KR102155380B1 - Method and Device for Analyzing Real-time Sound - Google Patents

Abstract

The real-time sound analysis device according to an embodiment of the present invention includes an input unit that collects sounds generated in real time, a signal processing unit that processes the collected real-time sound data to facilitate machine learning, and machine learning the previously collected sound data. ), and training a first function for classifying sound category information, and a first classifier for classifying sound data signal-processed by the first function into sound types. Characterized in that. According to an embodiment of the present invention, it is possible to learn the types and causes of sounds collected in real time based on machine learning, and more accurately predict the types and causes of sounds collected in real time.

Description

Real-time sound analysis method and device {Method and Device for Analyzing Real-time Sound}

The present invention relates to a method and apparatus for analyzing real-time sound, and more particularly, to a method and apparatus for learning and analyzing ambient sounds generated in real time using a machine learning method based on artificial intelligence.

With the development of sound technology, a variety of devices having a function of detecting and classifying sound are being released. The function of classifying sounds through frequency analysis and providing results to users is widely used through mobile devices of the public, and recently, artificial intelligence speakers have been released to respond to users' verbal sounds and respond appropriately to questions or commands. Tools for sound analysis such as providing feedback are becoming increasingly diverse.

In the case of Korean Patent No. 10-1092473, a method and apparatus for detecting baby crying sounds using a frequency and continuous pattern capable of detecting the crying sound of a baby among various surrounding sounds are provided. This aims to relieve the burden of parenting by providing a feedback function such as detecting whether the baby is crying and notifying the parents or automatically listening to the mother's heartbeat. However, techniques like this only tell if the baby is crying, not provide information about why the baby is crying, and consistent feedback (e.g., mother's) despite the fact that the reasons the baby is crying (e.g., hunger, pain, etc.) can vary. In some cases, such as only providing a heartbeat sound), inappropriate feedback is given.

Meanwhile, in the case of recently released artificial intelligence speakers, there is a problem that feedback cannot be provided for non-verbal sounds that cannot be expressed in writing (eg, baby crying) because they respond only to verbal voices.

Korean Patent Publication No. 10-1092473 (registered on December 5, 2011)

The present invention has been proposed to solve the above problems, and not only classifies sounds in real time by learning sounds by machine learning, but also analyzes not only the types of sounds but also the causes thereof by learning the cause of the sound generation. It is an object of the present invention to provide a method and apparatus that can be used.

The real-time sound analysis device according to an embodiment of the present invention includes an input unit that collects sounds generated in real time, a signal processing unit that processes the collected real-time sound data to facilitate machine learning, and machine learning the previously collected sound data. ), and training a first function for classifying sound category information, and a first classifier for classifying sound data signal-processed by the first function into sound types. Characterized in that.

The real-time sound analysis apparatus according to an embodiment of the present invention includes a first communication unit that transmits and receives information about sound data, and the first communication unit may transmit signal-processed sound data to an additional analysis device.

The first communication unit may receive a result of analyzing the cause of the sound through the second function learned by deep learning from the additional analysis device.

In an embodiment of the present invention, the first learning unit may supplement the first function by learning the real-time sound data using a machine learning method.

In an embodiment of the present invention, the first learning unit may supplement the first function by receiving the feedback input by the user and learning real-time sound data corresponding to the feedback through a machine learning method.

The real-time sound analysis apparatus according to an embodiment of the present invention may further include a first feedback receiving unit, and the first feedback receiving unit may directly receive feedback from a user or receive feedback from another device or module.

The term'function' used in the text refers to a tool that is continuously reinforced through given data and learning algorithms for machine learning. Specifically, it refers to a tool that predicts the relationship between input (sound) and output (type or cause). Therefore, at the time of initial learning, the function can be predetermined by the administrator.

The first function, which becomes more accurate as the number of data to be learned increases, can be a useful tool for classifying surrounding sounds by type by learning previously collected sound data using a machine learning method. For example, if the sound of interest is the sound of a patient, the first function can distinguish whether the patient makes a moaning sound, a daily conversation, or a laughter if the patient sound collected in advance is learned using a machine learning method. In this machine learning method, a classifier may be learned, and preferably the classifier may be a logistic regression classifier, but is not limited thereto. In other words, the function of the classifier may be trained in a machine learning method based on data to improve performance. This learning process is continuously repeated as real-time sound data is collected, allowing the classifier to derive more accurate results.

The additional analysis device that communicates with the real-time sound analysis device may include a second learning unit that supplements the second function by learning real-time sound data using a second machine learning method. The second function, which becomes more accurate as the number of data to be learned increases, can classify the causes of surrounding sounds by type by learning the previously collected sound data by machine learning. For example, if the sound of interest is the patient's sound, the second function is to classify the sound made by the patient by cause by learning the sound of the patient collected in advance by machine learning, so that whether the patient complains of neuralgia or pain due to high fever. It can be distinguished whether it complains of complaining of discomfort in posture. Preferably, the second machine learning method may be a deep learning method. Preferably, in the deep learning method, an error backpropagation method may be used, but is not limited thereto. This learning process is continuously repeated as real-time sound data is collected, allowing the classifier to derive more accurate results.

