KR102653784B1 - Contactless certification system using one time waves and method thereof - Google Patents

Abstract

The authentication system, which is connected to a sound wave transmitting device and a sound wave receiving device and uses one-time sound waves, generates a sound source to be used as the one-time sound wave (OTW), and partially overlaps a plurality of OTWs pre-stored in the OTW pool and the generated sound source. An OTW pool generator that stores sound sources selected through detection; an OTW mapping unit that maps authentication information to be transmitted by the sound wave transmission device to one of the plurality of OTWs; And transmitting OTW instruction information for playing the OTW mapped to the authentication information to the sound wave transmitting device, receiving OTW identification information corresponding to the OTW instruction information from the sound wave receiving device, and receiving the OTW identification information and the OTW. It includes an authentication processing unit that compares the similarity of sound sources stored in the pool and generates an authentication result.

Description

Non-contact authentication system and method using one-time sound waves {CONTACTLESS CERTIFICATION SYSTEM USING ONE TIME WAVES AND METHOD THEREOF}

The present invention relates to a non-contact authentication system and method using one-time sound waves, and more specifically, to perform non-contact payment based on one-time sound waves that cannot be reused for a specific time, and by giving time validity and spatial validity to the one-time sound waves. This relates to a non-contact authentication system and method that can improve security and obtain highly accurate results.

Recently, as the mobile payment market using smartphones has expanded explosively, research related to mobile payment app services is being actively conducted. In particular, the need for non-contact authentication methods using short-range wireless communication functions is increasing for the convenience of online and offline payments.

Figure 1 is a diagram showing a non-contact authentication system utilizing a short-range wireless communication function according to the prior art.

Referring to Figure 1, conventionally, non-contact authentication was performed using a terminal 10 including a Near Field Communication (NFC) function. NFC is a short-range wireless communication technology that transmits data at low power, allowing data to be exchanged at a short distance of less than 1cm. When the terminal 10 including the NFC function contacts the payment terminal 20, the terminal 10 and the payment terminal 20 are connected easily and quickly without a complicated setup process. At this time, as the NFC terminal 10 and the payment terminal 20 are connected, authentication is processed through communication with the authentication server.

This non-contact authentication method using the NFC method is widely used because it is inexpensive. However, in reality, the terminal 10 must make contact to transmit data to the payment terminal 20. In addition, the NFC method can be performed only when the payment terminal 20 includes the NFC function. in other words. If the payment terminal 20 does not include an NFC function, it is impossible to perform non-contact authentication.

In addition, the NFC method forces the user to directly touch the terminal 10 to the payment terminal 20 or hand the terminal 10 directly to a sales employee.

In addition, non-contact authentication can be performed using the Bluetooth function, a representative short-distance communication method. Bluetooth is a technology that can transmit and receive data between wireless communication devices up to 30m. Bluetooth has the advantage of supporting communication over longer distances than NFC, but because Bluetooth requires mutual pairing between the terminal 10 and the payment terminal 20, it is not suitable for authentication systems that frequently occur between unknown users. .

Therefore, there is a need to develop a non-contact authentication system that enables non-contact authentication at an appropriate distance (0.5 to 1 m) that provides user convenience in payment, and that can simple implement the authentication device or use an existing device as a payment terminal. do.

The technical problem to be achieved by the present invention is to provide a non-contact authentication system and method that can perform authentication based on one-time sound waves that cannot be reused for a specific time.

In addition, the technical problem to be achieved by the present invention is to provide a non-contact authentication system and method that can prevent sound wave copying attacks by giving time information and space information to one-time sound waves.

In addition, the technical problem to be achieved by the present invention is to provide a non-contact authentication system and method that can receive sound waves without partial distortion due to noise by extracting the characteristics of one-time sound waves.

In addition, the technical problem to be achieved by the present invention is to provide a non-contact authentication system and method that can use existing payment terminals.

The one-time sound wave-based authentication system according to an embodiment of the present invention to solve the above-described problem is connected to a sound wave transmitting device and a sound wave receiving device, generates a sound source for use as the one-time sound wave (OTW), and creates an OTW pool. an OTW pool generator that stores sound sources selected through detection of partial overlap between a plurality of OTWs pre-stored in and the generated sound sources; an OTW mapping unit that maps authentication information to be transmitted by the sound wave transmission device to one of the plurality of OTWs; And transmitting OTW instruction information for playing the OTW mapped to the authentication information to the sound wave transmitting device, receiving OTW identification information corresponding to the OTW instruction information from the sound wave receiving device, and receiving the OTW identification information and the OTW. It includes an authentication processing unit that compares the similarity of sound sources stored in the pool and generates an authentication result.

