that transmit information together with audio.

As an acoustic system, the technique described in Patent Document 1 is known. The acoustic system described in Patent Document 1 broadcasts identification information together with an acoustic signal, and an acoustic receiver (portable terminal) that receives (receives) this broadcast extracts the identification information from the broadcast sound and the identification information. The information related to is presented to the user.

Japanese Unexamined Patent Publication No. 2012-227921

By the way, when broadcasting is heard from a plurality of broadcasting sources, the above-mentioned receiving device receives an acoustic signal from each of them. Then, a plurality of identification information (embedded information) will be mixed in the received signal, and there is a risk that appropriate identification information cannot be extracted from the received signal.

Therefore, an acoustic signal forming device, an acoustic receiving device, and an acoustic system capable of extracting appropriate embedded information even when a plurality of embedded information are mixed in the received signal are provided.

(1) An acoustic system that solves the above problems is an acoustic system that causes an acoustic receiver to acquire embedded information embedded in a broadcast sound, and the broadcast sound is based on a diffusion code that differs depending on the broadcast source. Then, the embedded information is embedded.

According to the above configuration, the embedded information is embedded in the broadcast sound based on the diffusion code. The embedded information embedded in the broadcast sound is extracted by the diffusion code used for embedding, but the embedded information embedded in the broadcast sound is not extracted by the diffusion code not used for embedding. Further, in the above configuration, the spreading code differs depending on the broadcasting source. Therefore, even when a plurality of broadcast sounds propagate in the same space, only the predetermined embedded information can be extracted by using the predetermined diffusion code when extracting the embedded information. In this way, mixing of embedded information can be suppressed. That is, when a plurality of broadcast sounds propagate in the same space, a plurality of embedded information is mixed in the received signal, and even in such a case, appropriate embedded information can be extracted.

(2) The sound receiving device that solves the above problems includes a receiving unit that receives the broadcast sound, an extraction unit that extracts embedded information from the broadcast sound, and a code assigned to the broadcast source that is embedded from the broadcast sound. The extraction unit includes a storage unit that stores a diffusion code used when extracting information, and the extraction unit extracts the embedded information from the broadcast sound based on the diffusion code. According to this configuration, since individual diffusion codes are assigned to each broadcasting source, mixing of embedded information can be suppressed.

(3) In the sound receiving device, the storage unit stores an obfuscated file formed by the obfuscation process of the diffusion code, and the extraction unit acquires the diffusion code by decoding the obfuscation file. .. According to this configuration, the diffusion code can be kept secret.

(4) In the sound receiving device, the obfuscated file includes a check digit for checking an error in the obfuscated file. With this configuration, obfuscated file errors can be detected.

(5) An acoustic signal forming device that solves the above problems, the first acquisition unit that acquires an audio signal, the second acquisition unit that acquires embedded information, and a broadcast sound having different codes for each broadcasting source. A storage unit that stores a diffusion code used when embedding embedded information in the sound signal and an embedding unit that embeds the embedded information in the audio signal based on the diffusion code are provided. According to this configuration, the embedded information is embedded in the broadcast sound based on the diffusion code different for each broadcasting source, so that the mixing of the embedded information can be suppressed.

(6) In the acoustic signal forming apparatus, the storage unit stores an obfuscated file formed by the obfuscation process of the diffused code, and the embedded unit decodes the obfuscated file to obtain the diffused code. get. According to this configuration, the diffusion code can be kept secret.

(7) In the acoustic signal forming apparatus, the obfuscated file includes a check digit for checking an error in the obfuscated file. With this configuration, obfuscated file errors can be detected.

The acoustic signal forming device, the acoustic receiving device, and the acoustic system can suppress the mixing of the embedded information.

Schematic diagram of the acoustic system. A relationship diagram showing the relationship between the management company and the broadcasting source. Block diagram of the sound receiver. A table that associates embedded information with provided information. The block diagram of the acoustic signal forming apparatus. A table showing the relationship between the broadcast source, the diffusion code, the audio signal, and the embedded information.

The acoustic system will be described with reference to FIGS. 1 to 6.
The sound system 1 causes the sound receiving device 10 to acquire the embedded information SC embedded in the broadcast sound AS. The embedded information SC is embedded in the broadcast sound AS based on the diffusion code SD that is different for each broadcast source CB. In the present embodiment, the embedded information SC is associated with the provided information associated with the broadcast of the broadcast source CB. The sound receiving device 10 acquires the embedded information SC, and acquires the provided information associated with the broadcast of the broadcasting source CB based on the embedded information SC.

