CN211507131U - Deep squat motion monitoring device - Google Patents

Abstract

The utility model provides a motion monitoring devices squats deeply, including information input ware, display module, user motion information generator and monitoring subassembly, the information output ware is used for the input information, and the display module is used for playing relevant information, and user motion information generator is used for generating user motion information, and the monitoring subassembly is used for monitoring user's motion trail. Compared with the prior art, the scheme can generate the user motion information matched with the user according to the user basic information, the user can monitor whether the motion form of the user accords with the user motion information or not during actual motion, and the display assembly can play related information, so that the fitness quality of the user is effectively improved, and the performance of the deep-squatting motion monitoring device is optimized.

Description

Deep squat motion monitoring device

Technical Field

The utility model belongs to the technical field of body-building apparatus, concretely relates to motion monitoring devices squats deeply.

Background

2016, 10 and 25 days, the compendium for planning "health China 2030" issued by the State Council indicates "shared and healthy people", which is the strategic theme of building healthy China. In 7 months in 2019, the State department issued opinions on the implementation of healthy Chinese actions (hereinafter referred to as opinions), the State department office issued implementation and assessment schemes for healthy Chinese action organizations, and the health Chinese action promotion Committee issued actions in the health China (2019-2030). These three documents are collectively called healthy chinese action-related documents, and can be regarded as construction charts and route charts of healthy chinese strategies and "outline of healthy china 2030".

In the guidance document of healthy Chinese actions (2019-.

According to the survey of the health and fitness activities of the whole population in 2014 of the State general sports administration, the proportion of urban and rural residents in China who often take part in physical exercise is 33.9%, wherein the frequent exercise rate of the residents in 20-69 years is only 14.7%, the frequent exercise rate of adults is at a lower level, and the lack of physical activities becomes an important reason for the occurrence of various chronic diseases. Meanwhile, the change of indexes such as heart-lung endurance, flexibility, muscle strength, muscle endurance and body components is not optimistic, and most residents have great blindness when participating in sports activities. The regular proper physical activity is helpful for preventing and improving overweight, obesity, hypertension, heart disease, apoplexy, diabetes and other chronic diseases, and can promote mental health, improve life quality and happiness, and promote social harmony.

In healthy Chinese activities (2019-2030), the national fitness activity is one of fifteen major activities. Under the national strategic architecture of 'healthy China', the final task which needs to be completed by national fitness is to improve the health level of people and promote people to form a healthy life style, and the formation of sports consciousness is important for improving sports participation degree by referring to international experience. Therefore, the improvement of the consciousness of the national fitness is the first level of the general objective, and in view of the social nature of people, the consciousness is limited by the environment, the change consciousness of the environment, and the current situation of the lack of change consciousness by what means and mode, the creation of the natural environment, the social environment and the market environment of the national fitness is particularly important.

In the prior art, sports equipment is diversified, but the function of the sports equipment in the prior art is single. With the rapid development of network technology, simple sports equipment cannot meet the use requirements of people, and the sports equipment lacks necessary functions and is not favorable for people to insist on sports. For example, the deep-squat exercise is simple in action, basically does not need exercise equipment, and people can exercise instantly, but the action amplitude of the people doing the instant exercise does not always accord with the exercise standard, and in addition, the deep-squat exercise does not need the exercise equipment, so that the people are difficult to persist for a long time.

SUMMERY OF THE UTILITY MODEL

The utility model provides a motion monitoring devices squats deeply has solved the technical problem that people can't independently judge whether the motion accords with the standard when squating deeply among the prior art.

A deep squat exercise monitoring device;

the system comprises an information input device, a data processing device and a data processing device, wherein the information input device is used for inputting basic information of a user, and the basic information of the user at least comprises the age of the user, the sex of the user, the height of the user and the weight of the user;

the user motion information generator generates user motion information according to the user basic information;

the display component is used for playing the standard motion form and the actual motion form of the user;

and the monitoring component is used for monitoring the actual motion form of the user, wherein the actual motion information of the user is calculated if the actual motion form of the user accords with the standard motion form, and the actual motion information of the user is not calculated if the actual motion form of the user does not accord with the standard motion form.