Here, the OTW mapping unit is an authentication information mapping unit that maps the authentication information received from the sound wave transmission device with the OTW, and a time information mapping unit that maps the time information of receiving the authentication information from the sound wave transmission device with the OTW. It may include a local information mapping unit that maps the local information receiving the authentication information from the unit and the sound wave transmission device with the OTW.

Meanwhile, the OTW identification information may be an audio fingerprint of the corresponding sound source.

Additionally, the OTW indication information may include at least one of sound source data of the corresponding sound source, music score data, and a pre-assigned indicator.

Here, the sound wave transmission device includes: an OTW allocation request unit that requests the OTW allocation for the authentication information to the one-time sound wave-based authentication system and provides the authentication information and the area information; a time synchronization wave generator that generates a time synchronization wave so that time information is reflected in the allocated OTW; An OTW playback unit that plays the assigned OTW at a preset intensity, volume, and number of times through a speaker; and a success message that receives a reception success message from the one-time sound wave-based authentication system in response to playback of the assigned OTW. It may include a receiving unit.

In addition, the sound wave receiving device includes a sound source recording unit that records and receives the OTW reproduced from the sound wave transmitting device with a microphone; a time synchronization wave verification unit that verifies whether the received time synchronization wave of the OTW corresponds to the time at which the OTW was recorded; an audio fingerprint extractor that extracts the verified audio fingerprint of the OTW; a feature matching unit that matches a pre-stored audio fingerprint set with the extracted audio fingerprint of the OTW; And the one-time sound wave-based authentication system may include an authentication information request unit that requests authentication information of the corresponding OTW based on the OTW identification information.

In addition, the authentication processing unit searches for the similarity between the OTW of the OTW pool and the received OTW identification information, and compares the area information mapped to the OTW with the area information of the sound wave receiving device to perform verification. It can be included.

In addition, the authentication method of the authentication system using one-time sound waves according to an embodiment of the present invention includes the steps of: a) receiving an OTW allocation request and authentication information from the sound wave transmission device; b) allocating the OTW corresponding to the authentication information and mapping the authentication information and the allocated OTW; c) transmitting OTW indication information of the allocated OTW to the sound wave transmission device; d) receiving OTW identification information transmitted by the sound wave receiving device in response to reproduction of the OTW transmitted to the sound wave transmitting device; and e) comparing the identification information of the received OTW with the similarity of a plurality of OTWs stored in the OTW pool, and generating an authentication result based on the similarity.

Here, step b) randomly generates the sound source; Comparing the generated sound source with the OTW stored in the OTW pool to detect partial redundancy, and if the partial redundancy between the sound source and the OTW is greater than a threshold, excluding the generated sound source; And it may include the step of storing non-excluded sound sources in the OTW pool and assigning them as OTWs mapped to the authentication information.

In addition, step b) may further include mapping time information and area information received from the sound wave transmission device to the allocated OTW.

Meanwhile, step e) includes receiving OTW identification information of the OTW and searching for similarity between the OTW identification information and the plurality of OTWs stored in the OTW pool; When the similarity is greater than or equal to a threshold, verifying the OTW based on the time information and the region information included in the OTW identification information; And it may include generating the authentication result based on the verification result and providing it to the sound wave receiving device.

According to an embodiment of the present invention, authentication can be safely performed based on a one-time, one-time sound wave in which the assigned information is removed after being used once.

In addition, according to an embodiment of the present invention, an audio fingerprint, which is a characteristic including the frequency, peak, amplitude, and phase of a one-time sound wave, can be extracted, and the one-time sound wave can be searched based on the extracted audio fingerprint. As a result, search errors due to partial distortion that may occur due to noise when the payment terminal records a sound source can be minimized. Sound source search accuracy can be improved.

Additionally, according to an embodiment of the present invention, temporal information and spatial information can be reflected in one-time sound waves. Malicious use can be prevented by verifying one-time sound waves based on temporal and spatial information.

Additionally, according to an embodiment of the present invention, the sound wave receiving device and the sound wave transmitting device may include a PC, desktop, smartphone, tablet, etc. that have built-in speakers/audio. Additionally, it is possible to print receipts using an existing payment terminal. As a result, it is possible to perform non-contact authentication with a relatively simple configuration.

The effects of the present invention are not limited to the effects described above, and should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

Figure 1 is a diagram showing a non-contact authentication system utilizing a short-range wireless communication function according to the prior art.
Figure 2 is a diagram showing the operation of a non-contact authentication system utilized according to an embodiment of the present invention.
Figure 3 is a diagram showing a detailed block diagram of a one-time sound wave-based authentication system according to an embodiment of the present invention.
Figure 4 is a diagram showing the operation of a non-contact authentication system utilized according to an embodiment of the present invention.
Figure 5 is a diagram showing the operation of a sound wave transmission device according to an embodiment of the present invention.
Figure 6 is a diagram showing the operation of a sound wave receiving device according to an embodiment of the present invention.
Figure 7 is a diagram showing the process of authentication using OTW by a non-contact authentication system according to an embodiment of the present invention.
Figure 8 is a diagram showing the process of allocating OTW by the one-time sound wave-based authentication system according to an embodiment of the present invention.
Figure 9 is a diagram illustrating a process in which a one-time sound wave-based authentication system according to an embodiment of the present invention generates an authentication result.