As shown in FIG. 1, the user receives the broadcast sound AS by the sound receiving device 10 (see below). For example, the user receives the broadcast sound AS of the first broadcast source CB broadcast from the speaker 2a of the station by the sound receiving device 10, or the user receives the broadcast sound AS of the second broadcast source CB emitted from the speaker 2b in the store. Receives broadcast sound AS. Examples of the sound receiving device 10 include a mobile phone, a smartphone, and a notebook computer. The sound receiving device 10 acquires the provided information associated with the broadcast of the broadcast source CB based on the embedded information SC embedded in the broadcast sound AS. In this way, the user who uses the sound receiving device 10 can receive the provided information related to the broadcasting of the broadcasting source CB.

The broadcasting source CB is a device that manages and supplies information on services provided by an organization or an individual to which the spreading code SD described later is assigned. It should be noted that one operator may include a plurality of broadcasting source CBs. For example, there may be a broadcasting source CB for each department of the business operator that operates the store.

The provided information is information related to broadcasting of the broadcasting source CB. The storage location of the provided information is not limited. In one example, the provided information is stored in a server on the Internet IN. In another example, the provided information is stored in the acoustic receiver 10. An example of the information provided is given below. In the case of the broadcasting source CB used in store management, the provided information is the detailed contents of the products in the store. When the broadcast source CB is used by the local government, the provided information is a map showing the place to evacuate in the event of a disaster. When the broadcast source CB is used by the operator of the exhibition, the provided information is information indicating the details of the exhibit. The provided information may be link information (for example, URL: Uniform Resource Locator) indicating a place where detailed information is stored. In the present embodiment, the provided information is output to the user's sound receiving device 10 as a URL on the Internet IN (see FIG. 4).

One diffusion code SD is assigned to each broadcast source CB. The diffusion code SD is associated with the broadcast source CB in a one-to-one relationship. That is, the spreading code SD possessed by the broadcasting source CB is different from any of the spreading code SD possessed by other broadcasting source CBs. One operator may be assigned to a plurality of spread codes SD. In this case, there are a plurality of broadcasting source CBs having one diffusion code SD in one business operator.

Broadcast sound AS is a sound wave including frequencies in the audible range. The embedded information SC is embedded in the broadcast sound AS by a digital watermark. The broadcast sound AS is broadcast from the broadcasting device. Examples of broadcast sound AS include announcements, alarms, general or visually impaired sound signs, background music (BGM), explanatory audio output at museums and exhibitions, and broadcast programs.

The embedded information SC is information associated with the provided information. The embedded information SC is embedded in the broadcast sound AS. In the present embodiment, the embedded information SC is identification information linked to the provided information associated with the broadcast of the broadcast source CB (see FIG. 4).

The diffusion code SD is a code assigned to the broadcasting source CB as described above. The diffusion code SD is used when the embedded information SC is extracted from the broadcast sound AS. The embedding method is not limited. For example, the embedded information SC is embedded in the broadcast sound AS by the echo diffusion method or the spread spectrum method. In the present embodiment, the embedded information SC is embedded in the broadcast sound AS by the echo diffusion method. The diffusion code SD is also used when the embedded information SC is taken out from the broadcast sound AS in which the embedded information SC is embedded. When the embedded information SC is taken out from the broadcast sound AS in which the embedded information SC is embedded, the same diffusion code SD as the diffusion code SD used when embedding the embedded information SC in the broadcast sound AS is used.

The diffusion code SD may be any code as long as it is a code that is assigned differently to the plurality of broadcasting source CBs. For example, a PN (Pseudo Noise) code is used as the diffusion code SD.

The diffusion code SD is preferably obfuscated. This is because if the spread code SD is known to others, it may be tampered with by malicious intent. For example, in the sound receiving device 10, if the diffusion code SD used when extracting the embedded information SC is falsified, the embedded information SC cannot be extracted from the broadcast sound AS.

In one example, the diffusion code SD is obfuscated by obfuscation processing so that it is difficult to read. In the present embodiment, the file in which the diffusion code SD is formed by the obfuscation process is referred to as "obfuscation file FA". The obfuscation process indicates that the diffusion code SD is converted into an obfuscation code. Obfuscation code conversion is performed by using software that creates various obfuscation codes.

The obfuscated file FA preferably contains a check digit. The check digit is a code for detecting an error in the obfuscated file FA. When the spread code SD is used, the check digit checks for errors in the obfuscated file FA, and when there are no errors, the obfuscated file FA is decoded by the decoding application, and the spread code SD is extracted from the decoded information.

The obfuscated file FA is preferably managed by one management company CA. The management business operator CA may be one business entity or a consortium in which a plurality of business entities participate.