The utility model provides a motion monitoring devices squats deeply, including information input ware, display module, user motion information generator and monitoring subassembly, the information output ware is used for the input information, and the display module is used for playing relevant information, and user motion information generator is used for generating user motion information, and the monitoring subassembly is used for monitoring user's motion trail. Compared with the prior art, the scheme can generate the user motion information matched with the user according to the user basic information, the user can monitor whether the motion form of the user accords with the user motion information or not during actual motion, and the display assembly can play related information, so that the fitness quality of the user is effectively improved, and the performance of the deep-squatting motion monitoring device is optimized.

Preferably, this motion monitoring devices squats deeply still includes the casing, display element set up in on the casing, display element includes the touch-control screen, information input ware integrate in display element be provided with installation space in the casing, monitoring element reaches user's motion information generator all set up in the installation space, wherein, monitoring element with user's motion information generator communication, information input ware display element all with user's motion information generator communication.

This scheme is rational in infrastructure, has reduced the space that motion monitoring devices of squatting deeply took, has optimized motion monitoring devices's of squatting deeply performance.

Preferably, the monitoring assembly comprises a human body motion track scanner, the monitoring assembly is connected to the casing in a sliding mode, a driver for driving the monitoring assembly to reciprocate in the vertical direction is arranged on the casing, a controller for controlling the driver to work is further arranged in the casing, the controller is communicated with the information input device, and the controller controls the driver to work according to the height of a user input by the information input device.

This scheme makes the monitoring subassembly can reciprocate along the casing to can be in different positions according to the user's height of difference, improved the scanning precision of human action orbit scanner, optimized the performance of motion monitoring devices of squatting deeply.

Preferably, the driver includes linear servo motor, linear servo motor includes the output piece, the monitoring subassembly is fixed in on the output piece still be provided with the guide rail on the casing be provided with on the output piece with guide rail complex spout, the guide rail with casing formula structure as an organic whole.

The structure of the driver is simplified, the structure of the deep-squatting motion monitoring device is further simplified, and the deep-squatting motion monitoring device is easy to maintain.

Preferably, the information input device includes a portable intelligent electronic device, the portable intelligent electronic device communicates with the user movement information generator through a network, a graphic code matched with the portable intelligent electronic device is arranged on the display assembly, and an identifier for identifying the graphic code is arranged on the portable electronic device.

The application of the portable intelligent electronic equipment improves the input efficiency of the information input device and optimizes the performance of the deep-squatting motion monitoring device.

Preferably, this motion monitoring devices squats deeply still includes the instruction sign that instructs the user motion region, instruction sign includes the pedal pad be provided with pedal instruction label on the pedal pad, pedal instruction label bond in on the pedal.

The setting of instruction sign is used for instructing the user to stand to the exact position on, and then is favorable to monitoring subassembly monitoring user's motion trail, has optimized the performance of motion monitoring devices of squatting deeply.

Preferably, the step pad is provided with a suction cup for fixing the step pad to a target position, and the suction cup is adhered to the step pad.

The accurate difficult slip of pedal pad location has optimized the performance of motion monitoring devices of squatting deeply.

Preferably, a first position detector is disposed on the housing, and a second position detector is disposed on the step pad, wherein the first position detector is in communication with the second position detector, and the distance between the step pad and the housing is detected by the first position detector and the second position detector.

The device is beneficial to placing the pedal pad, does not need to be measured by a user, and optimizes the operation performance of the deep squatting motion monitoring device.

Preferably, the first position detector includes an LED lamp that is turned on when a distance between the step pad and the housing reaches a set distance.

The performance of the deep squatting motion monitoring device is optimized.

Preferably, the first position detector is fixed to the housing (5) by screws.

The first position detector has good fixing performance.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic view of an application scenario of the present disclosure.

Fig. 2 is a schematic view of another application scenario of the present disclosure.

Fig. 3 is a block diagram of an environment of hardware according to the present disclosure.

Fig. 4 is a schematic diagram of an internal structure of a hardware environment according to the present disclosure.

FIG. 5 is a schematic diagram of an embodiment of the connection between the output block and the housing of the present disclosure.

FIG. 6 is a schematic view of an embodiment of a connection between a display module and a housing according to the present disclosure.

Detailed Description

The present invention will be described in further detail with reference to the following examples, which are illustrative of the present invention and are not intended to limit the present invention.

