CN114916935A - Posture analysis auxiliary correction system based on correction process of correction personnel - Google Patents

Posture analysis auxiliary correction system based on correction process of correction personnel Download PDF

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CN114916935A
CN114916935A CN202210849900.8A CN202210849900A CN114916935A CN 114916935 A CN114916935 A CN 114916935A CN 202210849900 A CN202210849900 A CN 202210849900A CN 114916935 A CN114916935 A CN 114916935A
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posture
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CN114916935B (en
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王爱兵
郭曙光
张玉锦
薛会生
周秋阳
孙浩文
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Nanjing Huizhilingjie Information Technology Co ltd
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Abstract

The invention provides an auxiliary correction system for posture analysis based on a correction process of a corrector, and relates to the technical field of correction analysis, wherein the auxiliary correction system comprises a posture information acquisition subsystem and an information analysis subsystem, and the posture information acquisition subsystem is in wireless communication connection with the information analysis subsystem; the posture information acquisition subsystem comprises a sign acquisition module, a posture acquisition module and an auxiliary module, and the sign acquisition module is used for acquiring biological sign information of a corrector; the posture acquisition module is used for acquiring posture information of a corrector; the auxiliary module is used for generating stimulation signals and outputting the stimulation signals to the correcting personnel; the information analysis subsystem comprises a sign analysis module, a posture analysis module and a comprehensive analysis module; the method can assist community personnel to monitor and analyze the posture characteristics of the correction personnel, so as to solve the problems that the existing correction process is single in analysis mode and insufficient in correction result evaluation.

Description

Posture analysis auxiliary correction system based on correction personnel correction process
Technical Field
The invention relates to the technical field of correction analysis, in particular to an auxiliary correction system based on posture analysis of a correction person in a correction process.
Background
The concept of 'correction' is introduced into the social field, becomes a specialized term in the judicial field, and means that a state judicial authority and staff can make criminals or illegal persons with crime tendency obtain correction treatment in ideology, psychology and behavior through various measures and means, so that the society is merged again, and becomes a process of normal members in the society.
However, in the prior art, in the process of performing correction on the correction personnel, judgment is usually performed according to the experience of community personnel, but such a correction mode is not simple for a novice person or a person who just performs correction, a lot of misjudgment conditions of body state characteristic details of the correction personnel exist in the correction process, and a certain deviation exists for the presentation of a final correction result, so that a method capable of assisting community personnel in performing body state monitoring analysis on the correction personnel is lacked in the conventional community correction process.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide an auxiliary correction system based on posture analysis of a correction process of a correction person, which can assist community persons to monitor and analyze posture characteristics of the correction person so as to solve the problems that the existing correction process is single in analysis mode and insufficient in estimation of a correction result.
In order to realize the purpose, the invention is realized by the following technical scheme: an auxiliary correction system based on posture analysis of a corrector in a correction process comprises a posture information acquisition subsystem and an information analysis subsystem, wherein the posture information acquisition subsystem is in wireless communication connection with the information analysis subsystem;
the posture information acquisition subsystem comprises a sign acquisition module, a posture acquisition module and an auxiliary module, wherein the sign acquisition module is used for acquiring biological sign information of a correcting person; the posture acquisition module is used for acquiring posture information of a corrector; the auxiliary module is used for generating a stimulation signal and outputting the stimulation signal to a correcting person;
the information analysis subsystem comprises a sign analysis module, a posture analysis module and a comprehensive analysis module; the sign analysis module is used for analyzing the acquired sign information; the gesture analysis module is used for analyzing the acquired gesture information; the comprehensive analysis module is used for comprehensively analyzing the analysis results of the sign analysis module and the gesture analysis module.
As a further technical scheme, the physical sign acquisition module comprises a heart rate acquisition unit, a body temperature acquisition unit, a respiratory frequency acquisition unit, a blood pressure acquisition unit and a skin electrical frequency acquisition unit, wherein the heart rate acquisition unit is used for acquiring a heart rate value of a person to be corrected, the body temperature acquisition unit is used for acquiring a body temperature value of the person to be corrected, the respiratory frequency acquisition unit is used for acquiring a respiratory frequency of the person to be corrected, the blood pressure acquisition unit is used for acquiring a blood pressure high value and a blood pressure low value of the person to be corrected, and the skin electrical frequency acquisition unit is used for acquiring a skin electrical frequency of the person to be corrected;
the gesture collection module comprises a step counting unit and a pupil change collection unit, the step counting unit is used for collecting the movement steps of the correction personnel, and the pupil change collection unit is used for collecting pupil change data of the user.
