JP2020527433A - Method and device for obtaining human fatigue value - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose a method and an apparatus for acquiring a human body fatigue value. SOLUTION: The method collects a skin electrical resistance signal to be tested, performs low-pass filtering on the collected skin electrical resistance signal to obtain a filtered skin electrical resistance signal, and filters the collected skin electrical resistance signal. The subsequent skin electrical resistance signal is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing, and the target skin electrical resistance signal is obtained by capturing a signal satisfying a predetermined condition from the skin electrical resistance signal after the differential processing. To obtain the target skin electrical resistance signal after moving averaging by performing mobile averaging on the target skin electrical resistance signal, and to obtain the target skin electrical resistance signal after moving averaging, and to test the fatigue Includes obtaining the resistance value of the test object that reflects the degree. According to the present application, it is possible to solve the problem that it is difficult to obtain the fatigue value of the test target based on the skin electrical resistance of the test target in the technique. [Selection diagram] Fig. 1

Description

The present invention relates to the field of test technology, and more particularly to a method and apparatus for obtaining a human body fatigue value.

Bioelectricity is the change in potential and polarity that occurs during the life of living organs, tissues and cells. This is one of the physical and physico-chemical changes in life activity, an expression of normal physiological activity, and one of the basic characteristics of living tissues. When a living body receives an external stimulus or has high emotions, the electrical resistance of the skin decreases due to the increase in the potential difference between the two points of the skin, and such a phenomenon is called physiological electroreflex. In existing techniques, when analyzing the relationship between emotion and cutaneous electrical resistance, it was usually distinguished by the change in resistance magnitude whether the emotion under test was calm or excited. However, it is difficult to obtain the degree of fatigue of the test target based on the skin electrical resistance of the test target.

We have not yet presented an effective solution to the problem that it is difficult to obtain the fatigue value of the test target based on the skin electrical resistance of the test target in this technique.

An object of the present application is to provide a method and an apparatus for acquiring a human body fatigue value, which can solve a problem that it is difficult to acquire a fatigue value of a test object based on the skin electrical resistance of the test object in the technique.

In order to realize the above-mentioned object, according to one aspect of the present application, a method for obtaining a human body fatigue value is provided. The method involves collecting the skin electrical resistance signal to be tested, performing low-pass filtering on the collected skin electrical resistance signal to obtain the filtered skin electrical resistance signal, and the filtered skin. The electrical resistance signal is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing, and the signal satisfying a predetermined condition is captured from the skin electrical resistance signal after the differential processing to obtain the target skin electrical resistance signal. Based on the fact that the target skin electrical resistance signal is subjected to the moving averaging treatment to obtain the target skin electrical resistance signal after the moving averaging treatment, and the target skin electrical resistance signal after the moving averaging treatment is obtained, the fatigue of the test object is subjected to the test. Acquiring the resistance value of the test object that reflects the degree includes.

Further, to obtain the fatigue value of the test target based on the target skin electrical resistance signal after the mobile averaging treatment, the target skin electrical resistance signal after the mobile averaging treatment is normalized to obtain the normalized fatigue value. This includes obtaining a target skin electrical resistance signal and obtaining a fatigue value of the test object based on the normalized target skin electrical resistance signal.

Further, after acquiring the fatigue value of the test object based on the target skin electrical resistance signal after normalization, the method analyzes the fatigue value of the test object and the fatigue value of the test object. Further including generating the analysis result of the test object and generating the fatigue value report of the test object based on the analysis result.

Furthermore, to obtain the target skin electrical resistance signal after normalization by normalizing the target skin electrical resistance signal after the moving average treatment, the target skin after the moving average treatment can be obtained by using a support vector machine classifier. It further includes subjecting the electrical resistance signal to a normalization process to obtain the normalized target skin electrical resistance signal.

Further, to obtain the skin electrical resistance signal after the differential processing by performing the differential processing on the filtered skin electrical resistance signal, the skin is subjected to digital-to-analog conversion on the filtered skin electrical resistance signal. This includes obtaining a digital signal of electrical resistance and performing differential processing on the digital signal of skin electrical resistance to obtain a skin electrical resistance signal after the differential processing.