A deep squat exercise monitoring method comprises the following steps:

acquiring basic information of a user, wherein the basic information of the user at least comprises the sex of the user, the age of the user, the height of the user and the weight of the user;

generating user motion information, wherein the user motion information is generated according to the user basic information;

responding to a user starting motion request to play a standard motion form picture of deep squat motion, and monitoring a user actual motion form according to the standard motion form to generate user actual motion information, wherein the user actual motion information is calculated if the user actual motion form accords with the standard motion form, and the user actual motion information is not calculated if the user motion form does not accord with the standard motion form.

In the present disclosure:

the user basic information comprises the user gender, the user age, the user height and the user weight. The user motion information can be reasonably generated according to the gender and the age of the user, and specifically, the user motion information required by users of different ages and genders is inconsistent.

For example, in the case of the sex of the users, due to the difference of the physiological characteristics, the motion information of the users in the same age group of the male user and the female user is inconsistent, that is, the motion amount requirements of the male user and the female user are inconsistent, and assuming that the motion information of the male user is configured to the female user, the motion amount of the female user may be too large to be good for the health of the female user.

For example, in the case of a male user, the user motion information of a 20-year-old male user is obviously different from that of a 50-year-old male user, and if the motion information of the 20-year-old male user is configured to the 50-year-old male user, the motion amount of the 50-year-old male user may be too large to be good for the health of the 50-year-old male user.

Taking the height and the weight of the user as an example, when the height and the weight of the user are inconsistent in the same age and the same gender, the motion information of the user is inconsistent, and the obtaining of the height and the weight of the user is beneficial to the generation precision of the motion information of the user.

For example, for 20-year-old female users, one of the female users has a height of 170 cm and a weight of 45 kg, and the height and the weight of the female user are within a normal range, so that a healthy body can be obtained without excessive exercise, and the body of the female user may be deteriorated if the female user excessively exercises.

The height of the female user is 160 cm, the weight of the female user is 63 kg, the height and the weight of the female user may not be within a normal range, namely the fat content of the female user may be excessive, and at the moment, the exercise intensity of the female user is properly increased to obtain more reasonable exercise information of the user. At this time, the female user may not be good for his/her physical health if the amount of exercise is too small.

In summary, before generating the user motion information, at least the sex, age, height and weight of the user need to be obtained to generate reasonable user motion information, which is beneficial to the health of the user.

Since the user is not professional, his movement trajectory may not meet the standard movement trajectory, for example, in the case of a deep squat exercise, the standard form of the deep squat exercise is that the user has arm swing motion while squat deeply, i.e., the deep squat exercise requires leg movement and the arm should have a certain movement.

When the user actually moves, the user may neglect the arm movement during the deep squat due to factors such as no knowledge or laziness, and the movement form of the user is unreasonable in practice. That is, exercising under an incorrect motion trajectory may not meet the user's exercise needs and may also cause the user's body to deteriorate.

Therefore, when the user performs the deep squatting exercise, whether the exercise track of the user needs to meet the standard exercise track or not needs to be obtained besides the calculation of the deep squatting times of the user.

In the scheme, the user can play the standard form of the deep squatting movement while performing the deep squatting movement, and the form can be visually observed by the user so as to correct the movement track of the user. Meanwhile, the motion trail of the user is monitored, and when the motion trail of the user is inconsistent with the standard motion trail, the actual motion information of the user is not calculated. That is to say, only the number of deep squat movements of the user according with the standard movement track is calculated, and the scheme can effectively avoid the reduction of the movement quality of the user caused by the error of the movement track of the user.

From the above description, it is obvious that the technical solution of the present disclosure has the following beneficial effects:

the method has the beneficial effects that the user motion information is accurate, the user motion information is generated according to the user basic information, and the user basic information comprises the user gender, the user age, the user height and the user weight. The relationship between the user basic information and the user motion information is described above with reference to the description.

The user motion information is generated according to the age, the sex, the height and the weight of the user, and each user has the user motion information corresponding to the user, so that the body building quality of the user is improved.

Beneficial effect 2, the actual motion information of the user is accurate. The description of the motion trail of the user and the standard motion form refers to the description content above.

According to the scheme, the motion trail of the user is monitored in the motion process of the user, the actual motion trail of the user is compared with the standard motion trail to judge whether the motion form of the user is correct, and only the motion information of the user with the correct trail is calculated to generate the actual motion information of the user.

In the scheme, the actual motion information of the user is the motion with the correct track, so that the body-building quality of the user is improved.