Hereinafter, the present invention will be described with reference to the attached drawings. However, the present invention may be implemented in various different forms and, therefore, is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, combined)" with another part, this means not only "directly connected" but also "indirectly connected" with another member in between. "Includes cases where it is. Additionally, when a part is said to “include” a certain component, this does not mean that other components are excluded, but that other components can be added, unless specifically stated to the contrary.

The terms used herein are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 2 is a diagram showing the operation of a non-contact authentication system utilized according to an embodiment of the present invention.

Referring to Figure 2, the sound wave transmission device 200 may receive authentication information from the financial company server 400. Here, the term “authentication information” should be understood to include all data that can authenticate a specific authority that can be mapped to a one-time sound wave. In the embodiment shown in FIG. 2, the authentication information may be the user's card information. Additionally, the sound wave transmission device 200 may include a PC, desktop, smartphone, tablet, etc., but is not limited thereto and may include various devices capable of transmitting sound waves using a speaker.

The sound wave transmission device 200 is a one-time sound wave-based authentication system 100 that can provide authentication information through a wired or wireless communication network. Additionally, the sound wave transmission device 200 may request a one-time sound wave (OTW) from the one-time sound wave-based authentication system 100. Here, OTW may be a one-time sound file whose assigned information is removed after being used once. The one-time sound wave-based authentication system 100 can map OTW to the received authentication information. Additionally, the one-time sound wave-based authentication system 100 may transmit OTW indication information (one-time sound wave indication information) to the sound wave transmission device 200. The term “OTW instruction information” used in the specification includes all information that can be reproduced by instructing a specific OTW, and includes sheet music data for playing OTW sound sources, the sound source file itself, or a plurality of pieces stored in the sound wave transmission device 200. It can also be an indicator pointing to one of the sound sources.

Meanwhile, the one-time sound wave-based authentication system 100 can generate an OTW pool by generating a preset number of sound sources. If you greatly increase the number of sound sources, the probability of successful replication decreases, which can help defend against replication attacks, but the computational cost incurred during search may increase. Accordingly, the one-time sound wave-based authentication system 100 can reduce computational costs while maintaining security by generating a certain number of sound sources to form an OTW pool.

Additionally, the one-time sound wave-based authentication system 100 may generate a sound source and then perform a partial redundancy check with the already created OTW full sound source. As an example, the one-time sound wave-based authentication system 100 may exclude the corresponding sound source from the OTW pool when the redundancy between the generated sound sources is greater than a threshold. As a result, it is possible to prevent errors in which similar sound sources are searched that occur during one-time sound wave search.

The sound wave transmission device 200 can reproduce OTW using the received OTW instruction information. At this time, the sound wave receiving device 300 may record the played OTW with a microphone and receive it. As an example, the sound wave receiving device 300 may include a PC, desktop, smartphone, tablet, etc., but is not limited thereto and may include various devices capable of recording sound waves. That is, the sound wave transmitting device 200 and the sound wave receiving device 300 can be implemented as dedicated devices, but can be easily implemented using smart devices that are already in widespread use.

Additionally, the sound wave receiving device 300 may transmit OTW identification information about the received OTW to the one-time sound wave-based authentication system 100. In this specification, “OTW identification information” may include all information used to identify a received OTW sound source by a one-time sound wave-based authentication system. That is, the OTW identification information may include the received OTW sound source itself, signal-processed data of the OTW sound source, OTW-encoded data, and an audio fingerprint extracted from the OTW. Audio fingerprint refers to data from which OTW features, including specific frequency, peak, amplitude, and phase, are extracted.

The generated OTW identification information may be transmitted to the one-time sound wave-based authentication system 100. The one-time sound wave-based authentication system 100 can search for similarity based on the received OTW identification information. As an example, the one-time sound wave-based authentication system 100 may compare the similarity between the sound source stored in the one-time sound wave pool and the sound source included in the received OTW identification information. The one-time sound wave-based authentication system 100 may determine that the sound source stored in the one-time sound wave pool corresponds to the OTW identification information when the similarity is greater than a preset threshold. Additionally, the one-time sound wave-based authentication system 100 can generate authentication results. The one-time sound wave-based authentication system 100 may generate an authentication result indicating that the sound source included in the OTW identification information has been authenticated when the similarity is greater than a threshold. The one-time sound wave-based authentication system 100 may provide the generated authentication result to the sound wave transmission device 200.