In addition, the additional analysis device 700 may use information obtained from the real-time sound analysis device 600 as additional learning data. If the first learning unit extracts feature vectors from the raw data of sound and uses them to classify the sound category by machine learning, the second learning unit also classifies the type as a feature vector. Considering and repeating learning, the cause of sound generation can be analyzed more quickly and accurately. In machine learning or deep learning, the more diverse and accurate feature vectors to be learned, the faster learning is possible, so this method is very useful for increasing the accuracy of analysis.

In an embodiment of the present invention, the first learning unit may supplement the first function by learning the real-time sound data using a machine learning method.

In an embodiment of the present invention, the first learning unit may supplement the first function by receiving the feedback input by the user and learning real-time sound data corresponding to the feedback through a machine learning method.

In an embodiment of the present invention, the real-time sound analysis apparatus may further include a first feedback receiving unit, and the first feedback receiving unit may directly receive feedback from a user or receive feedback from another device or module.

In one embodiment of the present invention, the real-time sound analysis apparatus may further include a first control unit, and the first control unit determines whether the sound type classified by the first classifier corresponds to the sound of interest, and When the type corresponds to the sound of interest, the signal-processed sound data may be controlled to be transmitted to an additional analysis device.

In an embodiment of the present invention, the first learning unit may perform automatic labeling based on semi-supervised learning on the collected sound data. The automatic labeling may be performed by a predetermined algorithm or may be performed by a user's feedback. That is, the automatic labeling is performed according to an algorithm that is normally determined, and when a user's feedback on an error is received, the data corresponding to the feedback is labeled according to the user's feedback, and then the function is trained again by machine learning.

Preferably, the signal processing unit performs pre-processing, frame generation, and feature vector extraction.

The pre-processing may include at least one of Normalization, Frequency Filtering, Temporal Filtering, and Windowing.

The frame generation is an operation of dividing the preprocessed sound data into a plurality of frames in a time domain.

The feature vector extraction may be performed for each single frame among the plurality of frames or may be performed for each frame group consisting of the same number of frames.

The feature vector extracted from the signal processor may be configured with at least one dimension. That is, one feature vector may be used or a plurality of feature vectors may be used.

The signal processing unit performs pre-processing, frame generation, and feature vector extraction of real-time sound data, but may generate only a part of real-time sound data as a core vector before pre-processing. Since the amount of real-time sound data is vast, it is possible to perform pre-processing, frame generation, and feature vector extraction after processing only essential vectors without storing all of the original data. The core vector may be transmitted to an additional analysis device.

At least one dimension of the feature vector may include a dimension related to the sound category. This is because more accurate cause prediction is possible when the second learning unit of the additional analysis device that learns the second function for distinguishing the cause of sound occurrence includes a sound type as a feature vector of sound data. However, elements other than the sound type may be included in the feature vector, and the element of the feature vector that can be added is not limited to the sound type.

Preferably, the first machine learning method performed by the real-time sound analysis apparatus includes a least mean square method (LMS), and a logistic regression classifier is learned using the least mean square method. I can.

Preferably, the second machine learning method performed by the additional analysis device is a deep learning method, and the second function may be optimized through error backpropagation.

The signal processing unit may further include a step of forming a frame group redefining consecutive frames into a plurality of frame groups. It is preferable that a set of frames included in each frame group among the plurality of frame groups is different from a set of frames included in another frame group among the plurality of frame groups, and a time interval between each frame group is constant.

The extraction of feature vectors and classification of sound types and causes may be performed for each frame group as a unit.

The first learning unit may supplement the first function by receiving the feedback input by the user and learning real-time sound data corresponding to the feedback using a machine learning method.

To this end, the real-time sound analysis device may include a feedback receiving unit. The first feedback receiving unit may directly receive feedback from a user or may receive feedback from another device or module.

In one embodiment of the present invention, the apparatus for analyzing real-time sound based on artificial intelligence may further include a feedback receiving unit, and the feedback receiving unit transmits the feedback input by the user to at least one of the first learning unit and the second learning unit. And, the learning unit receiving the feedback may supplement the corresponding function. For example, the second learning unit may use information obtained from the real-time sound analysis device as additional learning data.

The real-time sound analysis device may further include a first display unit, and the additional analysis device may further include a second display unit, and each display unit outputs sound types and/or sound causes classified by a corresponding analysis device. can do.

The additional analysis device may be a server or a mobile communication terminal. When the additional analysis device is a server, the second communication unit may transmit at least one of the sound type and the sound cause to the mobile communication terminal, and may again receive a user's feedback input from the mobile communication terminal. When the additional analysis device is a mobile communication terminal, the mobile communication terminal directly performs sound cause analysis, and when the user inputs feedback to the mobile communication terminal, the mobile communication terminal may directly transmit the user's feedback to the real-time sound analysis device. .