Advantageous effect 3, the user can be prompted for a standard exercise form. The standard motion form picture of the deep squatting motion is played, and the picture can be visually observed by a user, so that the user can conveniently adjust the motion track of the user according to the motion form on the picture, the accuracy of the motion track of the user during body building is improved, and the body building quality of the user is improved.

The generating user motion information comprises:

generating the total times of deep squatting movements according to the basic information of the user, wherein the total times of the deep squatting movements are obtained through the following formula:

f=u*g*h/t*n；

wherein, f: taking an integer by adopting an advanced method for the total squatting times;

u: gender, wherein female is 1, male is 1.1 to 1.3;

g: age, the age interval being 20 to 50 years old;

h: height in centimeters;

t: body weight in kilograms; wherein, when the weight is squat deeply, t: weight plus weight, weight unit is kilogram;

n: the motion coefficient is 0.3 to 0.8, wherein the motion coefficient is smaller when the age is larger, and the motion coefficient is larger when the age is smaller;

obtaining a deep squatting group according to the total deep squatting times, wherein the deep squatting group is obtained by dividing the total deep squatting times by 10 and taking an integer by adopting an one-in-one method;

and acquiring the time interval between two adjacent groups of deep squatting movements according to the deep squatting group, wherein the time interval is the deep squatting group divided by 2 and rounded to obtain an integer, and the unit of the time interval is minutes.

The technical scheme in the embodiment is particularly suitable for users aged from 20 to 50. The motion coefficient determination method in this embodiment corresponds to the actual age of the user, and for example, the motion coefficient is smaller with a larger age, and the number of motions is larger with a smaller age.

Specifically, since the quality of the body-related function is more deteriorated with age, and at this time, the body function may be damaged by an excessive exercise amount, the exercise coefficient should be smaller with age.

A possible selection scheme of the motion coefficients is that 30 age values exist between 20 years old and 50 years old, at the moment, 30 motion values are selected between 0.3 and 0.8 of the motion numbers, and the motion coefficients of different ages are obtained through one-to-one correspondence of the age values and the motion values.

The magnitude of the motion coefficient has certain influence on the total times of deep squatting, and the total times of deep squatting has certain relation with the motion information of the user.

In order to meet the personalized requirements of the user, the motion coefficient can be input by the user.

For example, after obtaining the basic information of the user, the recommended motion coefficient interval value is presented to the user, and at this time, the user can freely input in the interval. The recommendation for the motion coefficient interval value is still between 0.3 and 0.8, wherein the motion coefficient is smaller the larger the age.

In the scheme, the deep-squatting groups and the time intervals among the groups influence the exercise amount of the single-group exercise, for example, the more the deep-squatting groups are, the shorter the time intervals in the two adjacent groups of deep-squatting groups are, the larger the exercise is, and the larger the age is, the smaller the exercise amount is in consideration of the relationship between the functions and the age of the human body.

The total number of squats, the number of groups and the time interval have certain influence on the amount of exercise. The group times and time intervals are not suitable for being acquired by other methods.

The obtaining mode of the deep squatting group is as follows: the squat group is the total squat times divided by 10, where the constant 10 represents the amount of movement for each group of squat movements, i.e. each group needs to make 10 squat movements.

Specifically, each group of 10 deep squat exercises has reasonable amount of exercise, and excessive deep squat exercises cause excessive amount of exercise of the user, which may cause damage to the user during the exercise. And if too little deep squat exercise is performed in each group, reasonable exercise amount cannot be achieved, which is not beneficial to body building of users.

Considering that when a user moves specifically, part of the motion trail may not conform to the standard motion form, so that the actual motion information of the user cannot be included.

The time interval between the adjacent two sets of squat movements has a certain influence on the user's quantity of motion, and for this reason, the time interval between the adjacent two sets of squat movements is acquired according to the squat group number, wherein the time interval is the squat group number divided by 2 and rounded up by a whole number.

Specifically, when the squat exercise was 7 groups, the time interval between two adjacent squat exercises was 4 minutes. In the scheme, the time interval between two adjacent groups of deep squatting exercises is associated with the group times of the deep squatting exercises, and the time interval has higher rationality and is favorable for the body building of a user.

In a possible hardware environment, the user motion information is generated by a user motion information generator 2, the user motion information generator 2 has a logic operation capability and a data storage capability, the logic operation capability can be realized by a central processing unit, the data storage capability can adopt a data storage device, the data storage device is communicated with the central processing unit, the acquired user basic information is stored in the data storage device, the central processing unit adjusts the user basic information in the data storage device, and an operation function for calculating the user motion information is also stored in the data storage device.