Figure 3 is a diagram showing a detailed block diagram of a one-time sound wave-based authentication system according to an embodiment of the present invention.

As shown in FIG. 3, the one-time sound wave-based authentication system 100 may include an OTW pool creation unit 110, an OTW mapping unit 120, and an authentication processing unit 130.

First, the OTW pool creation unit 110 may include a sound source creation unit 111, a sound source selection unit 112, and an OTW pool storage unit 113. The sound source generator 111 may generate a preset number of sound sources. The sound source generator 111 may randomly generate sound sources to have various frequencies, peaks, amplitudes, and phases. For example, when the sound source generator 111 generates a large number of sound sources, the probability of successful copying of the sound source is lowered, thereby effectively preventing malicious copying attacks. However, a problem may occur in that the computational cost incurred when searching for a sound source increases. The sound source generator 111 can improve security and reduce computational costs by randomly generating a certain number of sound sources.

The sound source selection unit 112 may detect partial overlap between the generated sound source and the stored sound source. The sound source selection unit 112 may remove the generated sound source when the partial redundancy between sound sources is greater than a threshold. The sound source selection unit 112 can solve the error of searching for similar sound sources by selecting valid sound sources. Here, the sound source generator 111 may generate as many sound sources as the number of sound sources removed to satisfy the preset number of sound sources.

Additionally, the OTW pool storage unit 113 can store selected sound sources in the OTW pool. In other words, OTW as many as a preset number of sound sources can be stored in the OTW pool.

Meanwhile, the OTW mapping unit 120 may include a time information mapping unit 121, an authentication information mapping unit 122, a local information mapping unit 123, and an OTW release unit 124.

The time information mapping unit 121 may map the time information received from the sound wave transmission device to the OTW. As will be described later, the similarity search performing unit 133 may compare the OTW reflecting the time information for receiving authentication information from the sound wave transmitting device and the time information for receiving OTW identification information from the sound wave receiving device. In other words, the one-time sound wave-based authentication system 100 can improve OTW authentication accuracy by providing time validity to OTW.

Additionally, the authentication information mapping unit 122 may map authentication information received from the sound wave transmission device to OTW. Here, the authentication information may include the user's card information.

The local information mapping unit 123 may map the local information received from the sound wave transmission device to the OTW. Local information can be generated based on the location sensor of the sound wave transmission device. As will be described later, the similarity search performing unit 133 may compare the OTW reflecting the area information for receiving authentication information from the sound wave transmitting device and the area information for receiving OTW identification information from the sound wave receiving device. In other words, the one-time sound wave-based authentication system 100 can nullify artificial sound source duplication by granting spatial validity to OTW.

The OTW release unit 124 can delete authentication information, time information, and region information assigned to the OTW. That is, the OTW release unit 124 can remove the allocated information so that it is not reused after the OTW is used.

The authentication processing unit 130 may include an OTW indication information transmitting unit 131, an OTW identification information receiving unit 132, a similarity search performing unit 133, and an authentication result transmitting unit 134.

The OTW instruction information transmitter 131 may provide OTW instruction information through a sound wave transmission device. OTW indication information may include OTW to which time information, authentication information, and region information are mapped.

The OTW identification information receiving unit 132 may receive OTW identification information from the sound wave receiving device. As an example, OTW identification information may be generated based on the OTW received by the sound wave receiving device from the sound wave transmitting device. The sound wave transmission device can extract the audio fingerprint of the received OTW and generate identification information of the OTW based on the extracted audio fingerprint. Here, the audio fingerprint may include specific frequency, peak, amplitude, and phase.

The similarity search performing unit 133 may perform a similarity search of the OTW pool and OTW identification information. At this time, the similarity search performing unit 133 may compare the similarity between the OTW searched from the OTW pool and the OTW of the OTW identification information. The similarity search performing unit 133 may compare the similarity based on the OTW's audio fingerprint of the OTW identification information. Here, the similarity search performance unit 133 may determine that the OTW searched from the corresponding OTW pool and the OTW of the identification information correspond when the similarity is greater than or equal to the threshold.

Additionally, the similarity search performing unit 133 may verify the OTW retrieved from the OTW pool determined to correspond to the OTW of the identification information. As an example, the similarity search performing unit 133 may verify the time and region information mapped to the OTW searched from the OTW pool by comparing the time and region information of the OTW in the identification information. The similarity search performing unit 133 may generate an OTW authentication result based on the verification result. OTW authentication results may include authentication information assigned to OTW. The similarity search performing unit 133 performs a similarity search, making it possible to identify the original sound even if it is partially distorted by noise.