As shown in FIG. 2, in one example, the management company CA assigns the obfuscated file FA to the broadcasting source CB. As a result, a separate spreading code SD is assigned to each broadcasting source CB. Further, it is preferable that the management company CA provides a decoding application capable of decoding the obfuscated file FA together with the obfuscated file FA. The management company CA may install a sound forming application for embedding the embedded information SC in the broadcast sound AS in the broadcast source CB.

The sound receiving device 10 will be described with reference to FIGS. 3 and 4.
The sound receiving device 10 includes a receiving unit 11 for receiving the broadcast sound AS, an extraction unit 12 for extracting the embedded information SC from the broadcast sound AS, and a storage unit 13.

The storage unit 13 stores the diffusion code SD. In the present embodiment, the storage unit 13 stores the obfuscated file FA. Further, the storage unit 13 stores a reference table (see FIG. 4). The reference table is a table that associates the embedded information SC with the provided information. Preferably, the sound receiving device 10 further includes an information acquisition unit 14.

The extraction unit 12 extracts the embedded information SC from the broadcast sound AS in which the embedded information SC is embedded based on the diffusion code SD.
The extraction unit 12 acquires the diffusion code SD by decoding the obfuscated file FA. Preferably, the obfuscated file FA comprises a check digit, as described above. In this case, the extraction unit 12 checks the obfuscated file FA based on the check digit.

The extraction unit 12 is composed of a decoding application installed in the sound receiving device 10 and an arithmetic device of the sound receiving device 10. The decoding application includes a check unit, a decoding unit, and a decoding unit.

The check unit checks whether or not the obfuscated file FA contains an error.
The decoding unit decodes the obfuscated file FA and extracts the spread code SD from the decoded obfuscated file FA. The decoding unit extracts the embedded information SC from the broadcast sound AS based on the diffusion code SD. When the embedded information SC is embedded by the echo diffusion method, the decoding unit converts the broadcast sound AS into cepstrum and correlates the signal after the cepstrum conversion with the diffusion code SD to obtain the embedded information SC. Take it out.

The information acquisition unit 14 acquires the provided information associated with the embedded information SC by referring to the reference table shown in FIG. Specifically, the information acquisition unit 14 is composed of an information acquisition application and an arithmetic unit of the sound receiving device 10. The information acquisition application acquires the provided information corresponding to the embedded information SC from the reference table.

A reference table is created for each broadcast source CB. That is, as shown in FIG. 4, a reference table is created for each diffusion code SD. The association between the identification number as the embedded information SC and the provided information in the reference table is set by the broadcasting source CB. In one example, there are multiple broadcast sound ASs (for example, tsunami warning, wave warning, earthquake warning) as disaster warnings, and provided information (for example, URL indicating an evacuation site corresponding to each disaster) is set for each disaster. In this case, the broadcast sound AS, the identification number as the embedded information SC, and the provided information are related as follows. A different identification number is embedded in each broadcast sound AS. The identification number and the provided information are associated with each other by a reference table. With this configuration, each of the various broadcast sound ASs is associated with the provided information via the embedded information SC.

The acoustic signal forming apparatus 20 will be described with reference to FIG.
The acoustic signal forming device 20 forms the broadcast sound AS used in the above-mentioned acoustic system 1. The broadcast sound AS is a signal in which the embedded information SC is embedded based on the diffusion code SD that is different for each broadcast source CB. In one example, the acoustic signal forming device 20 outputs the broadcast sound AS as a sound file to another device. The acoustic signal forming device 20 may be built in a device that outputs broadcast sound AS as sound waves. For example, the acoustic signal forming device 20 is built in the broadcasting device.

The acoustic signal forming device 20 is based on the first acquisition unit 21 that acquires the audio signal BS, the second acquisition unit 22 that acquires the embedded information SC, the storage unit 23 that stores the diffusion code SD, and the diffusion code SD. It is provided with an embedding unit 24 for embedding the embedded information SC in the audio signal BS.

The storage unit 23 stores the obfuscation file FA formed by the obfuscation processing of the diffusion code SD. Preferably, the obfuscated file FA comprises a check digit, as described above. The storage unit 23 may store the audio signal BS.

The embedding unit 24 acquires the diffusion code SD by decoding the obfuscated file FA. Preferably, the embedding unit 24 checks the obfuscated file FA based on the check digit. The embedding unit 24 is composed of an embedded application installed in the acoustic signal forming apparatus 20 and an arithmetic unit of the acoustic signal forming apparatus 20. The embedded application includes a check unit, a decoding unit, and an encoding unit.