Preferably, when the first communication unit receives user feedback on the sound type, the first learning unit may supplement the first classifier by learning about sound data corresponding to the feedback in a first machine learning method. I can. This learning process allows the classifier to derive more accurate results by continuously repeating the process of collecting real-time sound data and receiving feedback.

Preferably, when the second communication unit receives a user's feedback on the cause of the sound, the second learning unit may supplement the second classifier by learning about sound data corresponding to the feedback using a second machine learning method. I can. This learning process allows the classifier to derive more accurate results by continuously repeating the process of collecting real-time sound data and receiving feedback.

For example, upon receiving a user's feedback on the sound type and sound cause, the first classifier and/or the second classifier may be developed through machine learning and/or deep learning based on the feedback.

The signal processing unit performs signal processing for optimizing the real-time sound data to be easily processed, and after pre-processing the real-time sound data, divides the pre-processed sound data into a plurality of frames in a time domain, A feature vector may be extracted from each frame of the plurality of frames. The pre-processing may be, for example, normalization, frequency filtering, temporal filtering, and windowing.

At least one dimension of the feature vector may be a dimension related to the sound type information.

Preferably, the second machine learning method is a deep learning method, and the second classifier may be developed through error backpropagation.

In the real-time sound analysis method according to an embodiment of the present invention, training a first function for classifying sound category information by learning pre-collected sound data by machine learning (S110) , Collecting the sound generated in real time through the input unit (S120), the step of processing the collected real-time sound data to facilitate learning (S130), the signal-processed real-time sound data through the first function Classifying as (S140), determining whether the sound type classified in the step of classifying as the sound type corresponds to the sound of interest (S150), when the classified sound type corresponds to the sound of interest, signal-processed real-time sound And transmitting data from a real-time sound analysis device to an additional analysis device (S160), and learning the real-time sound data using a machine learning method to supplement the first function (S190).

Preferably, the real-time sound analysis device may include receiving a result of analyzing a sound cause from the additional analysis device through a second function learned by deep learning (S170).

In an embodiment of the present invention, the operation S180 may further include outputting a sound of interest and/or an analysis result of the sound of interest to the first display unit D1.

The method is illustrated by FIG. 8.

According to an embodiment of the present invention, it is possible to learn the types and causes of sounds collected in real time based on machine learning, and more accurately predict the types and causes of sounds collected in real time.

1 is a conceptual diagram illustrating a real-time sound analysis method and apparatus related to the present invention.
2 is a diagram showing a first embodiment of a real-time sound analysis apparatus according to the present invention.
3 is a diagram showing a second embodiment of a real-time sound analysis apparatus according to the present invention.
4 is a diagram showing a third embodiment of a real-time sound analysis apparatus according to the present invention.
5 is a block diagram of a real-time sound analysis method according to the present invention.
6 is a block diagram of signal processing of sound data.
7 is a diagram illustrating an embodiment of extracting a feature vector by classifying sound data for each frame.
8 is a block diagram of a real-time sound analysis method according to the present invention.

Hereinafter, exemplary embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings, but identical or similar elements are denoted by the same reference numerals regardless of reference numerals, and redundant descriptions thereof will be omitted. The suffixes "module" and "unit" for components used in the following description are given or used interchangeably in consideration of only the ease of preparation of the specification, and do not have meanings or roles that are distinguished from each other by themselves. In addition, in describing the embodiments disclosed in the present specification, when it is determined that a detailed description of related known technologies may obscure the subject matter of the embodiments disclosed in the present specification, the detailed description thereof will be omitted. In addition, the accompanying drawings are for easy understanding of the embodiments disclosed in the present specification, and the technical idea disclosed in the present specification is not limited by the accompanying drawings, and all modifications included in the spirit and scope of the present invention It should be understood to include equivalents or substitutes.

1 is a conceptual diagram illustrating a real-time sound analysis method and apparatus related to the present invention.

When the ambient sound 10 occurs, it is sensed in real time through an input unit 610 such as a microphone and stored as data. The ambient sound 10 may be a sound that has no meaning, or may be a sound that is not of interest to the user, that is, noise 12, or may be a sound of interest 13 that the user wants to classify or analyze. . In some cases, the sound of interest 13 may be a patient's groan 131, a baby's cry 132, or an adult's voice 133. However, the sound of interest 13 is not limited to the above three examples, and may be any sound such as a traffic accident collision sound, vehicle operation sound, and animal sound.

For example, when the sound of interest 13 is an adult's voice 133, the baby crying sound 132 may be classified as a noise 12. For example, when the sound of interest 13 is an animal sound, a patient's groan 131, a baby's cry 132, an adult's voice 133, and a traffic accident collision sound may be classified as noise 12. .