The authentication result transmitter 134 may transmit the generated OTW authentication result to the sound wave receiving device. The sound wave receiving device can proceed with payment based on the authentication information included in the OTW authentication result.

Figure 4 is a diagram showing the operation of a non-contact authentication system utilized according to an embodiment of the present invention.

Referring to Figure 4, the sound wave transmission device 200 may transmit authentication information to the OTW pool storage unit 113. Here, the authentication information may include the user's card information. Additionally, authentication information may be expressed as a digital data value formed in the form of a code.

The OTW pool storage unit 113 may store a preset number of OTW (OTW n). Here, OTW stored in the OTW pool storage unit 113 may include sound sources selected by the sound source selection unit 112. The sound source selection unit 112 can detect partial overlap between the generated sound source and the sound source stored in the OTW pool storage unit 113. When the partial redundancy between sound sources is greater than a threshold, the sound source selection unit 112 excludes the generated sound source from the OTW pool. That is, the OTW full storage unit 113 can minimize errors in searching for similar sound sources by storing only selected sound sources. Additionally, the OTW pool storage unit 113 may store the received authentication information and the mapped OTW (OTW3). The OTW pool storage unit 113 may provide authentication information and mapped OTW (OTW3) to the sound wave transmission device 200.

OTW3 received by the sound wave transmission device 200 can be output. The sound wave receiving device 300 can record and receive the output OTW3. As an example, the sound wave transmission device 200 may include a PC, desktop, smartphone, and tablet, but is not limited thereto and may include various devices including speakers. Additionally, the sound wave receiving device 300 may include a PC, desktop, smartphone, tablet, etc., but is not limited thereto and may include various devices including a microphone.

The sound wave receiving device 300 may generate OTW identification information (OTW3a) of the received OTW3. The received OTW3 may differ from the original sound source due to surrounding noise or signal attenuation or deterioration. OTW identification information (OTW3a) refers to identification information that allows OTW3 to be searched using this received signal. OTW identification information (OTW3a) can be an audio fingerprint of OTW3 including specific frequency, peak, amplitude, and phase. That is, the sound wave receiving device 300 can reduce the probability of false detection of OTW3 by extracting OTW identification information (OTW3a) using audio fingerprint even if OTW3 is received with partial distortion due to noise. Additionally, the sound wave receiving device 300 may transmit OTW identification information (OTW3a) to the similarity search performing unit 133.

The similarity search performing unit 133 may search the similarity between the received OTW identification information (OTW3a) and OTW 1 to OTWn stored in the OTW pool storage unit 113. When the similarity between the audio fingerprint of the OTW identification information (OTW3a) and OTW3 stored in the OTW pool storage unit 113 is greater than or equal to a threshold, the similarity search performing unit 133 matches OTW3 stored in the OTW pool storage unit 113 with OTW3a. It can be judged that it is.

The OTW pool storage unit 113 may provide the authentication result to the authentication result transmission unit 134. The authentication result may include authentication information assigned to OTW3. The authentication result transmitter 134 may provide the authentication result of OTW3 to the sound wave receiving device. The sound wave receiving device 300 may perform payment based on the received OTW3 authentication result.

Figure 5 is a diagram showing the operation of a sound wave transmission device according to an embodiment of the present invention.

As shown in Figure 5, APP 210, OTW allocation request unit 220, time synchronous wave generator 230, mixing unit 240, OTW playback unit 250, and reception success message reception unit 260. may include.

The APP 210 may include financial/payment software that supports payment using one-time sound waves. Additionally, user data such as login information, user authentication information, and user card information may be input to the APP 210. The APP 210 may provide authentication information to the OTW allocation request unit 220.

The OTW allocation request unit 220 can request OTW allocation for authentication information using a one-time sound wave-based authentication system. Additionally, the OTW allocation request unit 200 may receive location information of the area where authentication information is received from the APP 210. Location information can be determined based on the GPS sensor built into the sound wave transmission device 200. Therefore, the OTW allocation request unit 200 can provide authentication information and area information through a one-time sound wave-based authentication system. The one-time sound wave-based authentication system can provide the received authentication information and area information and OTW indication information for the mapped OTW to the OTW allocation request unit 220.

The time synchronization wave generator 230 may generate a time synchronization wave to reflect time information about the OTW. The time synchronization wave generator 230 may generate a time synchronization wave for a specific time in the allocated OTW and grant time validity to the OTW received through the mixing unit 240.

The OTW playback unit 250 can play OTW containing a time-synchronized wave at a preset intensity, volume, and number of times through a speaker.

When the reception success message receiver 260 determines that the output OTW has been received by the sound wave receiving device, it may receive a reception success message from the one-time sound wave-based authentication system. When the one-time sound wave-based authentication system receives OTW from the sound wave receiving device, the sound wave receiving device can determine that OTW reception was successful.