As a further technical solution, the pupil change collecting unit is configured with a pupil change collecting strategy, where the pupil change collecting strategy includes obtaining image data passing through a pupil, obtaining an area of the pupil from the image data, taking a circle which can be covered by the pupil as a reference circle of a pupil range at the minimum, taking a first pupil change time as a change period, obtaining radii of the reference circle at a start point and an end point of the first pupil change time, obtaining a radius change difference of the reference circle, and setting the change difference as a pupil change coefficient.
As a further technical solution, the sign analysis module is configured with a sign information analysis policy, and the sign information analysis policy includes: substituting the heart rate value, the body temperature value, the respiratory frequency, the blood pressure high value and the blood pressure low value into a physical sign basic monitoring formula to obtain a physical sign monitoring coefficient;
when the physical sign monitoring coefficient is larger than or equal to a first basic physical sign threshold value, outputting a stimulation signal through an auxiliary module, and substituting the physical sign monitoring coefficient and the skin electrical frequency before and after the auxiliary module outputs the stimulation signal into a physical sign stimulation monitoring formula to obtain a physical sign stimulation response coefficient;
when the physical sign stimulation response coefficient is larger than or equal to the first physical sign stimulation response threshold, outputting a high-correction physical sign stimulation signal; when the physical sign stimulation response coefficient is greater than or equal to the second physical sign stimulation response threshold and is smaller than the first physical sign stimulation response threshold, outputting a middle correction physical sign stimulation signal; and when the physical sign stimulation response coefficient is smaller than a second physical sign stimulation response threshold value, outputting a low correction physical sign stimulation signal.
As a further technical solution, the basic physical sign monitoring formula is configured as:
Figure 440812DEST_PATH_IMAGE001
(ii) a The vital signs stimulation monitoring formula is configured to:
Figure 470560DEST_PATH_IMAGE002
(ii) a Wherein Xtz is a physical sign monitoring coefficient, Lx is a heart rate value, L1 is a heart rate reference value, Tw is a body temperature value, and T1 isThe body temperature reference value Wh is respiratory frequency, W1 is respiratory frequency reference value, Pg is blood pressure high value, Pd is blood pressure low value, P1 is blood pressure comprehensive reference value, a1 is heart rate ratio coefficient, a2 is body temperature ratio coefficient, a3 is respiratory ratio coefficient, a4 is blood pressure ratio coefficient, Xtc is sign stimulation response coefficient, Xtz1 and Xtz2 are sign monitoring coefficients before and after the auxiliary module outputs stimulation signals respectively, and Pp1 and Pp2 are skin electrical frequency before and after the auxiliary module outputs stimulation signals respectively.
As a further technical solution, the attitude analysis module is configured with an attitude information analysis policy, and the attitude information analysis policy includes: substituting the motion steps into a basic attitude formula to obtain a basic attitude coefficient;
when the basic posture coefficient is larger than a first basic posture threshold value, outputting a stimulation signal through an auxiliary module, and substituting pupil change coefficients before and after the auxiliary module outputs the stimulation signal into a posture stimulation monitoring formula to obtain a posture stimulation response coefficient, wherein the stimulation signal comprises one or more of sound stimulation, flash stimulation and heating stimulation;
when the posture stimulation response coefficient is larger than or equal to the first posture stimulation response threshold value, outputting a high-correction posture stimulation signal; when the posture stimulation response coefficient is larger than or equal to the second posture stimulation response threshold and smaller than the first posture stimulation response threshold, outputting a middle correction posture stimulation signal; and when the posture stimulation response coefficient is smaller than the second posture stimulation response threshold value, outputting a low correction posture stimulation signal.
As a further technical solution, the basic posture formula is configured as:
Figure 326521DEST_PATH_IMAGE003
(ii) a The postural stimulus monitoring formula is configured as:
Figure 634005DEST_PATH_IMAGE004
(ii) a Wherein Xzt is the basic posture coefficient, Bs is the exercise step number, B1 is the reference value of the exercise step number, B1 is the conversion coefficient of the exercise step number, Xzc is the posture stimulation response coefficient, and Kt1 and Kt2 are the auxiliary components respectivelyThe module outputs pupil change coefficients before and after the stimulus signal.