Further, acquiring the fatigue value of the test object based on the target skin electrical resistance signal after normalization is a test corresponding to the target skin electrical resistance signal after normalization by the fatigue analysis model of the test object. Including acquiring the fatigue value of the target, the fatigue analysis model of the test target is a model constructed after training with the fatigue values of a plurality of test targets in advance.

Further, after acquiring the fatigue value of the test object based on the target skin electrical resistance signal after normalization, the method determines whether or not the fatigue value of the test object exceeds a predetermined value. When it is determined that the fatigue value of the test object exceeds a predetermined value, it is determined that the test object is in the fatigue period, and the fatigue value of the test object belongs to, including mild fatigue and severe fatigue. Further including determining the fatigue level.

In order to achieve the above-mentioned object, according to another aspect of the present application, a device for acquiring a human body fatigue value is provided. The device is installed so as to obtain a skin electrical resistance signal after filtering by performing low-pass filtering on the collected skin electrical resistance signal and a collection unit installed to collect the skin electrical resistance signal to be tested. The filtering unit, the first processing unit installed so as to obtain the skin electrical resistance signal after the differential treatment by performing differential processing on the filtered skin electrical resistance signal, and the skin after the differential treatment. A second processing unit installed so as to acquire a signal satisfying a predetermined condition from the electric resistance signal to obtain a target skin electric resistance signal, and a moving averaging process is performed on the target skin electric resistance signal after the moving averaging process. Based on the third processing unit installed so as to obtain the target skin electrical resistance signal of the above and the target skin electrical resistance signal after the mobile averaging treatment, the fatigue value of the test target reflecting the degree of fatigue of the test target is determined. Includes acquisition units installed to acquire.

Further, the acquisition unit has a processing means installed so as to perform a normalization process on the target skin electrical resistance signal after the moving average processing to obtain the target skin electrical resistance signal after the normalization, and a target after the normalization. Includes an acquisition means set up to acquire the fatigue value of the test subject based on the skin electrical resistance signal.

In order to achieve the above-mentioned object, according to another aspect of the present application, a storage medium for storing a program for executing the method for acquiring a human body fatigue value according to any one of the above is provided.

In order to achieve the above object, according to another aspect of the present application, there is provided a processor that executes a program for executing the method for acquiring a human body fatigue value according to any one of the above.

According to the present application, a step of collecting the skin electrical resistance signal to be tested, a step of performing low-pass filtering on the collected skin electrical resistance signal to obtain a filtered skin electrical resistance signal, and a step of filtering the skin electrical resistance signal. A step of differentiating the resistance signal to obtain a skin electrical resistance signal after the differential processing, and a step of capturing a signal satisfying a predetermined condition from the skin electrical resistance signal after the differential processing to obtain a target skin electrical resistance signal. Based on the step of performing mobile averaging processing on the target skin electrical resistance signal to obtain the target skin electrical resistance signal after the moving averaging treatment and the target skin electrical resistance signal after the moving averaging treatment, the degree of fatigue of the test target is determined. Includes a step to obtain the resistance value of the test object to be reflected. According to the present application, it is possible to solve the problem that it is difficult to obtain the fatigue value of the test target based on the skin electrical resistance of the test target in the technique. By collecting the skin electrical resistance signal of the test target and then obtaining the fatigue value of the test target through filtering, differentiation processing, acquisition, and moving average processing, the degree of fatigue of the test target can be determined based on the skin electrical resistance of the test target. The effect that can be obtained can be realized.

The drawings constituting a part of the present application are for further understanding of the present application, and the examples and their explanations shown in the present application are for interpreting the present application and are not intended to limit the present application.

It is a flowchart of the acquisition method of the human body fatigue value provided in the Example of this application. It is a figure which shows the support vector machine classifier in the acquisition method of the human body fatigue value provided in the Example of this application. It is a figure which shows the acquisition device of the human body fatigue value provided in the Example of this application.

As long as there is no contradiction, the examples of the present application and the features in the examples can be combined. Hereinafter, the present application will be described in detail by combining examples with reference to the drawings.

In order for those skilled in the art to understand the technical proposal of the present application more easily, the technical proposal of the embodiment of the present application will be clearly and completely described below by combining the drawings in the examples of the present application. It goes without saying that the examples are not all but a part of the examples of the present application. Based on the embodiments of the present application, all other embodiments obtained by those skilled in the art without the need for creative acts are included in the scope of protection of the present application.