The check unit checks whether or not the obfuscated file FA contains an error. The decoding unit decodes the obfuscated file FA and extracts the spread code SD from the decoded obfuscated file FA. The encoding unit embeds the embedded information SC in the audio signal BS based on the diffusion code SD. When the embedded information SC is embedded by the echo diffusion method, the encoding unit forms a kernel in which the embedded information SC is diffused in the time domain by the diffusion code SD, and embeds the kernel in the audio signal BS. The encoding unit outputs the audio signal BS in which the kernel as the embedded information SC is embedded as the broadcast sound AS.

The relationship between the broadcasting source CB, the diffusion code SD, the audio signal BS, and the embedded information SC will be described with reference to FIG.
As shown in FIG. 6, one spreading code SD is assigned to one broadcasting source CB. The audio signal BS is set by the broadcasting source CB. For a plurality of audio signal BSs used by one broadcasting source CB, one diffusion code SD is used for embedding the information of these audio signal BSs. Individual embedded information SCs are embedded for each of the audio signal BSs. The same embedded information SC may be embedded in different audio signal BSs.

The identification number as the embedded information SC is set within a predetermined range. For example, the identification number is represented by a 16-bit code string. In this case, the broadcasting source CB can use about 64K identification numbers.

The operation of this embodiment will be described.
As the embedded information SC embedded in the broadcast sound AS, an identification number (embedded information SC) represented by a 16-bit code string is used in any broadcasting source CB. Therefore, it is assumed that a plurality of broadcasting source CBs use the same identification number (embedded information SC). Even in such a case, the spread code SD that can be used by one broadcast source CB is different from any of the spread code SD used by the other broadcast source CB. Therefore, by decoding from the broadcast sound AS with the predetermined diffusion code SD, only the embedded information SC embedded by the predetermined diffusion code SD can be extracted. That is, only the embedded information SC embedded by the specific broadcasting source CB can be acquired. In this way, even if a plurality of broadcasting source CBs use the same identification number (embedded information SC), it is possible to prevent the identification numbers (embedded information SC) from being mixed on the receiving side receiving the broadcast sound AS. NS.

The effect of this embodiment will be described.
(1) The sound system 1 is a system that causes the sound receiving device 10 to acquire the embedded information SC embedded in the broadcast sound AS. The embedded information SC is embedded in the broadcast sound AS based on the diffusion code SD that is different for each broadcast source CB.

According to the above configuration, the embedded information SC is embedded in the broadcast sound AS based on the diffusion code SD. The embedded information SC embedded in the broadcast sound AS is extracted by the diffusion code SD used for embedding, but the embedded information SC embedded in the broadcast sound AS is extracted by the diffusion code SD not used for embedding. Not extracted. Further, in the above configuration, the diffusion code SD is different for each broadcasting source CB. Therefore, even when a plurality of broadcast sound ASs propagate in the same space, only the embedded information SC of the predetermined broadcast source CB can be extracted by using the predetermined diffusion code SD when extracting the embedded information SC. Can be done. In this way, mixing of embedded information SC can be suppressed. That is, when a plurality of broadcast sound AS propagates in the same space, a plurality of embedded information SCs are mixed in the received signal, and even in such a case, appropriate embedded information can be extracted.

(2) The sound receiving device 10 includes a receiving unit 11, an extracting unit 12 for extracting the embedded information SC from the broadcast sound AS, and a storage unit 13 for storing the diffusion code SD. The spread code SD is assigned to each broadcast source CB. The extraction unit 12 extracts the embedded information SC from the broadcast sound AS based on the diffusion code SD. According to this configuration, since an individual diffusion code SD is assigned to each broadcasting source CB, mixing of embedded information SC can be suppressed.

(3) The storage unit 13 of the sound receiving device 10 stores the obfuscation file FA formed by the obfuscation processing of the diffusion code SD. The extraction unit 12 acquires the diffusion code SD by decoding the obfuscated file FA. According to this configuration, the spread code SD can be kept secret.

(4) The obfuscated file FA includes a check digit for checking for an error in the obfuscated file FA. According to this configuration, an error in the obfuscated file FA can be detected.
(5) The acoustic signal forming device 20 includes a first acquisition unit 21 for acquiring the audio signal BS, a second acquisition unit 22 for acquiring the embedded information SC, a storage unit 23 for storing the diffusion code SD, and a diffusion code. It includes an embedding unit 24 that embeds the embedding information SC in the audio signal BS based on the SD. The diffusion code SD is different for each broadcasting source CB. According to this configuration, since the embedded information SC is embedded in the broadcast sound AS based on the diffusion code SD different for each broadcasting source CB, mixing of the embedded information SC can be suppressed.