As a further technical solution, the comprehensive analysis module is configured with a comprehensive analysis policy, and the comprehensive analysis policy includes: acquiring a physical sign stimulation response coefficient, a basic attitude coefficient and an attitude stimulation response coefficient once every first comprehensive monitoring time, and substituting the acquired physical sign stimulation response coefficients, basic attitude coefficients and attitude stimulation response coefficients of the first comprehensive monitoring number into a comprehensive monitoring formula to obtain a comprehensive correction coefficient;
when the comprehensive correction coefficient is larger than or equal to the first comprehensive correction threshold value, outputting a comprehensive high correction signal; when the comprehensive correction coefficient is greater than or equal to the second comprehensive correction threshold and smaller than the first comprehensive correction threshold, outputting a comprehensive middle correction signal; and outputting a comprehensive low correction signal when the comprehensive correction coefficient is smaller than the second comprehensive correction threshold value.
As a further technical solution, the integrated monitoring formula is configured as:
Figure 462284DEST_PATH_IMAGE005
(ii) a Wherein Xtc1 to Xtcn are respectively the sign stimulus response coefficients of the first comprehensive monitoring quantity, Xzt1 to Xztn are respectively the basic attitude coefficients of the first comprehensive monitoring quantity, Xzc1 to Xzcn are respectively the attitude stimulus response coefficients of the first comprehensive monitoring quantity, Xtca is the average number of the sign stimulus response coefficients of the first comprehensive monitoring quantity, Xzta is the average number of the basic attitude coefficients of the first comprehensive monitoring quantity, and Xzca is the average number of the attitude stimulus response coefficients of the first comprehensive monitoring quantity.
The invention has the beneficial effects that: the system can acquire the biological sign information and posture information of a corrector through the posture information acquisition subsystem; the auxiliary module can generate stimulation signals and output the stimulation signals to the correction personnel, the design can monitor physiological conditions of the correction personnel after stimulation is performed, so that the correction conditions of the correction personnel are improved to be evaluated, the collected biological sign information and posture information are analyzed through the information analysis subsystem, and finally, the comprehensive analysis module can comprehensively analyze analysis results of the sign analysis module and the posture analysis module, so that the correction results of the correction personnel are improved to evaluate the comprehensiveness, and the effectiveness and the accuracy of evaluation are improved.
Advantages of additional aspects of the invention will be set forth in part in the description of the embodiments which follows, and in part will be obvious from the description, or may be learned by practice of the invention.
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Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:
FIG. 1 is a functional block diagram of an auxiliary orthotic system according to the present invention;
FIG. 2 is a block diagram of the body state information collection subsystem and the information analysis subsystem of the present invention;
FIG. 3 is a schematic block diagram of a sign acquisition module of the present invention;
FIG. 4 is a gesture collection module of the present invention.
In the figure: 1. an auxiliary orthotic system; 11. a body state information acquisition subsystem; 111. a physical sign acquisition module; 1111. a heart rate acquisition unit; 1112. a body temperature acquisition unit; 1113. a respiratory frequency acquisition unit; 1114. a blood pressure acquisition unit; 1115. a skin electrical frequency acquisition unit; 112. an attitude acquisition module; 1121. a pupil change acquisition unit; 1122. a step counting unit; 113. an auxiliary module; 12. an information analysis subsystem; 121. a sign analysis module; 122. an attitude analysis module; 123. and a comprehensive analysis module.
Detailed Description
It is to be understood that the following detailed description is exemplary and is intended to provide further explanation of the invention as claimed. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.
It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the invention.
The embodiments and features of the embodiments of the invention may be combined with each other without conflict.
Example one
Referring to fig. 1 and 2, the invention provides an auxiliary correction system for posture analysis based on a correction process of a correction person, which can assist community persons to monitor and analyze posture characteristics of the correction person, so as to solve the problem that the existing correction process is single in analysis mode and insufficient in estimation of a correction result.
The auxiliary correction system 1 comprises a posture information acquisition subsystem 11 and an information analysis subsystem 12, wherein the posture information acquisition subsystem 11 is in wireless communication connection with the information analysis subsystem 12.