The terms "first", "second", etc. used in the specification and claims of the present application and the drawings are for distinguishing similar objects, and limit a specific order or front-back order. It's not a thing. Numerical values used in this way are interchangeable in appropriate circumstances so that the embodiments of the present application described herein can be realized in a different order than shown or described in the drawings. Also, "including", "having" and their variants cover non-exclusive inclusion, for example, a process, method, system, product or device involving a series of steps or units is clearly exemplified. Represents not being limited to steps or units, but also including other steps or units not explicitly exemplified or specific to these processes, methods, products or equipment.

According to the embodiment of the present application, a method for obtaining a human body fatigue value is provided.

FIG. 1 is a flowchart of a method for acquiring a human body fatigue value according to an embodiment of the present application. As shown in FIG. 1, the method comprises steps S101-S106.

In step S101, the skin electrical resistance signal to be tested is collected.

In step S102, the collected skin electrical resistance signal is low-pass filtered to obtain the filtered skin electrical resistance signal.

In step S103, the filtered skin electrical resistance signal is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing.

In step S104, a signal satisfying a predetermined condition is captured from the skin electrical resistance signal after the differential processing to obtain a target skin electrical resistance signal.

In step S105, the target skin electrical resistance signal is subjected to a moving average treatment to obtain the target skin electrical resistance signal after the moving average treatment.

In step S106, the fatigue value of the test target is acquired based on the target skin electrical resistance signal after the moving average treatment, and the fatigue value of the test target reflects the degree of fatigue of the test target.

According to the method for acquiring the human body fatigue value provided in the embodiment of the present application, the skin electrical resistance signal to be tested is collected, the collected skin electrical resistance signal is subjected to low-pass filtering, and the filtered skin electrical resistance signal is obtained. The obtained skin electrical resistance signal after filtering is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing, and a signal satisfying a predetermined condition is captured from the skin electrical resistance signal after the differential processing. The target skin electrical resistance signal is obtained, the target skin electrical resistance signal is subjected to moving averaging processing, the target skin electrical resistance signal after the moving averaging treatment is obtained, and the target skin electrical resistance signal after the moving averaging treatment is obtained. The resistance value of the test target is acquired, and here, the resistance value of the test target reflects the degree of fatigue of the test target. According to the present application, it is possible to solve the problem that it is difficult to obtain the fatigue value of the test target based on the skin electrical resistance of the test target in the technique. By collecting the skin electrical resistance signal of the test target and then obtaining the fatigue value of the test target through filtering, differentiation processing, acquisition, and moving average processing, the degree of fatigue of the test target can be determined based on the skin electrical resistance of the test target. The effect that can be obtained can be realized.

Alternatively, in the method for acquiring the human body fatigue value provided in the embodiment of the present application, acquiring the fatigue value of the test target based on the target skin electrical resistance signal after the moving average treatment is to obtain the target skin after the moving average treatment. Performing normalization processing on the electrical resistance signal to obtain the target skin electrical resistance signal after normalization, and obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization. Including.

In order to improve the accuracy of acquiring the fatigue value of the test target, in the present technical proposal, the target skin electrical resistance signal after the moving average treatment is normalized to obtain the normalized target skin electrical resistance signal. Obtain the fatigue value of the test target based on the target skin electrical resistance signal after normalization. The normalization process in the present application is limited to a certain range by processing the target skin electrical resistance signal so that the fatigue value data of the test target can be easily acquired later based on the target skin electrical resistance signal. It is to be.

Alternatively, in the method for acquiring the human body fatigue value provided in the embodiment of the present application, after acquiring the fatigue value of the test target based on the target skin electrical resistance signal after normalization, the method is applied to the fatigue value of the test target. It further includes performing the analysis and generating the analysis result of the test object and generating the fatigue value report of the test object based on the analysis result for the fatigue value of the test object.

The fatigue value of the test target is analyzed, a fatigue value report of the test target is generated based on the analysis result, and the fatigue value report can intuitively reflect the fatigue status and physical condition of the test target.