When the reception success message receiver 260 determines that reception is successful, it can stop the operation of the OTW playback unit. Additionally, the reception success message receiver 260 may transmit the reception success message to the APP 210. At this time, the APP 210 may display the reception success message on the screen or provide a notification to the user through vibration, etc.

Figure 7 is a diagram showing the process of authentication using OTW by a non-contact authentication system according to an embodiment of the present invention.

The sound wave receiving device 300 includes an APP 310, a sound source recording unit 320, a time synchronized wave verification unit 330, an audio fingerprint extractor 340, a feature matching unit 350, and an authentication information request unit 360. ) may include.

The APP 310 may include software that allows payment through the received OTW. Additionally, the APP 310 can operate the sound source recording unit 320 when set to the operation mode. That is, the sound source recording unit 320 can be driven only when the APP 310 is in operation mode. Accordingly, the sound source recording unit 320 can perform recording only in necessary situations.

The sound recording unit 320 can record OTW played through a microphone. Additionally, the sound source recording unit 320 can prevent unnecessary noise from being recorded by performing recording according to a preset time. In addition, the sound source recording unit 320 is equipped with a directional microphone, so that it can selectively receive OTW for payment among a plurality of sound sources received in the same space.

Here, the sound recording unit 320 may encode the recorded OTW using the PCM (Pulse Code Modulation) method. PCM modulates an analog signal into a digital signal by sampling and encoding it with a certain number of bits. The recorded OTW is modulated using the PCM method, so it can be less affected by external noise because information is transmitted based on encoded digital data.

The time synchronization wave verification unit 330 can verify the time synchronization wave of OTW. As an example, the time synchronization wave verification unit 330 may verify whether the time synchronization wave of the OTW corresponds to the time when the sound source recording unit 320 recorded the OTW. The time synchronous wave verification unit 330 may transmit the OTW determined to correspond to the audio fingerprint extractor 340.

The audio fingerprint extractor 340 can extract the audio fingerprint of the received OTW. Audio fingerprints can be features of OTW, including specific frequencies, peaks, amplitudes, and phases.

The feature matching unit 350 may match a pre-stored audio fingerprint set with the extracted audio fingerprint of the OTW. Mulberry finger print dna[0], dna[1]… The stored audio fingerprint set may be implemented inside the sound wave receiving device 300, but may also be implemented externally (eg, a one-time sound wave-based authentication system).

Through the above-described exaggeration, the feature matching unit 350 can generate OTW identification information.

The authentication information request unit 360 can request authentication information by providing OTW identification information with a one-time sound wave-based authentication system. The one-time sound wave-based authentication system can determine the corresponding OTW based on OTW identification information. At this time, the one-time sound wave-based authentication system may provide authentication information of the OTW determined to correspond to the authentication information request unit 360. Additionally, the authentication information request unit 360 may provide the received authentication information to the APP 310. APP 310 can proceed with payment based on the provided authentication information.

Figure 7 is a diagram showing the process of authentication using OTW by a non-contact authentication system according to an embodiment of the present invention.

In step S100, the sound wave transmission device 200 may request OTW allocation from the one-time sound wave-based authentication system 100.

In step S110, the sound wave transmission device 200 may transmit authentication information and area information to the one-time sound wave-based authentication system 100. The authentication information may include the user's card information provided by the financial company server to the sound wave transmission device 200. Additionally, the area information may be the location when the sound wave transmission device 200 requests OTW allocation from the one-time sound wave-based authentication system 100. The sound wave transmission device 200 can generate local information by embedding a GPS sensor.

In step S120, the one-time sound wave-based authentication system 100 may allocate an OTW to be mapped to the received authentication information. The one-time sound wave-based authentication system 100 can map the received authentication information and local information to OTW. Additionally, the one-time sound wave-based authentication system 100 may generate time information based on the time at which authentication information is received, and map the generated time information to OTW.

In step S130, the one-time sound wave-based authentication system 100 may transmit the allocated OTW indication information to the sound wave transmission device 200. OTW indication information may include OTW to which time information, authentication information, and region information are mapped.

Additionally, the sound wave transmission device 200 can reproduce the received OTW. The sound wave transmission device 200 can reproduce OTW at a preset intensity, volume, and number of times through a speaker. The sound wave receiving device 300 can record and receive the played OTW. The sound wave receiving device 300 can record OTW played through a microphone. Additionally, the sound wave receiving device 300 can prevent unnecessary noise from being recorded by performing recording according to a preset time.

In step S140, the sound wave receiving device 300 may verify the received OTW. The sound wave receiving device 300 can verify the time synchronization wave of OTW. As an example, the sound wave receiving device 300 may verify whether the time synchronization wave of the OTW corresponds to the time at which the OTW was recorded.