The classification of such sound types may be performed by the first classifier 630 in the real-time sound analysis apparatus 600. The first classifier 630 may be enhanced with a machine learning method through the first learning unit 650. First, a sound type is labeled on at least a part of the pre-collected sound data S001. Thereafter, the first learning unit 650 learns the first function f1 of the first classifier 630 using a machine learning method using pre-collected sound data S001 labeled with a sound type. . The first classifier 630 may be a logistic regression classifier.

Supervised Learning is one of the machine learning methods for training a function using training data. Training data generally contains the properties of the input object in the form of a vector, and the desired result for each vector is It is marked what it is. Among the trained functions, outputting continuous values is called regression, and marking what kind of values a given input vector is called classification. On the other hand, unsupervised learning, unlike supervised learning, does not give a target value for an input value.

Preferably, in an embodiment of the present invention, the first learning unit 650 may use a semi-supervised learning method having an intermediate characteristic between supervised learning and unsupervised learning. The quasi-supervised learning refers to using both data with a target value indicated and data not indicated for training. In most cases, the training data used in this method has a small amount of data with a target value indicated and a lot of data not indicated. Using the quasi-supervised learning can greatly save time and cost for labeling.

The task of displaying the target value is labeling. For example, if ambient sound (10) is generated and the sound data is input, labeling indicates whether the type of sound is silent (11), noise (12), or sound of interest (13). It's a job. In other words, labeling is a basic operation for pre-marking an example of an output in data and learning a function using a machine learning algorithm.

What a person directly displays is supervised learning, and what does not display is unsupervised learning, and some is directly marked by a person, and others are not marked as semi-supervised learning.

In an embodiment of the present invention, the first analysis device 600 may perform an auto-labeling operation based on semi-supervised learning. Label means the result values that the function should output. For example, the labels are result values of silence, noise, baby crying, and baby sounds excluding crying sounds. The automatic labeling may be performed in the following order. The automatic labeling may be performed, for example, by the first learning unit 650.

First, a person intervenes and displays a label for a certain number of data (eg, 100). For sound data collected from then on, the label is not displayed, but appropriate signal processing is performed and then dimension reduction is performed. A clustering technique that classifies a group with homogeneity is used to group a plurality of data classified as a homogeneity into a single data group. In this case, the clustering technique is classified based on a predetermined hyperparameter, but the hyperparameter may be changed according to a learning accuracy performed in the future.

Next, when a plurality of data groups are formed, only a predetermined number (for example, 4 data) for each data group is randomly selected to determine which element has a characteristic. For example, if three or more of the four data selected from the first data group are found to correspond to noise, all of the first data group are regarded as noise, and all data in the first data group are labeled as noise. . If two or less of the four data selected from the second data group correspond to the baby's crying sound, all data in the second data group are labeled as noise or silence.

Next, labeling is performed with this predetermined algorithm, and the labeled data is used as training data. In this case, if the accuracy index increases, labeling is continued with the algorithm, and if the accuracy index decreases, the dimensionality reduction method is changed or the clustering parameter is changed, and the previous process is performed again.

On the other hand, although the real-time sound analysis device 600 provides convenience to the user 2 by detecting and displaying the sound of interest 13, the user 2 is a human with hearing, and the patient moans in the surroundings. It can recognize whether it is making or not, it can recognize whether a baby is crying or not, and it can recognize whether an animal is making a sound or not. This is an element that can be distinguished if the hearing ability, one of the five senses of humans, is not damaged. However, it is difficult for the user 2 to hear only the sound when the patient makes a groan and know which part is painful and makes the groan. Similarly, it is difficult for the user 2 to hear only the sound when the baby is crying and know what the baby wants.

When the sound of interest 13 is detected, the real-time sound analysis device 600 transmits the signal-processed real-time sound data to the additional analysis device 700. There may be various causes of the sound of interest 13 to be generated, such as a first cause, a second cause, and a third cause, and the demand of the user 2 is concentrated on the cause of the sound of interest 13.

For example, if the sound of interest 13 is the crying sound of the baby 132, the baby may have cried because he was hungry, or he may have cried because he felt stool, or because of discomfort after packing a diaper. Maybe he was sleepy and cried. Or, depending on your emotional state, you may have been sad and cry, or you may be sad and rejoice and make a cry. As such, babies' crying sounds may sound similar to an adult's hearing, but the causes are varied.

For example, if the sound of interest 13 is the patient's groan 131, according to an embodiment of the present invention, it is possible to detect a specific disease that is difficult to detect early through various sounds generated from the patient's voice. Do. In addition, various sounds generated by the patient's body rather than the patient's groan 131 may also be the sound of interest 13. Specifically, after detecting the urine sound of the patient as the sound of interest 13 by the real-time sound analysis device 600, the additional analysis device 700 may analyze whether the patient suffers from an enlarged prostate.

For example, when the sound of interest 13 is a bearing friction sound, according to an embodiment of the present invention, it is possible to detect a defect that may cause an accident early through various sounds generated as the bearing rotates.