Alternatively, in the method for acquiring the human body fatigue value provided in the embodiment of the present application, it is possible to obtain the target skin electrical resistance signal after the normalization by performing the normalization treatment on the target skin electrical resistance signal after the moving average treatment. It further comprises performing a normalization process on the target skin electrical resistance signal after the moving average treatment using a support vector machine classifier to obtain the target skin electrical resistance signal after the normalization.

The principle of the support vector machine classifier in the embodiment of the present application is shown in FIG. Here, ◯ and □ represent positive and negative samples, respectively, and are as shown by the optimum hyperplane (optimal hyperplane) in FIG. The sample points of the real core in FIG. 2 are the points closest to the hyperplane in the positive and negative samples, and the distance between the two dotted lines in FIG. 2 represents the distance (gap) between the positive and negative samples. The support vector machine maximizes the distance (gap) between the positive and negative samples in the situation where the samples are accurately separated, and the mathematical formula minimize 1/2 || w || ² project to y ⁱ (w ^t x _i + b). It can be expressed by ≧ 1i = 1,2 ... m. The target skin electrical resistance signal after the moving average treatment is normalized by the support vector machine classifier described above to obtain the target skin electrical resistance signal after the normalization.

Alternatively, in the method for obtaining the human body fatigue value provided in the embodiment of the present application, obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization is performed after normalization by the test target fatigue analysis model. The target fatigue value of the test object, which includes acquiring the fatigue value of the test object corresponding to the target skin electrical resistance signal, is a model constructed after training with the fatigue values of a plurality of test objects in advance.

By training in advance with the fatigue values of multiple test targets to build a fatigue analysis model, and acquiring the fatigue values of the test target corresponding to the digital signal of skin electrical resistance based on the test target fatigue analysis model, the test target The efficiency of acquiring the fatigue value of the test object is improved, and the accuracy of acquiring the fatigue value of the test target is also improved.

Alternatively, in the method for acquiring the human body fatigue value provided in the embodiment of the present application, it is possible to obtain the skin electrical resistance signal after the differential processing by performing the differential processing on the filtered skin electrical resistance signal after filtering. Digital-to-analog conversion of the skin electrical resistance signal to obtain the skin electrical resistance digital signal, and differential processing of the skin electrical resistance digital signal to obtain the skin electrical resistance signal after the differential processing. including.

According to the above-mentioned technical proposal, the digital-to-analog conversion of the filtered skin electrical resistance signal is performed to obtain the digital skin electrical resistance signal, and then the digital signal of the skin electrical resistance is differentiated. Obtain the skin electrical resistance signal after differential processing.

Alternatively, in the method for acquiring the human body fatigue value provided in the embodiment of the present application, after acquiring the fatigue value to be tested based on the target skin electrical resistance signal after normalization, the method uses the fatigue value to be tested. To determine whether or not the test target exceeds a predetermined value, and when it is determined that the fatigue value of the test target exceeds a predetermined value, it is determined that the test target is in the fatigue period, and the fatigue value of the test target is determined. Includes determining the fatigue level to which the fatigue level belongs, where fatigue levels include mild fatigue and severe fatigue.

For example, a fatigue level in which the fatigue value is in the range of 60 to 80 is defined as mild fatigue, and a fatigue level in which the fatigue value> 80 is defined as severe fatigue. By determining that the test target is in the fatigue period based on the fatigue value of the test target and determining the fatigue level to which the fatigue value of the test target belongs, the fatigue feeling and physical condition of the test target are more accurately reflected.

It should be noted that the steps shown in the flowchart in the drawing can be executed, for example, in a computer system in which a set of computers can execute instructions, and the flowchart shows the logic order, but in some cases it is shown or shown in a different order. You can perform the steps described.

Further, the human body fatigue value acquisition device is provided in the embodiment of the present application, and the human body fatigue value acquisition device according to the embodiment of the present application can realize the method for acquiring the human body fatigue value provided in the embodiment of the present application. it can. Hereinafter, the device for acquiring the human body fatigue value provided in the embodiment of the present application will be described.

FIG. 3 is a diagram showing a device for acquiring a human body fatigue value according to an embodiment of the present application. As shown in FIG. 3, the apparatus includes a collection unit 10, a filtering unit 20, a first processing unit 30, a second processing unit 40, a third processing unit 50, an acquisition unit 60, and the like. including.