Referring to fig. 3, the posture information collecting subsystem 11 includes a sign collecting module 111, a posture collecting module 112, and an auxiliary module 113, and the auxiliary module 113 is configured to generate a stimulation signal and output the stimulation signal to a correcting person; the sign acquisition module 111 is used for acquiring biological sign information of the correcting personnel; sign collection module 111 includes heart rate collection unit 1111, body temperature collection unit 1112, respiratory frequency collection unit 1113, blood pressure collection unit 1114 and skin electrical frequency collection unit 1115, heart rate collection unit 1111 is used for gathering the heart rate value of correcting the personnel, body temperature collection unit 1112 is used for gathering the body temperature value of correcting the personnel, respiratory frequency collection unit 1113 is used for gathering the respiratory frequency of correcting the personnel, blood pressure collection unit 1114 is used for gathering the blood pressure height value and the blood pressure low value of correcting the personnel, skin electrical frequency collection unit 1115 is used for gathering the skin electrical frequency of correcting the personnel. Under the general condition, the body temperature, the heart rate, the respiratory rate and the blood pressure of personnel can greatly reflect the state of the body, and the physiological characteristics of the correction personnel can be well judged under the correction instruction of community assessment personnel or training personnel by combining the change monitoring of the skin electricity frequency, so that the accuracy of the process assessment of the correction training is greatly improved.
The information analysis subsystem 12 comprises a sign analysis module 121; the sign analysis module 121 is configured to analyze the acquired sign information; the sign analysis module 121 is configured with a sign information analysis strategy, where the sign information analysis strategy includes the following steps:
step S11, substituting the heart rate value, the body temperature value, the respiratory rate, the blood pressure high value and the blood pressure low value into a basic physical sign monitoring formula to obtain a physical sign monitoring coefficient;
in step S11, the vital signs basic monitoring formula is configured as:
Figure 197022DEST_PATH_IMAGE001
(ii) a Xtz is a physical sign monitoring coefficient, Lx is a heart rate value, L1 is a heart rate reference value, a specific L1 setting range is 65-85, Tw is a body temperature value, T1 is a body temperature reference value, a specific T1 setting range is 36.5-37.5, Wh is a respiratory rate, W1 is a respiratory rate reference value, a specific W1 setting range is 12-20/min, Pg is a blood pressure high value, Pd is a blood pressure low value, P1 is a blood pressure comprehensive reference value, a specific P1 reference high and low pressure total value setting, a range is set between 180 and 220, a1 is a heart rate ratio coefficient, a2 is a body temperature ratio coefficient, a3 is a respiratory ratio coefficient, a4 is a blood pressure ratio coefficient, wherein a1, a2, a3 and a4 are respectively set according to the ratio of the change of the correcting person in heart rate, body temperature, body frequency and blood pressure under actual conditions.
Step S12, when the physical sign monitoring coefficient is larger than or equal to the first basic physical sign threshold, the auxiliary module 113 outputs the stimulation signal, and then the physical sign monitoring coefficient and the skin electrical frequency before and after the auxiliary module 113 outputs the stimulation signal are substituted into the physical sign stimulation monitoring formula to obtain the physical sign stimulation response coefficient;
in step S12, the stimulation signal includes one or more of a sound stimulation, a flash stimulation and a warming stimulation, the temperature provided by the warming stimulation is 30-40 degrees celsius, which is not harmful to the human body, and is preferably performed by a combination of the sound stimulation and the flash stimulation, or by a combination of the sound stimulation, the flash stimulation and the warming stimulation, and the vital sign stimulation monitoring formula is configured to:
Figure 743541DEST_PATH_IMAGE002
(ii) a Xtc is the vital signs stimulation response coefficient, Xtz1 and Xtz2 are the vital signs monitoring coefficients before and after the auxiliary module 113 outputs the stimulation signal, respectively, and Pp1 and Pp2 are the electrodermal frequency before and after the auxiliary module 113 outputs the stimulation signal, respectively.