(6) In the acoustic signal forming apparatus 20, the storage unit 23 stores the obfuscated file FA formed by the obfuscation processing of the diffusion code SD. The embedding unit 24 acquires the diffusion code SD by decoding the obfuscated file FA. According to this configuration, the spread code SD can be kept secret.

(7) In the acoustic signal forming apparatus 20, the obfuscated file FA includes a check digit for checking an error of the obfuscated file FA. According to this configuration, an error in the obfuscated file FA can be detected.

<Other Embodiments>
This embodiment can be modified and implemented as follows. The present embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.

-In the above embodiment, one embedded information SC is embedded in one audio signal BS, but a plurality of embedded information SCs may be embedded in one audio signal BS.
-In the above embodiment, one spreading code SD is assigned to one broadcasting source CB, but one spreading code SD may be assigned to a plurality of businesses. In this case, in the present technology, since a plurality of businesses use one common diffusion code SD, they are regarded as one broadcasting source CB.

AS ... Broadcast sound, BS ... Audio signal, CA ... Management company, CB ... Broadcast source, FA ... Obfuscated file, IN ... Internet, SC ... Embedded information, SD ... Diffusion code, 1 ... Sound system, 2a ... Speaker, 2b ... speaker, 10 ... sound receiving device, 11 ... receiving unit, 12 ... extracting unit, 13 ... storage unit, 14 ... information acquisition unit, 20 ... acoustic signal forming device, 21 ... first acquisition unit, 22 ... second acquisition Department, 23 ... Storage part, 24 ... Embedded part.

Claims (5)

It is an acoustic receiver
A receiver that receives broadcast sound from the broadcast source,
An application provided for acquiring information from a broadcast sound emitted from the broadcast source, a decoding application that is pre-installed in the sound receiving device and decodes an obfuscated file associated with the broadcast source.
An extraction unit that extracts embedded information from the broadcast sound received by the reception unit, and an extraction unit.
A storage unit for storing the obfuscated file provided for acquiring the broadcast sound emitted from the broadcast source is provided.
The obfuscation file, the file that is formed by processing obfuscate spreading code used when assigned to each of said broadcast source to retrieve the embedded information from the broadcast sound of a different code for each of the broadcast source And
The extraction unit is an acoustic receiving device that acquires the diffusion code by decoding the obfuscated file with the decoding application and extracts the embedded information from the broadcast sound based on the acquired diffusion code. The audio receiving device according to claim 1, wherein the obfuscated file includes a check digit for checking an error in the obfuscated file. An acoustic signal forming device installed in a broadcasting source.
The first acquisition unit that acquires the audio signal,
The second acquisition unit that acquires embedded information,
A storage unit that stores an obfuscated file associated with the broadcasting source, which is a file provided for embedding the embedded information in the audio signal.
An application provided for embedding the embedded information in the audio signal, which is pre-installed in the acoustic signal forming apparatus and a decoding application for decoding the obfuscated file.
It is provided with an embedding unit that embeds the embedding information acquired by the second acquisition unit into the voice signal acquired by the first acquisition unit.
The obfuscation file is a file that is assigned to each broadcasting source and has a different code for each broadcasting source and is formed by obfuscation processing of a diffusion code used when embedding the embedded information in the audio signal. And
The embedded unit is an acoustic signal forming device that acquires the diffusion code by decoding the obfuscated file by the decoding application and embeds the embedded information in the audio signal based on the acquired diffusion code. The acoustic signal forming apparatus according to claim 3, wherein the obfuscated file includes a check digit for checking an error in the obfuscated file. An acoustic system including a broadcasting source including the acoustic signal forming apparatus according to claim 3 or 4, and an acoustic receiving device for receiving broadcast sound emitted from the broadcasting source.
The sound receiving device is
A receiver that receives the broadcast sound emitted from the broadcast source, and
An application provided for acquiring information from the broadcast sound emitted from the broadcast source, a decoding application that is pre-installed in the sound receiving device and decodes an obfuscated file associated with the broadcast source.
An extraction unit that extracts embedded information from the broadcast sound received by the reception unit, and an extraction unit.
A storage unit for storing the obfuscated file is provided.
The obfuscation file is a file that is assigned to each broadcasting source and has a different code for each broadcasting source and is formed by obfuscation processing of a diffusion code used for extracting the embedded information from the broadcasting sound. can be,
The extraction unit is an acoustic system that acquires the diffusion code by decoding the obfuscated file with the decoding application and extracts the embedded information from the broadcast sound based on the acquired diffusion code.

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