Specifically, the collection unit 10 is installed to collect the skin electrical resistance signal to be tested.

The filtering unit 20 is installed so as to perform low-pass filtering on the collected skin electrical resistance signal to obtain the filtered skin electrical resistance signal.

The first processing unit 30 is installed so as to perform differential processing on the filtered skin electrical resistance signal to obtain the skin electrical resistance signal after the differential processing.

The second processing unit 40 is installed so as to acquire a signal satisfying a predetermined condition from the skin electrical resistance signal after the differential processing and obtain a target skin electrical resistance signal.

The third processing unit 50 is installed so as to perform moving average processing on the target skin electrical resistance signal to obtain the target skin electrical resistance signal after the moving average processing.

The acquisition unit 60 is installed so as to acquire the fatigue value of the test target based on the target skin electrical resistance signal after the moving average treatment, where the fatigue value of the test target reflects the degree of fatigue of the test target.

According to the human body fatigue value acquisition device provided in the embodiment of the present application, the skin electrical resistance signal to be tested is collected by the collecting unit 10, and the skin electrical resistance signal collected by the filtering unit 20 is subjected to low-pass filtering to be filtered. The skin resistance signal after the differential treatment was obtained, and the skin electrical resistance signal after filtering by the first processing unit 30 was subjected to differential processing to obtain the skin electrical resistance signal after the differential treatment, and the second processing unit 40 was obtained. A signal satisfying a predetermined condition is captured from the skin electrical resistance signal after the differential processing, a target skin electrical resistance signal is obtained, and the target skin electrical resistance signal is subjected to mobile averaging processing by the third processing unit 50. By obtaining the target skin electrical resistance signal after the moving average treatment and acquiring the fatigue value of the test target that reflects the degree of fatigue of the test target based on the target skin electrical resistance signal after the moving average treatment by the acquisition unit, In this technology, the problem that it is difficult to obtain the fatigue value of the test target based on the skin electrical resistance of the test target is solved, and after collecting the skin electrical resistance signal of the test target, filtering, differential processing, acquisition, and moving averaging processing are performed. By acquiring the fatigue value of the test target, it is possible to realize the effect that the fatigue level of the test target can be acquired based on the skin electrical resistance of the test target.

The collection unit 10, the filtering unit 20, the first processing unit 30, the second processing unit 40, the third processing unit 50, and the acquisition unit 60 may be executed by the computer terminal as a part of the apparatus. The functions of the above-mentioned means can be realized by the processor in the computer terminal, and the computer terminal is a smartphone (for example, an Android mobile phone, an iOS mobile phone, etc.), a tablet PC, a pocket PC, and a mobile Internet device (Mobile Internet Devices). , MID), PAD and other terminal devices.

Alternatively, in the human body fatigue value acquisition device provided in the embodiment of the present application, the acquisition unit 60 performs normalization processing on the target skin electrical resistance signal after the moving average treatment, and the target skin electrical resistance signal after normalization. Further includes a processing means set up to obtain the fatigue value of the test object based on the normalized target skin electrical resistance signal.

The human body fatigue value acquisition device includes a processor and a memory, and any of the collection unit 10, the filtering unit 20, the first processing unit 30, the second processing unit 40, the third processing unit 50, and the like. Is also stored in the memory as a program unit, and the corresponding function is realized by executing the program unit stored in the memory by the processor.

The processor contains a kernel, which schedules the corresponding program unit from memory. One or more kernels can be provided, and the degree of fatigue of the human body is obtained by adjusting the kernel parameters.

Memory includes formats such as volatile memory in computer readable media, random access memory (RAM) and / or non-volatile memory such as read-only memory (ROM) or flash memory (flash RAM), and memory is at least Includes one storage chip.

In the embodiment of the present invention, a storage medium is provided, a program is stored in the storage medium, and when the program is executed by a processor, the above-mentioned method for acquiring a human body fatigue value is realized.

A processor is provided in an embodiment of the present invention, and the processor executes a program, in which the above-described method for acquiring a human body fatigue value is realized when the program is executed.