Step S13, when the physical sign stimulation response coefficient is larger than or equal to the first physical sign stimulation response threshold, outputting a high-correction physical sign stimulation signal; when the physical sign stimulation response coefficient is greater than or equal to the second physical sign stimulation response threshold and is smaller than the first physical sign stimulation response threshold, outputting a middle correction physical sign stimulation signal; and when the physical sign stimulation response coefficient is smaller than the second physical sign stimulation response threshold, outputting a low correction physical sign stimulation signal.
In step S13, the response change of the person who corrects the high correction sign stimulation signal is stronger than the response change of the person who corrects the medium correction sign stimulation signal, the response change of the person who corrects the medium correction sign stimulation signal is stronger than the response change of the person who corrects the low correction sign stimulation signal, and the first sign stimulation response threshold is greater than the second sign stimulation response threshold.
Example two
In the second embodiment, the posture information of the correction staff is mainly analyzed, specifically, the posture information collecting subsystem 11 includes a posture collecting module 112 and an auxiliary module 113, and the auxiliary module 113 is configured to generate a stimulation signal and output the stimulation signal to the correction staff.
The posture information acquisition subsystem 11 comprises a posture acquisition module 112 and an auxiliary module 113, wherein the auxiliary module 113 is used for generating stimulation signals and outputting the stimulation signals to correction personnel; the posture acquisition module 112 is used for acquiring posture information of the correction personnel; referring to fig. 4, the posture collecting module 112 includes a step counting unit 1122 and a pupil variation collecting unit 1121, where the step counting unit 1122 is configured to collect the number of moving steps of a person to be corrected, and the pupil variation collecting unit 1121 is configured to collect pupil variation data of a user. The pupil change acquisition unit 1121 is configured with a pupil change acquisition strategy, which includes the following steps:
a step a1 of acquiring image data of a pupil, acquiring an area of the pupil from the image data, and taking a circle which can be covered by the pupil at the minimum as a reference circle of the pupil range;
step A2, taking the first pupil change time as a change period, and obtaining the radius of a reference circle at the start point and the end point of the first pupil change time;
step a3, a radius change difference of the reference circle is obtained, and the change difference is set as a pupil change coefficient.
In steps a1, a2 and A3, in which the number of steps of an orthotic is monitored, the daily activity state of the orthotic can be greatly reflected, so that the amount of exercise of the orthotic can be well estimated.
The information analysis subsystem 12 includes a posture analysis module 122, and the posture analysis module 122 is configured to analyze the acquired posture information; the pose analysis module 122 is configured with a pose information analysis strategy, which includes the following steps:
step S21, substituting the motion steps into a basic attitude formula to obtain a basic attitude coefficient;
in step S21, the base pose formula is configured as:
Figure 854716DEST_PATH_IMAGE003
(ii) a Wherein Xzt is the basic attitude coefficient, Bs is the number of motion steps, B1 is the reference value of the number of motion steps, and B1 is the conversion coefficient of the number of motion steps. Wherein, B1 is set according to the time line of one day, the specific setting range is 3000-10000, and the setting of B1 is larger than zero.
Step S22, when the basic posture coefficient is larger than the first basic posture threshold, the auxiliary module 113 outputs the stimulation signal, and then the pupil variation coefficient before and after the auxiliary module 113 outputs the stimulation signal is substituted into the posture stimulation monitoring formula to obtain the posture stimulation reaction coefficient;
in step S22, the postural stimulus monitoring formula is configured to:
Figure 803081DEST_PATH_IMAGE006
(ii) a Xzc is posture stimulus response coefficient, Kt1 and Kt2 are pupil change coefficients before and after the auxiliary module 113 outputs stimulus signals, wherein the stimulus signals include one or more of sound stimulus, flash stimulus and warming stimulus, the temperature provided by the warming stimulus is 30-40 ℃, which will not harm human body, preferably adopts two combined stimulus modes of sound stimulus and flash stimulus, or three combined modes of sound stimulus, flash stimulus and warming stimulus;
step S23, when the posture stimulation response coefficient is larger than or equal to the first posture stimulation response threshold value, outputting a high-correction posture stimulation signal; when the posture stimulation response coefficient is greater than or equal to the second posture stimulation response threshold and smaller than the first posture stimulation response threshold, outputting a middle correction posture stimulation signal; and when the posture stimulation response coefficient is smaller than the second posture stimulation response threshold value, outputting a low correction posture stimulation signal.