Specifically, a user inputs basic user information into a data memory in any mode, the data memory temporarily stores the basic user information, then a central processing unit calls an operation function and the basic user information in the data memory, the basic user information is assigned to the operation function, and after the operation function is assigned, the operation function is calculated to obtain the user motion information.

The responding to the user starting motion request to play the standard motion form picture of the deep squatting motion, and the monitoring the user actual motion form according to the standard motion form to generate the user actual motion information comprises the following steps:

scanning a user motion track after responding to a user motion starting request, comparing the user motion track with a standard motion form, and acquiring whether the actual motion form of the user meets the requirement;

and prompting the time interval between the squat groups of the user by using sound according to the motion track of the user.

Specifically, when the user performs the normal squat exercise, the trajectory of the user in the height direction and the trajectory of the user in the horizontal direction are changed, the trajectory in the height direction is the action of the user from standing to deep squat, the parameters of the user in the height direction are continuously changed in the process of completing the action, and the movement trajectory of the user in the height direction can be obtained through the change. The movement track of the user in the horizontal direction means that the user needs to perform related movements such as combination, opening and the like on both arms in the process of completing the actions from standing to deep squatting, in the process, the track of the user in the horizontal direction is also changed, and whether the movement form of the user meets the requirements or not can be obtained by acquiring the movement track of the user in the height direction and the movement track of the user in the horizontal direction and then comparing the movement track of the user in the height direction and the movement track of the user in the horizontal direction with the standard movement form.

In one possible hardware environment, a radar detector or a scanner with trajectory scanning capability may be employed to obtain the actual trajectory of the user's motion. The radar detector may employ active radar or passive radar.

In combination with one possible specific application example of the present solution, the application example is only exemplary and is not a limitation on the present solution.

In response to the user motion starting request, the user motion starting request may be triggered by touch, by sound, by body motion of the user, or possibly by a portable electronic device. The triggering mode of the user starting the exercise request is not limited and can be freely selected.

Scanning a user motion track in the process of carrying out deep squatting motion, specifically, scanning the user motion track by adopting a real-time scanning mode until one or a group of deep squatting motions are finished, wherein the user motion track comprises a track in the height direction and a track in the horizontal direction.

The scanning of the motion trail of the user is mainly used for acquiring whether the actual motion form of the user accords with the standard motion form. The judging method can be as follows: the height of the user during standing is obtained by the height of the user, the possible width of the user in the horizontal direction during standing is obtained according to the weight of the user, a group of height values and width values are obtained at the moment, the height values and the width values are stored in a data storage, the user needs to squat deeply and stretch arms during deep squat movement, the height of the user is changed greatly during deep squat, and the width direction of the user is changed greatly after the arms are stretched during deep squat movement.

When the user actually moves, the parameters in the height direction and the width direction of the user can be greatly changed, and the change range is at least about 1 meter, so that whether the movement form of the user accords with the standard movement form or not can be conveniently judged through scanning.

The trace variation in the height direction and the horizontal direction of the user is large in the deep squatting movement process, and whether the actual movement form of the user meets the standard movement form or not can be effectively determined without too high scanning precision.

In a possible hardware environment, the timer is used for calculating the time interval of two adjacent groups of deep-squatting exercises, specifically, after each group of deep-squatting exercises are completed, the timer can time, and after the time counted by the timer reaches the time interval, the timer can send out a sound through the sound generator to prompt the user to carry out the next group of deep-squatting exercises.

The sound generator and the timer can be communicated with the central processing unit, and the central processing unit carries out relevant logic movement and sends out corresponding control signals.

According to the scheme, the actual motion trail of the user is obtained in a scanning mode, and the accuracy of the actual motion trail of the user obtained by the scheme is favorable for calculating the actual motion information of the user, so that the fitness quality of the user is improved.

As shown in fig. 1 and 3, a deep squat exercise monitoring device;

the device comprises an information input device 1, a data processing device and a data processing device, wherein the information input device is used for inputting basic information of a user, and the basic information of the user at least comprises the age of the user, the sex of the user, the height of the user and the weight of the user;

the user motion information generator 2 generates user motion information according to the user basic information;

the display component 3 is used for playing a standard motion form and a user actual motion form;

and the monitoring component 4 is used for monitoring the actual motion form of the user, wherein the actual motion information of the user is calculated if the actual motion form of the user accords with the standard motion form, and the actual motion information of the user is not calculated if the actual motion form of the user does not accord with the standard motion form.