Provided in an embodiment of the present invention, the device comprises a processor, a memory, and a program stored in the memory and executed by the processor, and the skin electricity to be tested when the processor executes the program. A step of collecting the resistance signal, a step of performing low-pass filtering on the collected skin electrical resistance signal to obtain the filtered skin electrical resistance signal, and a step of differentiating the filtered skin electrical resistance signal are performed. Move to the step of obtaining the skin electrical resistance signal after the differential treatment, the step of capturing the signal satisfying a predetermined condition from the skin electrical resistance signal after the differential treatment, and obtaining the target skin electrical resistance signal, and the target skin electrical resistance signal. Based on the step of performing averaging and obtaining the target skin electrical resistance signal after moving averaging treatment and the target skin electrical resistance signal after moving averaging, obtain the fatigue value of the test target that reflects the degree of fatigue of the test target. To realize the steps to be taken.

To obtain the fatigue value of the test target based on the target skin electrical resistance signal after the moving average treatment, the target skin electrical resistance signal after the moving average treatment is normalized and the target skin electricity after normalization is performed. Includes obtaining a resistance signal and obtaining a fatigue value under test based on the normalized target skin electrical resistance signal.

After obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization, the method analyzes the fatigue value of the test target and based on the analysis result for the fatigue value of the test target. It further includes generating the analysis result of the test object and generating the fatigue value report of the test object.

To obtain the target skin electrical resistance signal after normalization by normalizing the target skin electrical resistance signal after the moving average treatment, the target skin electrical resistance after the moving average treatment can be obtained using a support vector machine classifier. It further includes subjecting the signal to a normalization process to obtain the normalized target skin electrical resistance signal.

To obtain the skin electrical resistance signal after differential processing by performing differential processing on the filtered skin electrical resistance signal, digital-to-analog conversion is performed on the skin electrical resistance signal after filtering to digitalize the skin electrical resistance. This includes obtaining a signal and subjecting a digital signal of skin electrical resistance to a differential process to obtain a skin electrical resistance signal after the differential process.

Obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization is to obtain the fatigue value of the test target corresponding to the target skin electrical resistance signal after normalization in the test target fatigue analysis model. Here, the test target fatigue analysis model is a model constructed after training with a plurality of test target resistance values in advance.

After obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization, the method determines whether the fatigue value of the test target exceeds a predetermined value and fatigue of the test target. When it is determined that the value exceeds a predetermined value, it further includes determining that the test subject is in a fatigue period and determining the fatigue level to which the fatigue value of the test subject belongs, where fatigue Levels include mild and severe fatigue. The device of the present application can be a server, a PC, a PAD, a mobile phone, or the like.

Further provided in the present application, a computer program product is provided, and when executed in a data processing device, the step of collecting the skin electrical resistance signal to be tested and the low-pass filtering of the collected skin electrical resistance signal are performed after filtering. A step of obtaining a skin electrical resistance signal, a step of differentiating the filtered skin electrical resistance signal to obtain a skin electrical resistance signal after the differential treatment, and a predetermined condition from the skin electrical resistance signal after the differential treatment. A step of capturing a signal to be satisfied to obtain a target skin electrical resistance signal, a step of performing a moving averaging process on the target skin electrical resistance signal to obtain a target skin electrical resistance signal after the moving averaging process, and a step of performing the moving averaging process. Based on the target skin electrical resistance signal, the step of obtaining the fatigue value of the test object, which reflects the degree of fatigue of the test object, is suitable for the execution of the initialized program.

To obtain the fatigue value of the test target based on the target skin electrical resistance signal after the moving average treatment, the target skin electrical resistance signal after the moving average treatment is normalized and the target skin electricity after normalization is performed. Includes obtaining a resistance signal and obtaining a fatigue value under test based on the normalized target skin electrical resistance signal.

After obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization, the method analyzes the fatigue value of the test target and based on the analysis result for the fatigue value of the test target. It includes generating the analysis result of the test target and generating the fatigue value report of the test target.

Performing normalization processing on the target skin electrical resistance signal after moving average processing to obtain the target skin electrical resistance signal after normalization is normal to the target skin electrical resistance signal after moving average processing with a support vector machine classifier. It further includes performing a chemical treatment to obtain a normalized target skin electrical resistance signal.