In step S23, the first posture stimulus response threshold is greater than the second posture stimulus response threshold, the posture response change of the person who corrects the high posture stimulus signal is stronger than the posture response change of the person who corrects the medium posture stimulus signal, and the posture response change of the person who corrects the medium posture stimulus signal is stronger than the posture response change of the person who corrects the low posture stimulus signal.
EXAMPLE III
The third embodiment provides a method for comprehensively analyzing the analysis results of the first embodiment and the second embodiment, and the specific technical scheme is as follows: the information analysis subsystem 12 includes an integrated analysis module 123, and the integrated analysis module 123 is configured to perform comprehensive analysis on the analysis results of the sign analysis module 121 and the posture analysis module 122. The comprehensive analysis module 123 is configured with a comprehensive analysis strategy, and the comprehensive analysis strategy includes the following steps:
step S31, acquiring the physical sign stimulation response coefficient, the basic posture coefficient and the posture stimulation response coefficient once every first comprehensive monitoring time, and substituting the acquired physical sign stimulation response coefficients, the basic posture coefficients and the posture stimulation response coefficients of the first comprehensive monitoring quantity into a comprehensive monitoring formula to obtain a comprehensive correction coefficient;
in step S31, the integrated monitoring formula is configured to:
Figure 971369DEST_PATH_IMAGE005
(ii) a Wherein Xtc1 to Xtcn are respectively the sign stimulation response coefficients of the first comprehensive monitoring number, Xzt1 to Xztn are respectively the basic posture coefficients of the first comprehensive monitoring number, Xzc1 to Xzcn are respectively the posture stimulation response coefficients of the first comprehensive monitoring number, Xtca is the average number of the sign stimulation response coefficients of the first comprehensive monitoring number, Xzta is the average number of the basic posture coefficients of the first comprehensive monitoring number, and Xzca is the average number of the posture stimulation response coefficients of the first comprehensive monitoring number; the stimulation signals comprise one or more of sound stimulation, flash stimulation and warming stimulation, the temperature provided by the warming stimulation is 30-40 ℃, and no harm is caused to a human body, and preferably, a stimulation mode combining the sound stimulation and the flash stimulation or a mode combining the sound stimulation, the flash stimulation and the warming stimulation is adopted;
step S32, when the comprehensive correction coefficient is larger than or equal to the first comprehensive correction threshold value, outputting a comprehensive high-correction signal; when the comprehensive correction coefficient is greater than or equal to the second comprehensive correction threshold and smaller than the first comprehensive correction threshold, outputting a comprehensive middle correction signal; and when the comprehensive correction coefficient is smaller than the second comprehensive correction threshold value, outputting a comprehensive low correction signal.
In step S32, the first comprehensive correction threshold is greater than the second comprehensive correction threshold, the response change of the person who corrects the high comprehensive correction signal is stronger than the response change of the person who corrects the medium comprehensive correction signal, and the response change of the person who corrects the medium comprehensive correction signal is stronger than the response change of the person who corrects the low comprehensive correction signal.
The working principle is as follows: firstly, biological sign information and posture information of a corrector can be acquired through the posture information acquisition subsystem 11; and the auxiliary module 113 can generate stimulation signals and output the stimulation signals to the correctors, so that the physiological conditions of the correctors after stimulation can be monitored, the information analysis subsystem 12 can analyze the collected biological sign information and posture information, and the comprehensive analysis module 123 can comprehensively analyze the analysis results of the sign analysis module 121 and the posture analysis module 122, so that the comprehensiveness of the correction results of the correctors can be evaluated.
Those skilled in the art will appreciate that the modules or steps of the present invention described above can be implemented using general purpose computer means, or alternatively, they can be implemented using program code that is executable by computing means, such that they are stored in memory means for execution by the computing means, or they are separately fabricated into individual integrated circuit modules, or multiple modules or steps of them are fabricated into a single integrated circuit module. The present invention is not limited to any specific combination of hardware and software.