Additionally, the sound wave receiving device 300 can extract the audio fingerprint of the OTW. Audio fingerprints can be features of OTW, including specific frequencies, peaks, amplitudes, and phases. The sound wave receiving device 300 may generate identification information of the OTW based on the extracted audio fingerprint. By extracting the audio fingerprint of the OTW, the sound wave receiving device 300 can reduce the probability of false detection even if the OTW is received with partial distortion due to noise.

In step S150, the sound wave receiving device 300 may transmit OTW identification information to the one-time sound wave-based authentication system 100.

In step S160, the one-time sound wave-based authentication system 100 may search for the similarity between the received OTW identification information and the OTW stored in the OTW pool. The one-time sound wave-based authentication system 100 may determine that the OTW and OTW identification information stored in the OTW pool correspond when the similarity between OTWs is greater than a threshold. The one-time sound wave-based authentication system 100 can generate an authentication result based on the judgment result.

In step S170, the one-time sound wave-based authentication system 100 may transmit the authentication result to the sound wave receiving device 300. The authentication result may include authentication information assigned to the OTW. Accordingly, the sound wave receiving device 300 can perform payment based on the received authentication result.

Figure 8 is a diagram showing the process of allocating OTW by the one-time sound wave-based authentication system according to an embodiment of the present invention.

In step S121, the one-time sound wave-based authentication system may generate a sound source. The one-time sound wave-based authentication system can randomly generate a preset number of sound sources.

In step S122, the one-time sound wave-based authentication system can compare the generated sound source with the OTW pool.

In step S123, the one-time sound wave-based authentication system can detect partial redundancy between the OTW stored in the OTW pool and the generated sound source. As an example, a one-time sound wave-based authentication system can exclude a generated sound source if redundancy is greater than a threshold.

In step S124, the one-time sound wave-based authentication system may assign the OTW to the sound wave transmitting device. The allocated OTW is an OTW for which no partial duplication has been detected in the OTW stored in the OTW pool. As a result, it is possible to prevent errors in which similar sound sources are searched that occur during one-time sound wave search.

In step S125, the one-time sound wave-based authentication system may map authentication information, time information, and area information to the assigned OTW. Authentication information may include the user's card information. Additionally, the one-time sound wave-based authentication system can map regional information that receives authentication information from a sound wave transmitting device with OTW. Local information can be generated based on a location sensor built into the sound wave transmission device. The one-time sound wave-based authentication system can receive authentication information and area information from a sound wave transmitting device. The one-time sound wave-based authentication system can map the time information of receiving authentication information from the sound wave transmitting device with OTW. A one-time sound wave-based authentication system can improve security and authentication accuracy by providing time validity and spatial validity to OTW.

Figure 9 is a diagram illustrating a process in which a one-time sound wave-based authentication system according to an embodiment of the present invention generates an authentication result.

In step S161, the one-time sound wave-based authentication system may receive OTW identification information from the sound wave receiving device. As an example, OTW identification information may be generated based on the OTW's audio fingerprint. Here, the audio fingerprint may include specific frequency, peak, amplitude, and phase.

In step S162, the one-time sound wave-based authentication system may search for OTWs stored in the OTW pool similar to the received OTW identification information. A one-time acoustic wave-based authentication system can detect OTW identification information based on the OTW's audio fingerprint.

In step S163, the one-time sound wave-based authentication system may compare the similarity of the OTW audio fingerprint of the retrieved OTW and OTW identification information. The one-time sound wave-based authentication system can determine that the OTW audio fingerprint of the searched OTW and OTW identification information corresponds when the similarity is above a threshold. Additionally, the one-time sound wave-based authentication system may perform the OTW search step again (step S162) when the similarity is below the threshold.

In step S164, the one-time sound wave-based authentication system may verify the OTW determined to correspond. One-time sound wave-based authentication system can be verified based on time information and regional information mapped to OTW. As an example, a one-time sound wave-based authentication system can be verified by comparing the time information and area information mapped to the OTW with the time and area at which OTW identification information is received from the sound wave receiving device. That is, when allocating OTW instruction information, if the distance calculated through the location information of the sound wave transmitting device 200 and the location information of the OTW receiving device 300 that transmitted the OTW identification information is greater than the threshold, it is regarded as fraudulent use and is authenticated. can be refused.

In step S165, the one-time sound wave-based authentication system may generate an authentication result based on the verification result. As an example, when the one-time sound wave-based authentication system determines that the OTW has been verified, it can generate an authentication result based on the authentication information of the OTW.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims described below, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention.