The classification of the sound cause may be performed by the second classifier 710 in the additional analysis device 700. The function of the second classifier 710 may be enhanced through a deep learning method through the second learning unit 750. First, a sound cause is labeled on at least a part of the sound data S001 collected in advance. Thereafter, the second learning unit 750 learns the second function f2 of the second classifier 710 using a deep learning method using pre-collected sound data S001 in which the sound cause is labeled. .

Through communication between the real-time sound analysis device 600 and the additional analysis device 700, the user 2 can determine whether the sound of interest 13 is generated and the causes 21, 22, and 23 of the sound of interest 13 .

In an embodiment of the present invention, the cause of the sound may be a state of a subject generating the sound. In other words, if the'cause' of the baby's cry is hunger, the baby can be considered to be in a'state' of hunger. The term'state' may be understood as a primary meaning that the baby is crying, but the data to be obtained from the additional analysis device 700 according to an embodiment of the present invention has a secondary meaning such as the reason why the baby is crying. It is preferable to be understood as.

In an embodiment of the present invention, the real-time sound analysis apparatus 600 may improve the accuracy of analyzing the state of the analysis object (cause of sound generation) by detecting information other than sound and performing analysis together with sound. For example, you can detect and further analyze the vibrations your baby turns. Accordingly, a device for sensing vibration may be additionally configured. Alternatively, a module for sensing vibration may be mounted on the real-time sound analysis device 600. The device for sensing vibration is only an example, and any device that detects information related to the set sound of interest 13 can be added.

In one embodiment of the present invention, the real-time sound analysis device 600 may improve the accuracy of analyzing the state of the analysis object (cause of sound generation) by detecting a plurality of sounds of interest 13 and performing analysis together with the sound. .

For example, if the crying sound of a baby is detected after the sound of someone falling or bumping is detected, it may be less likely that the cause will be analyzed as'painfulness' if the device analyzes only the crying sound of the baby (for example, For example, 60%), by analyzing the information that the falling sound and the bumping sound occurred immediately before the crying sound, the cause of the crying sound of the baby is'painfulness' and analyzed with a higher probability (for example, 90%). I can. That is, the reliability of the device can be improved.

In one embodiment of the present invention, the real-time sound analysis device 600 is preferably disposed near an object for which the user 2 wants to sense sound. Therefore, the real-time sound analysis device 600 may require mobility, and its data storage capacity may be small. That is, in the case of a small (or ultra-small) device such as a sensor included in a device that needs to be moved, it is common that computing resources (memory usage, CPU usage), network resources, and battery resources are very insufficient compared to a general desktop or server environment. That is, when the surrounding sound 10 occurs after the real-time sound analysis device 600 is placed, it is preferable that only core information necessary for artificial intelligence analysis, especially machine learning or deep learning, is stored among the original data for this.

For example, a processor based on a microcontroller unit (MCU) is only a few hundred thousandths of a processor used in a desktop computer. In particular, in the case of media data such as sound data, since the data size is very large, it is impossible to store and process the original data in memory like a desktop computer. For example, 4 minutes of audio data (44.1KHz sampling rate) is usually about 40MB, but the total memory capacity of a high-performance MCU system is only 64KB, which is about 1 in 600.

Therefore, the real-time sound analysis apparatus 600 according to an embodiment of the present invention stores the original data to be analyzed in a memory and processes the original data in an intermediate process (for example, FFT, Arithmetic computation, etc.). ) First, and then only some information necessary for the artificial intelligence analysis process is created as a core vector.

The core vector is different from preprocessing and feature vectors, and does not undergo a process of performing a feature vector operation immediately using the result after preprocessing the original data in real time. Specifically, preprocessed intermediate calculation values required for calculation of feature vectors to be obtained later and intermediate calculation values of original data are stored. This is not strictly speaking the compression of the original data.

Therefore, the core vector operation is performed before the preprocessing and feature vector extraction, and the real-time sound analysis apparatus 600 stores the core vector instead of the original data, thereby overcoming the limitation of insufficient computational power and storage space.

Preferably, data transmitted from the real-time sound analysis device 600 to the additional analysis device 700 (or to another device) may be key vector information of real-time sound data. That is, since the operation of transmitting the sound collected in real time to the additional analysis device 700 (or to another device) must also be performed in real time, only the core vector information generated by the signal processing unit of the real-time sound analysis device 600 is an additional analysis device. It is advantageous to transfer to 700.

Hereinafter, the interaction between the sound source 1, the real-time sound analysis device 600, the additional analysis device 700, the mobile communication terminal 800, and the user 2 will be described in detail using FIGS. 2 to 5.

2 is a diagram showing a first embodiment of a real-time sound analysis apparatus according to the present invention.