Although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that the following descriptions are only illustrative and not restrictive, and that the scope of the present invention is not limited to the above embodiments: any person skilled in the art can modify or easily conceive the technical solutions described in the foregoing embodiments or equivalent substitutes for some technical features within the technical scope of the present disclosure; such modifications, changes or substitutions do not depart from the spirit and scope of the embodiments of the present invention, and they should be construed as being included therein. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (9)

1. An auxiliary correction system based on posture analysis of a correction process of a correction person is characterized in that the auxiliary correction system (1) comprises a posture information acquisition subsystem (11) and an information analysis subsystem (12), wherein the posture information acquisition subsystem (11) is in wireless communication connection with the information analysis subsystem (12);
the posture information acquisition subsystem (11) comprises a physical sign acquisition module (111), a posture acquisition module (112) and an auxiliary module (113), wherein the physical sign acquisition module (111) is used for acquiring biological physical sign information of a correction person; the posture acquisition module (112) is used for acquiring posture information of a correcting person; the auxiliary module (113) is used for generating a stimulation signal and outputting the stimulation signal to a correcting person;
the information analysis subsystem (12) comprises a sign analysis module (121), a posture analysis module (122) and a comprehensive analysis module (123); the sign analysis module (121) is used for analyzing the acquired sign information; the gesture analysis module (122) is used for analyzing the acquired gesture information; the comprehensive analysis module (123) is used for comprehensively analyzing the analysis results of the sign analysis module (121) and the posture analysis module (122);
the gesture acquisition module (112) comprises a pupil change acquisition unit (1121), and the pupil change acquisition unit (1121) is used for acquiring pupil change data of a user; the pupil change acquisition unit (1121) is configured with a pupil change acquisition strategy, wherein the pupil change acquisition strategy comprises the steps of acquiring image data passing through a pupil, acquiring the area of the pupil from the image data, taking a circle which can be covered by the pupil at the minimum as a reference circle of the pupil range, taking first pupil change time as a change period, acquiring the radiuses of the reference circles of a starting point and an ending point of the first pupil change time, acquiring a radius change difference value of the reference circle, and setting the change difference value as a pupil change coefficient.
2. The system for assisting in correcting body posture analysis based on a correcting process of a person according to claim 1, wherein the sign collecting module (111) comprises a heart rate collecting unit (1111), a body temperature collecting unit (1112), a breathing frequency collecting unit (1113), a blood pressure collecting unit (1114) and a skin electrical frequency collecting unit (1115), the heart rate collecting unit (1111) is used for collecting a heart rate value of the person to be corrected, the body temperature collecting unit (1112) is used for collecting a body temperature value of the person to be corrected, the breathing frequency collecting unit (1113) is used for collecting a breathing frequency of the person to be corrected, the blood pressure collecting unit (1114) is used for collecting a blood pressure high value and a blood pressure low value of the person to be corrected, and the skin electrical frequency collecting unit (1115) is used for collecting a skin electrical frequency of the person to be corrected.
3. An auxiliary orthotic system based on analysis of posture of an orthotic device as claimed in claim 1, wherein the posture-acquisition module (112) comprises a step-counting unit (1122), the step-counting unit (1122) being configured to acquire the number of steps taken by the orthotic device.
4. An auxiliary orthotic system based on analysis of posture of an orthotic device as claimed in any one of claims 2 or 3, wherein the vital signs analysis module (121) is configured with a vital signs information analysis strategy comprising: substituting the heart rate value, the body temperature value, the respiratory frequency, the blood pressure high value and the blood pressure low value into a physical sign basic monitoring formula to obtain a physical sign monitoring coefficient;
when the physical sign monitoring coefficient is larger than or equal to a first basic physical sign threshold value, outputting a stimulation signal through an auxiliary module (113), and then substituting the physical sign monitoring coefficient and the skin electrical frequency before and after the auxiliary module (113) outputs the stimulation signal into a physical sign stimulation monitoring formula to obtain a physical sign stimulation reaction coefficient, wherein the stimulation signal comprises one or more of sound stimulation, flash stimulation and warming stimulation;
when the physical sign stimulation response coefficient is larger than or equal to the first physical sign stimulation response threshold, outputting a high-correction physical sign stimulation signal; when the physical sign stimulation response coefficient is greater than or equal to the second physical sign stimulation response threshold and is smaller than the first physical sign stimulation response threshold, outputting a middle correction physical sign stimulation signal; and when the physical sign stimulation response coefficient is smaller than a second physical sign stimulation response threshold value, outputting a low correction physical sign stimulation signal.