100: One-time sound wave-based authentication system
200: Sound wave transmission device
300: Sound wave receiving device

Claims (12)

In the authentication system that is connected to the sound wave transmitting device and the sound wave receiving device and uses one-time sound waves,
an OTW pool generator that generates a sound source to be used as the one-time sound wave (OTW) and stores the sound source selected through detection of partial overlap between a plurality of OTWs pre-stored in the OTW pool and the generated sound source;
an OTW mapping unit that maps authentication information to be transmitted by the sound wave transmission device to one of the plurality of OTWs; and
OTW instruction information for playing the OTW mapped to the authentication information is transmitted to the sound wave transmitting device, and OTW identification information corresponding to the OTW instruction information is received from the sound wave receiving device, and the OTW identification information and the OTW pool are received. Authentication processing unit that generates authentication results by comparing the similarity of sound sources stored in
Includes one-time acoustic wave-based authentication system.
According to paragraph 1,
The OTW mapping unit
An authentication information mapping unit that maps the authentication information received from the sound wave transmission device with the OTW,
A time information mapping unit that maps time information on receiving the authentication information from the sound wave transmission device with the OTW, and
A one-time sound wave-based authentication system comprising a local information mapping unit that maps the local information received from the sound wave transmitting device to the OTW.
According to paragraph 1,
A one-time sound wave-based authentication system in which the OTW identification information is an audio fingerprint of the corresponding sound source.
According to paragraph 1,
The OTW indication information is a one-time sound wave-based authentication system that includes at least one of sound source data of the corresponding sound source, sheet music data, and a pre-assigned indicator.
According to paragraph 2,
The sound wave transmitting device is
an OTW allocation request unit that requests the OTW allocation for the authentication information to the one-time sound wave-based authentication system and provides the authentication information and the region information;
a time synchronization wave generator that generates a time synchronization wave so that time information is reflected in the allocated OTW;
An OTW playback unit that plays the assigned OTW at a preset intensity, volume, and number of times through a speaker; And
A one-time sound wave-based authentication system comprising: a success message receiving unit that receives a reception success message from the one-time sound wave-based authentication system in response to playback of the allocated OTW.
According to clause 5,
The sound wave receiving device,
a sound source recording unit that records and receives the OTW reproduced from the sound wave transmission device with a microphone;
a time synchronization wave verification unit that verifies whether the received time synchronization wave of the OTW corresponds to the time at which the OTW was recorded;
an audio fingerprint extractor that extracts the verified audio fingerprint of the OTW;
a feature matching unit that matches a pre-stored audio fingerprint set with the extracted audio fingerprint of the OTW; and
A one-time sound wave-based authentication system comprising an authentication information request unit that requests authentication information of the corresponding OTW based on the OTW identification information.
According to paragraph 2,
The authentication processing unit,
One-time sound wave-based, including a similarity search performing unit that searches for the similarity between the OTW of the OTW pool and the received OTW identification information, and performs verification by comparing the area information mapped to the OTW with the area information of the sound wave receiving device. Authentication system.
In the authentication method of the authentication system that is connected to the sound wave transmitting device and the sound wave receiving device and uses one-time sound waves,
a) receiving an OTW allocation request and authentication information from the sound wave transmission device;
b) allocating the OTW corresponding to the authentication information and mapping the authentication information and the allocated OTW;
c) transmitting OTW indication information of the allocated OTW to the sound wave transmission device;
d) receiving OTW identification information transmitted by the sound wave receiving device in response to reproduction of the OTW transmitted to the sound wave transmitting device; and
e) Comparing the identification information of the received OTW with the similarity of a plurality of OTWs stored in the OTW pool, and generating an authentication result based on the similarity. One-time sound wave-based authentication method.
According to clause 8,
In step b),
Randomly generating the sound source;
Comparing the generated sound source with the OTW stored in the OTW pool to detect partial redundancy, and if the partial redundancy between the sound source and the OTW is greater than a threshold, excluding the generated sound source; and
A one-time sound wave-based authentication method comprising the step of storing non-excluded sound sources in the OTW pool and assigning them as OTWs mapped to the authentication information.
According to clause 9,
In step b),
One-time sound wave-based authentication method further comprising mapping time information and area information received from the sound wave transmission device to the allocated OTW.
According to clause 10,
In step e),
Receiving OTW identification information of the OTW and searching for similarity between the OTW identification information and the plurality of OTWs stored in the OTW pool;
When the similarity is greater than or equal to a threshold, verifying the OTW based on the time information and the region information included in the OTW identification information; and
A one-time sound wave-based authentication method comprising generating the authentication result based on the verification result and providing it to the sound wave receiving device.
According to clause 11,
The OTW identification information is an audio fingerprint that includes at least one of a specific frequency, peak, amplitude, and phase that characterizes the OTW.

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