In this embodiment, the operation process of the squat exercise monitoring device can be described as above, and is not described herein again. The scheme introduces a possible hardware device for realizing the deep-squatting motion monitoring method from the hardware perspective.

Specifically, the information input device 1 inputs the corresponding user basic information to the user movement information generator 2, and after the basic information is acquired by the user movement information generator 2, the user movement information generator 2 assigns the corresponding user basic information to the user movement information acquisition function, which has been described in detail above. The user motion information generator 2 generates user motion information.

When the user performs actual movement, the user initiates a movement starting request, at this time, the display component 3 plays a standard movement form, and meanwhile, the display component 3 can also play the user actual movement form at the same time for the user to refer to. The monitoring component 4 monitors the user's movement pattern.

According to the scheme, the user motion information can be generated according to the basic information of the user, the user motion information matched with the user is obtained, then the user exercises according to the information, and the irregular motion form of the user can be monitored under the action of the monitoring component 4, so that the exercise quality of the user is improved, and the performance of the squat motion monitoring device is optimized.

In one possible hardware configuration, the user motion information generator 2 may include a central processing unit, a data storage, a data comparator, and other elements, wherein the data storage and the data comparator are both in communication with the central processing unit, the data storage stores necessary functions for calculating user motion information, corresponding assignment codes, video files in standard motion forms, and the like, the information input unit 1 inputs corresponding user basic information to the data storage, and the central processing unit calls related motion functions in the data storage to obtain the user motion information. Then, after receiving the request of starting the exercise from the user, the central processing unit controls the display component 3 to play the standard exercise form, and after the user starts the exercise, the monitoring component 4 scans the actual exercise form of the user, and meanwhile, the actual exercise form of the user can also be displayed on the display component 3.

The monitoring component 4 scans the actual motion form of the user and then temporarily stores the relevant data in the data memory, the central processing unit calls the relevant information in the data memory, and meanwhile, the central processing unit controls the data comparator to compare whether the actual motion form of the user is matched with the standard motion form, so that whether the actual motion information of the user meets the requirement is determined. For a comparison method of the comparator, please refer to the above description, which is not repeated herein.

As shown in fig. 1, fig. 3, and fig. 4, a possible embodiment of the device for monitoring deep squat exercise further includes a housing 5, the display component 3 is disposed on the housing 5, the display component 3 includes a touch screen, the information input device 1 is integrated with the display component 3, an installation space 501 is disposed in the housing 5, the monitoring component 4 and the user exercise information generator 2 are disposed in the installation space 501, wherein the monitoring component 4 communicates with the user exercise information generator 2, and the information input device 1 and the display component 3 communicate with the user exercise information generator 2.

The casing 5 can be made of metal materials, the casing 5 can also be made of other materials, and the casing 5 has the characteristics of light weight and low price so as to reduce the production cost of the deep squatting motion monitoring device.

The housing 5 may be formed in a spliced manner to facilitate maintenance of the squat motion monitoring apparatus. In this scheme, a possible optimization mode can be further provided, wherein a base can be arranged at the bottom of the housing 5, so that the stability of the housing 5 is improved, and the stability of the deep-squatting motion monitoring device is improved.

The base can with 5 formula structures as an organic whole of casing, the base also can be connected with casing 5 through releasable connection mode, can set up the balancing weight in the base, this balancing weight can be the stone, the balancing weight also can be other materials, the concrete material of balancing weight does not do the injecing, technical staff in the field can rationally select as required.

The display component 3 includes a touch screen, which is only one possible solution, for example, the touch screen may also be replaced by a gesture control screen, and the specific solution is not limited, but the display and control capability is retained, so as to simplify the structure of the squat exercise monitoring device.

In one possible embodiment, the information input 1 and the display component 3 may be integrated. That is, when the display unit 3 is a touch panel, the display unit 3 has an information input capability, and accordingly, a virtual keyboard or the like can be displayed on the display unit 3. The user can enter information directly through the display assembly 3, for example by clicking or sliding. The display module 3 for realizing the function is a conventional structure in the prior art, and can be obtained by purchase, and the specific structure thereof is not described in detail herein.