5. Auxiliary orthotic based on postural analysis of orthotic personnel orthotic process according to claim 4A positive system, wherein the vital signs basic monitoring formula is configured to:
Figure 31475DEST_PATH_IMAGE001
(ii) a The vital signs stimulation monitoring formula is configured to:
Figure 946342DEST_PATH_IMAGE002
(ii) a Xtz is a sign monitoring coefficient, Lx is a heart rate value, L1 is a heart rate reference value, Tw is a body temperature value, T1 is a body temperature reference value, Wh is a respiratory frequency, W1 is a respiratory frequency reference value, Pg is a blood pressure high value, Pd is a blood pressure low value, P1 is a blood pressure comprehensive reference value, a1 is a heart rate ratio coefficient, a2 is a body temperature ratio coefficient, a3 is a respiratory ratio coefficient, a4 is a blood pressure ratio coefficient, Xtc is a sign stimulation response coefficient, Xtz1 and Xtz2 are sign monitoring coefficients before and after the auxiliary module (113) outputs the stimulation signal, and Pp1 and Pp2 are skin electrical frequencies before and after the auxiliary module (113) outputs the stimulation signal.
6. An auxiliary orthotic system based on postural analysis of an orthotic personnel orthotic process according to claim 5, wherein the posture analysis module (122) is configured with a posture information analysis strategy comprising: substituting the motion steps into a basic attitude formula to obtain a basic attitude coefficient;
when the basic posture coefficient is larger than a first basic posture threshold value, outputting a stimulation signal through the auxiliary module (113), and substituting pupil change coefficients before and after the auxiliary module (113) outputs the stimulation signal into a posture stimulation monitoring formula to obtain a posture stimulation response coefficient;
when the posture stimulation response coefficient is larger than or equal to the first posture stimulation response threshold value, outputting a high-correction posture stimulation signal; when the posture stimulation response coefficient is larger than or equal to the second posture stimulation response threshold and smaller than the first posture stimulation response threshold, outputting a middle correction posture stimulation signal; and outputting a low correction posture stimulation signal when the posture stimulation response coefficient is smaller than the second posture stimulation response threshold.
7. An auxiliary orthotic system according to claim 6, wherein the base posture formula is configured to:
Figure 483633DEST_PATH_IMAGE003
(ii) a The postural stimulus monitoring formula is configured as:
Figure 560174DEST_PATH_IMAGE004
(ii) a Wherein Xzt is a basic posture coefficient, Bs is a motion step number, B1 is a motion step number reference value, B1 is a motion step number conversion coefficient, Xzc is a posture stimulus response coefficient, and Kt1 and Kt2 are pupil change coefficients before and after the auxiliary module (113) outputs the stimulus signal, respectively.
8. An auxiliary orthotic system based on postural analysis of an orthotic personnel orthotic process according to claim 7, wherein said comprehensive analysis module (123) is configured with a comprehensive analysis strategy comprising: acquiring the physical sign stimulation response coefficient, the basic attitude coefficient and the attitude stimulation response coefficient once every first comprehensive monitoring time, and substituting the acquired physical sign stimulation response coefficients, the basic attitude coefficient and the attitude stimulation response coefficients of the first comprehensive monitoring number into a comprehensive monitoring formula to obtain a comprehensive correction coefficient;
when the comprehensive correction coefficient is larger than or equal to the first comprehensive correction threshold value, outputting a comprehensive high correction signal; when the comprehensive correction coefficient is greater than or equal to the second comprehensive correction threshold and smaller than the first comprehensive correction threshold, outputting a comprehensive middle correction signal; and outputting a comprehensive low correction signal when the comprehensive correction coefficient is smaller than the second comprehensive correction threshold value.
9. An auxiliary orthotic system according to claim 8, wherein the integrated monitoring formula is configured to:
Figure 484880DEST_PATH_IMAGE005
(ii) a Wherein Xtc1 to Xtcn are the sign stimulation response coefficients of the first comprehensive monitoring number, Xzt1 to Xztn are the basic posture coefficients of the first comprehensive monitoring number, Xzc1 to Xzcn are the posture stimulation response coefficients of the first comprehensive monitoring number, Xtca is the average number of the sign stimulation response coefficients of the first comprehensive monitoring number, Xzta is the average number of the basic posture coefficients of the first comprehensive monitoring number, and Xzca is the average number of the posture stimulation response coefficients of the first comprehensive monitoring number.
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