To obtain the skin electrical resistance signal after differential processing by performing differential processing on the filtered skin electrical resistance signal, digital-to-analog conversion is performed on the skin electrical resistance signal after filtering to digitalize the skin electrical resistance. This includes obtaining a signal and subjecting a digital signal of skin electrical resistance to a differential process to obtain a skin electrical resistance signal after the differential process.

Obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization means that the fatigue value of the test target corresponding to the target skin electrical resistance signal after normalization can be obtained in the test target fatigue analysis model. Including, here, the test target fatigue analysis model is a model constructed after training with a plurality of test target fatigue values in advance.

After obtaining the fatigue value of the test target based on the target skin electrical resistance signal after normalization, the method determines whether the fatigue value of the test target exceeds a predetermined value and fatigue of the test target. When it is determined that the value exceeds a predetermined value, it further includes determining that the test subject is in a fatigue period and determining the fatigue level to which the fatigue value of the test subject belongs, where fatigue Levels include mild and severe fatigue.

Those skilled in the art will appreciate that the embodiments of the present application can be provided as methods, systems or computer program products. Thus, the present application may employ a complete hardware embodiment, a complete software embodiment, or an embodiment in which software and hardware are combined. The present application is a computer program implemented in one or more computer-usable storage media (including, but not limited to, disk drives, CD-ROMs, optical memories, etc.) including computer-usable program code. The form of the product can also be adopted.

The present application has been described with reference to the methods, devices (systems), flow charts and / or block diagrams of computer program products according to the embodiments of the present application. It is understandable that computer program instructions can be used to combine the processes and / or blocks in the flowchart and / or block diagram, and the processes and / or blocks in the flowchart and / or block diagram. Providing these computer programming instructions to a general purpose computer, a dedicated computer, an embedded processor or the processor of another programmable data processor to generate equipment and instructing the processor of the computer or other programmable data processor. By executing the device, one process or a plurality of processes in the flowchart and / or a device that realizes the function specified in one block or a plurality of blocks in the block diagram is generated.

These computer programming instructions can be stored in a computer-readable memory that guides the computer or other programmable data processing device to operate in a particular form, and is stored in the computer-readable memory. A product including an instruction device can be generated in an instruction, and the instruction device realizes a function specified in one process or a plurality of processes in a flowchart and / or a block in a block diagram. To do.

These computer programming instructions can also be loaded into a computer or other programmable data processor to perform a series of operational steps on the computer or other programmable device to cause computer processing. , Thereby, by instructions executed on a computer or other programmable device, realize the function specified for one process or multiple processes in the flowchart and / or one block or multiple blocks in the block diagram. Provide steps to do.

In a typical arrangement, the computing device includes one or more processors (CPUs), an input / output interface, a network interface, and internal memory.

Memory includes formats such as volatile memory in computer readable media, random access memory (RAM) and / or non-volatile memory such as read-only memory (ROM) or flash memory (flash RAM). Memory is an example of a computer-readable medium.

Computer-readable media include non-volatile and volatile, removable and non-removable media, and store information by all methods or techniques. The information includes computer-readable instructions, data structures, program means or other data. Examples of computer storage media include phase change memory (PRAM), static random access memory (SRAM), dynamic random access memory (RAM), other types of random access memory (RAM), and read-only memory (ROM). , Electrically erasable and rewritable read-only memory (EEPROM), flash memory or other memory technology, read-only disc read-only memory (CD-ROM), digital versatile disk (DVD) or other optical storage , But are not limited to those that store information accessible to computers such as magnetic cassette tapes, magnetic tape storage or other magnetic storage devices or any other non-transmission medium. According to the limitations of the present application, computer readable media do not include transient computer readable media (transity media) such as modulated data signals and carriers.

It should be noted that the terms "include", "include" or all of these variants cover non-exclusive inclusion, so that a process, method, product or device containing a series of elements may include those elements. Other than including, it means that it includes other elements that are not explicitly exemplified, or includes other elements that are specific to these processes, methods, products or equipment. Unless further limited, an element limited to "contains one ..." does not preclude the process, method, product or device containing the element from including other identical elements.