The sound source 1 may be a baby, an animal, or an object. In Figure 2 a crying baby is shown. For example, when the baby's crying sound 132 is detected by the input unit 610, it is stored as real-time sound data (S002) and processed by the signal processing unit 620 to match machine learning. The signal-processed real-time sound data is classified as a sound type by a first classifier 630 including a first function f1.

The real-time sound data classified as sound type by the first classifier 630 is transmitted to the additional analysis device 700 through communication between the first communication unit 640 and the second communication unit 740. Among the transmitted real-time sound data, data related to a sound of interest is classified as a sound cause by the second classifier 730.

The first learning unit 650 learns the first function f1 of the first classifier 630 by machine learning. Here, the input is the ambient sound (10), and the output is the sound type. The sound types include silence 11, noise 12, and sound of interest 13, but other types may be included. For example, a plurality of sounds of interest may be placed, and sound types may include silence 11, noise 12, a first sound of interest, a second sound of interest, and a third sound of interest. For example, the silence 11 and the noise 12 may also be changed to other types.

The first classifier 630 includes a first function f1 learned using pre-collected sound data S001. That is, pre-learning is performed so that the input real-time sound data can be classified into the output sound type through the first function f1. However, even if the pre-learning is performed, since the first function f1 is not perfect, it is desirable to be continuously supplemented. After the real-time sound data (S002) is continuously introduced and the result values are output, when the user 2 inputs feedback on the result values with errors, the first learning unit 650 reflects this and The classifier 630 is trained again. As this process is repeated, the first function f1 is gradually supplemented, and the accuracy of classification of sound types is improved.

The second classifier 730 includes a second function f2 learned using pre-collected sound data S001. That is, prior learning is performed so that the input real-time sound data can be classified as an output sound source through the second function f2. However, even if the prior learning is performed, since the second function f2 is not perfect, it is desirable to be continuously supplemented. After the real-time sound data (S002) is continuously introduced and the result values are output, when the user 2 inputs feedback on the result values with errors, the second learning unit 750 reflects this and The classifier 730 is trained again. As this process is repeated, the second function f2 is gradually supplemented, and the accuracy of classification of sound causes is improved.

The real-time sound analysis device 600 may include a first display unit 670. The first display unit 670 may be, for example, a lighting, a speaker, a text display unit, and a display panel. The first display unit 670 may display a sound type, and preferably, a sound cause transmitted from the additional analysis device 700 may be displayed.

The additional analysis device 700 may include a second display unit 770. The second display unit 770 may be, for example, a lighting, a speaker, a text display unit, and a display panel. The second display unit 770 may display the cause of the sound, and preferably, may display the type of sound transmitted from the real-time sound analysis device 600.

Components of the real-time sound analysis device 600 are controlled by the first control unit 660. The first control unit 660 may command the signal processing unit 620 and the first classifier 630 to perform signal processing and classification when the ambient sound 10 is detected by the input unit 610, and the classification result and A command may be transmitted to the first communication unit 640 to transmit real-time sound data to the additional analysis device 700. In addition, according to the inflow of real-time sound data, the first learning unit 650 may determine whether to perform learning to supplement the first classifier 630. In addition, the first control unit 660 may control the classification result to be displayed on the first display unit 670.

Components of the additional analysis device 700 are controlled by the second control unit 760. The second control unit 760 may issue a command to the second classifier 730 to perform classification upon receiving data from the real-time sound analysis device 600, and transmit the classification result to the real-time sound analysis device 600. 2 A command can be transmitted to the communication unit 740. In addition, according to the inflow of real-time sound data, the second learning unit 750 may determine whether to perform learning to supplement the second classifier 730. In addition, the second control unit 760 may control the classification result to be displayed on the second display unit 770.

The user 2 is provided with an analysis of the type and cause of sound through an application installed in the mobile communication terminal 800. That is, the real-time sound analysis device 600 transmits the real-time sound data and sound type classification results processed by the first communication unit 640 to the second communication unit 740, and the additional analysis device 700 is based on the received data. Classify the sound cause by Thereafter, the additional analysis device 700 transmits the analysis result performed by the real-time sound analysis device 600 and the additional analysis device 700 to the mobile communication terminal 800, and the user 2 transmits the analysis result to the analysis result through an application. I can access it.

The user 2 may provide feedback on whether the analysis result is correct or incorrect through the application, and the feedback is transmitted to the additional analysis device 700. The real-time sound analysis device 600 and the additional analysis device 700 share the feedback and relearn the corresponding functions f1 and f2 by the respective controllers 660 and 760. That is, real-time sound data corresponding to the feedback is labeled by reflecting the feedback, and the learning units 650 and 750 learn the classifiers 630 and 730 to improve the accuracy of each function.

In the embodiment of FIG. 2, the additional analysis device 700 may be a server.

3 is a diagram showing a second embodiment of a real-time sound analysis apparatus according to the present invention. Description of the overlapping portion with FIG. 2 will be omitted.