Those skilled in the art will appreciate that the embodiments of the present application can be provided as methods, systems or computer program products. Thus, the present application may employ a complete hardware embodiment, a complete software embodiment, or an embodiment in which software and hardware are combined. The present application is a computer program implemented in one or more computer-usable storage media (including, but not limited to, disk drives, CD-ROMs, optical memories, etc.) including computer-usable program code. The form of the product can also be adopted.

The above is merely a preferred embodiment of the present application and does not limit the present application. Those skilled in the art can make various modifications and modifications to the present application. All modifications, equivalent replacements, improvements, etc. within the spirit and principles of the present application are within the scope of the present application.

Claims (10)

Collecting the skin electrical resistance signal to be tested and
Low-pass filtering the collected skin electrical resistance signal to obtain the filtered skin electrical resistance signal.
The skin electrical resistance signal after the filtering is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing.
Obtaining a target skin electrical resistance signal by capturing a signal satisfying a predetermined condition from the skin electrical resistance signal after the differential processing
The target skin electrical resistance signal is subjected to moving average processing to obtain the target skin electrical resistance signal after the moving average treatment.
A method for acquiring a human body fatigue value including acquiring a fatigue value of the test object reflecting the degree of fatigue of the test object based on a target skin electrical resistance signal after the moving average treatment. Obtaining the fatigue value of the test object based on the target skin electrical resistance signal after the moving average treatment is
To obtain the target skin electrical resistance signal after normalization by normalizing the target skin electrical resistance signal after the moving average treatment,
The method according to claim 1, wherein the fatigue value of the test object is obtained based on the target skin electrical resistance signal after normalization. After obtaining the fatigue value of the test object based on the target skin electrical resistance signal after normalization,
Analyzing the fatigue value of the test object and
The method according to claim 2, further comprising generating an analysis result of the test object and generating a fatigue value report of the test object based on the analysis result of the fatigue value of the test object. Performing normalization processing on the target skin electrical resistance signal after the moving average treatment to obtain the target skin electrical resistance signal after normalization is possible.
The method according to claim 2, further comprising performing a normalization treatment on the target skin electrical resistance signal after the moving average treatment using a support vector machine classifier to obtain the target skin electrical resistance signal after the normalization. It is possible to obtain the skin electrical resistance signal after the differential processing by performing the differential processing on the filtered skin electrical resistance signal.
The digital-to-analog conversion of the filtered skin electrical resistance signal is performed to obtain the digital skin electrical resistance signal.
The method according to claim 2, wherein the digital signal of skin electrical resistance is subjected to differential processing to obtain the skin electrical resistance signal after the differential processing. Obtaining the fatigue value of the test object based on the target skin electrical resistance signal after normalization
The fatigue analysis model of the test object includes acquiring the fatigue value of the test object corresponding to the target skin electrical resistance signal after the normalization, wherein the fatigue analysis model of the test object is previously subjected to a plurality of tests. The method according to claim 2, which is a model constructed after training with a target fatigue value. After obtaining the fatigue value of the test object based on the target skin electrical resistance signal after normalization,
Determining whether the fatigue value of the test object exceeds a predetermined value, and
When it is determined that the fatigue value of the test object exceeds a predetermined value, it is determined that the test object is in the fatigue period.
The method of claim 4, further comprising determining a fatigue level, including mild and severe fatigue, to which the fatigue value under test belongs. With a collection unit installed to collect the skin electrical resistance signal under test,
A filtering unit installed so as to perform low-pass filtering on the collected skin electrical resistance signal to obtain the filtered skin electrical resistance signal,
A first processing unit installed so as to obtain the skin electrical resistance signal after the differential processing by performing differential processing on the filtered skin electrical resistance signal, and
A second processing unit installed so as to capture a signal satisfying a predetermined condition from the skin electrical resistance signal after the differential processing and obtain a target skin electrical resistance signal.
A third processing unit installed so as to perform moving average processing on the target skin electrical resistance signal to obtain the target skin electrical resistance signal after the moving average processing, and
A human body fatigue value acquisition device including an acquisition unit installed so as to acquire a fatigue value of the test object that reflects the degree of fatigue of the test object based on a target skin electrical resistance signal after the moving average treatment. A storage medium in which a program for executing the method for acquiring a human body fatigue value according to any one of claims 1 to 7 is stored. A processor that executes a program for executing the method for acquiring a human body fatigue value according to any one of claims 1 to 7.

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