The user 2 may receive an analysis result for the type and cause of sound directly from the real-time sound analysis device 600. The analysis result may be provided through the first display unit 670. The user 2 may directly provide feedback on whether the analysis result is correct or incorrect to the real-time sound analysis device 600, and the feedback is transmitted to the additional analysis device 700. The real-time sound analysis device 600 and the additional analysis device 700 share the feedback and relearn the corresponding functions f1 and f2 by the respective controllers 660 and 760. That is, real-time sound data corresponding to the feedback is labeled by reflecting the feedback, and the learning units 650 and 750 learn the classifiers 630 and 730 to improve the accuracy of each function.

In the embodiment of FIG. 3, the additional analysis device 700 may be a server.

4 is a diagram showing a third embodiment of a real-time sound analysis apparatus according to the present invention. Description of the overlapping portion with FIG. 2 will be omitted.

The user 2 may receive an analysis result of the type and cause of sound directly from the additional analysis device 600. The analysis result may be provided through the second display unit 770. The user 2 may directly provide feedback on whether the analysis result is correct or incorrect to the additional analysis device 700, and the feedback is transmitted to the real-time sound analysis device 600. The real-time sound analysis device 600 and the additional analysis device 700 share the feedback and relearn the corresponding functions f1 and f2 by the respective controllers 660 and 760. That is, real-time sound data corresponding to the feedback is labeled by reflecting the feedback, and the learning units 650 and 750 learn the classifiers 630 and 730 to improve the accuracy of each function.

In the embodiment of FIG. 4, the additional analysis device 700 may be a part of a mobile communication terminal. That is, the mobile communication terminal 800 may include the additional analysis device 700, and in this case, the user 2 may directly input the feedback to the additional analysis device 700.

5 and 8 are block diagrams of a real-time sound analysis method according to the present invention.

The real-time sound analysis method and apparatus according to the present invention operates by the interaction of the real-time sound analysis device 600 and the additional analysis device 700. The pre-collected sound data S001 may be collected by a crawling method, but is not limited thereto. To enable each classifier (630, 730) to perform a minimum function, at least a part of both the first learning unit 650 of the real-time sound analysis device 600 and the second learning unit 750 of the additional analysis device 700 Pre-collected sound data (S001) labeled with is required. The pre-collected sound data (S001) is transmitted to each analysis device (600, 700). The operation of training the first function f1 and the second function f2 by the pre-collected sound data S001 precedes the classification operation.

5 and 8 are referred together. After the first function (f1) and the second function (f2) are optimized to some extent by training and real-time sound data (S002) is input through the input unit 610, a signal processing step including pre-processing and feature vector extraction (S130) is performed. Thereafter, they are classified by sound type through the first function f1.

The sound type may include silence 11 and noise 12, and at least one sound of interest 13 that the user is interested in may be designated. For example, the interest sound 13 may be a baby crying sound, and the interest sound 13 may be a baby crying sound and a parent's voice.

The first control unit 660 may determine whether the classified sound type corresponds to a sound of interest. If the classified sound type corresponds to the sound of interest, the signal-processed real-time sound data is transmitted from the real-time sound analysis device 600 to the additional analysis device.

The second communication unit 740 receiving the signal-processed real-time sound data transfers this information to the second classifier 730, and the second classifier 730 classifies each sound cause through a second function f2.

The classification result for the sound cause may be transmitted to an external device. The external device may be the real-time sound analysis device 600, but may be another device.

After transmitting the sound cause classification result to the first communication unit 640 through the second communication unit 740, the display unit of each analysis device 600, 700 may output a sound type and/or an analysis result for the sound cause. .

After going through a series of processes, the first learning unit 650 may supplement the first function by learning the collected real-time sound data using a machine learning method. Here, when a user's feedback is received, it is preferable to improve the first function by learning real-time sound data corresponding to the feedback using a machine learning method.

After going through a series of processes, the second learning unit 750 may supplement the second function by learning the collected real-time sound data in a deep learning method. Here, when a user's feedback is received, it is preferable to improve the second function by learning real-time sound data corresponding to the feedback in a deep learning method.

The real-time sound analysis device 600 extracts feature vectors after signal processing and classifies them into sound types. The additional analysis device 700 receives real-time sound data in which a sound type is classified from the real-time sound analysis device 600 and classifies it as a sound cause through a second function. When the classification operation is completed in each of the analysis devices 600 and 700, each function f1, f2 may be supplemented.

In an embodiment of the present invention, when the sound of interest 13 is a simple baby sound rather than a baby crying sound 132, the real-time sound analysis method and apparatus according to the present invention provides more useful information to the user 2 can do.

That is, the baby may make a pre-crying sound before crying, and if the sound of interest 13 is the sound before crying, and the user 2 receives the sound type and cause analysis for this, A quicker response is possible than if the baby was crying and then provided with an analysis of the baby's cries.

6 is a block diagram of signal processing of sound data.

The signal processing unit 620 optimizes real-time sound data to facilitate machine learning, and the optimization may be performed by signal processing.

Preferably, the signal processing unit 620 undergoes pre-processing such as, for example, normalization, frequency filtering, temporal filtering, and windowing, and stores the pre-processed sound data in time. After dividing the region into a plurality of frames, a feature vector of each frame or frame group may be extracted.

The real-time sound data expressed as a feature vector may constitute one unit for each frame or for each frame group.

7 is a diagram illustrating an embodiment of extracting a feature vector by classifying sound data for each frame.

Each frame (FR1, FR2, FR3, FR4, FR5) cut by 100ms in the time domain is defined, from which a single frame feature vector (V1) is extracted. As shown in FIG. 7, five consecutive frames are grouped and defined as one frame group (FG1, FG2, FG3), and a frame group feature vector (V2) is extracted from this. Analysis may be performed for each single frame, but analysis may be performed for each frame group (FG1, FG2, FG3) to prevent overload and improve accuracy due to data processing.

1: sound source
2: user
10: ambient sound
11: silent
12: noise
13: sounds of interest
131: patient moaning
132: baby cry
133: adult voice
21: first cause
22: second cause
23: third cause
600: real-time sound analysis device
610: input
620: signal processing unit
630: first classifier
640: first communication unit
650: first learning unit
660: first control unit
670: first display unit
700: additional analysis device
730: second classifier
740: second communication unit
750: second learning unit
760: second control unit
770: second display unit
S001: Pre-collected sound data
S002: Real-time sound data
FR1, FR2, FR3, FR4, FR5: Frame
FG1, FG2, FG3: frame group
V1, V2: feature vectors

Claims (13)

An input unit for collecting sounds generated in real time;
A signal processing unit processing the collected real-time sound data to facilitate deep learning;
A first classifier for classifying signal-processed sound data into sound types by a first function for classifying sound type information learned by deep learning; And
Including; a first communication unit for transmitting and receiving information on sound data,
The first communication unit transmits the signal-processed sound data to an additional analysis device, which is a server, and receives a result of analyzing the sound cause through a second function learned by deep learning from the additional analysis device,
Mobility is required, and data storage capacity, battery resources, and computing power are less than those of the additional analysis device. To classify the sound type,
The first function and the second function become more accurate as the number of data to be learned increases,
Real-time sound analysis device based on artificial intelligence.
delete delete The method of claim 1,
Further comprising a learning unit for training a first function for classifying sound type information by learning the pre-collected sound data in a deep learning method,
The learning unit supplements the first function by learning the real-time sound data in a deep learning method,
Real-time sound analysis device based on artificial intelligence.
The method of claim 4,
The learning unit receives the feedback input by the user and learns real-time sound data corresponding to the feedback in a deep learning method to supplement a first function,
Real-time sound analysis device based on artificial intelligence.
The method of claim 5,
Further comprising a first feedback receiving unit, wherein the first feedback receiving unit receives a direct feedback from a user or receives a feedback from another device or module,
Real-time sound analysis device based on artificial intelligence.
The method of claim 4,
The learning unit receives the feedback input by the user and learns real-time sound data corresponding to the feedback using a machine learning method to supplement a first function,
Real-time sound analysis device based on artificial intelligence.
The method of claim 1,
Further comprising a first control unit,
The first control unit determines whether the sound type classified by the first classifier corresponds to the sound of interest, and when the classified sound type corresponds to the sound of interest, controls to transmit signal-processed sound data to an additional analysis device. ,
Real-time sound analysis device based on artificial intelligence.
The method of claim 4,
The learning unit performs automatic labeling based on semi-supervised learning on the collected sound data,
Real-time sound analysis device based on artificial intelligence.
The method of claim 9,
The automatic labeling is performed by a predetermined algorithm or by a user's feedback,
Real-time sound analysis device based on artificial intelligence.
The method of claim 1,
The signal processing unit performs pre-processing, frame generation, and feature vector extraction of real-time sound data, but generates only a part of real-time sound data as a core vector before pre-processing,
Real-time sound analysis device based on artificial intelligence.
Collecting sounds generated in real time through an input unit;
Signal processing the collected real-time sound data to facilitate learning;
Classifying the signal-processed real-time sound data into sound types through a first function for classifying sound type information learned by deep learning;
Determining whether the sound type classified in the sound type classification step corresponds to a sound of interest;
If the classified sound type corresponds to the sound of interest, transmitting the signal-processed real-time sound data from the real-time sound analysis device to the additional analysis device;
Supplementing the first function by learning the real-time sound data using a deep learning method; And
And receiving, by the real-time sound analysis device, a result of analyzing the sound cause from the additional analysis device through a second function for classifying sound cause information learned by deep learning,
The real-time sound analysis device requires mobility, and data storage capacity, battery resources, and computational power are less than that of the additional analysis device. Can be classified,
The first function and the second function become more accurate as the number of data to be learned increases,
Real-time sound analysis method based on artificial intelligence.
delete

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