As shown in fig. 6, a mounting window 308 for mounting the display module 3 is correspondingly disposed on the housing 5, and the mounting window 308 should prevent the display module 3 from protruding out of the outer surface of the housing 5, that is, the display module 3 should not protrude out of the housing 5 after being mounted on the housing 5, so as to prevent the display module 3 from being damaged by collision and prolong the service life of the housing 5.

In a possible scheme, the display module 3 may be fixed on the casing 5 by screws, a buffer 307 may be further disposed between the display module 3 and the casing 5, the buffer 307 may generate a certain elastic deformation capability, the buffer 307 may be adhered to the casing 5, and the buffer 307 may also be adhered to the display module 3, so as to facilitate the assembly of the display module 3.

Wherein, the mounting window 308 on the housing 5 may have a concave filtering feature, and the concave transition feature may be formed by stamping, and the concave filtering feature is mainly used to recess the display component 3 into the housing 5, so as to further prevent the display component 3 from being damaged by collision, and further prolong the service life of the display component 3.

In one possible embodiment, the housing 5 is formed by splicing plates, the plates can be fixed together by screws, the plates can also be fixed together by bolts, and the mounting space 501 is used for mounting the user movement information generator 2 and the monitoring component 4, wherein the monitoring component 4 can communicate with the user movement information generator 2 to enable the user movement information generator 2 to communicate with the monitoring component 4.

Wherein, can set up support body 203 in installation space 501, this support body 203 mainly used installs user motion information generator 2, and user motion information generator 2 contains more electronic component, and relevant electronic component can produce a large amount of heat energy at the during operation, and this heat energy should be distributed away in time to the life of extension user motion information generator 2.

The frame body 203 is adopted to fix the user movement information generator 2, so that the contact area between the user movement information generator 2 and the air is increased, the heat exchange area between the user movement information generator 2 and the air is further increased, the heat dissipation efficiency of the user movement information generator 2 is improved, and the service life of the user movement information generator 2 is prolonged.

The rack 203 may be fixed to the inside of the casing 5 by screws, the rack 203 may also be welded to the inside of the casing 5, and the fixing manner between the rack 203 and the casing 5 is not limited and may be freely selected.

The user motion information generator 2 and the frame body 203 can be connected through screws, the user motion information generator 2 and the frame body 203 can also be connected through other connection modes, and the connection mode between the user motion information generator 2 and the frame body 203 is not limited and can be freely selected.

A heat sink 201 for forcibly dissipating the user motion information may be further fixed to the user motion information generator 2, and the heat sink 201 may be directly fixed to the user motion information generator 2 by screws.

The heat sink 201 may adopt a heat dissipation fan, and the user movement information generator 2 may further be provided with a temperature detector 202 and a controller, the temperature detector 202 is configured to detect the temperature of the user movement information generator 2, and the controller is configured to control the heat sink 201, wherein the temperature detector 202 is in communication with the controller, and the heat sink 201 is controlled by the controller to operate. The controller controls the operation of the heat sink 201 according to the temperature parameter detected by the temperature detector 202.

In some possible embodiments, a heat dissipation area may be further disposed on the casing 5, a plurality of through holes may be disposed in the heat dissipation area, and a filter screen covering the heat dissipation area may be further disposed on the casing 5, and the filter screen may be fixed to the casing 5 by adhesion or detachable connection, and specifically, the filter screen is mainly used to prevent external impurities from entering the installation space 501, so as to optimize the working environment of the user movement information generator 2.

The function of the heat dissipation area is mainly used to realize convection between air in the installation space 501 and outside air, so as to further improve the working environment of the user motion information generator 2 and prolong the service life of the user motion information generator 2.

One possible implementation scheme is that the monitoring component 4 comprises a human body motion track scanner 401, the monitoring component 4 is connected to the casing 5 in a sliding mode, a driver 402 for driving the monitoring component 4 to reciprocate along the vertical direction is arranged on the casing 5, a controller for controlling the driver 402 to work is further arranged in the casing 5, the controller is in communication with the information input device 1, and the controller controls the driver 402 to work according to the height of a user input by the information input device 1.

The human motion trajectory scanner 401 in this scheme may adopt an active radar, or the human motion trajectory scanner 401 may also adopt a passive radar, or the human motion scanner may also adopt a thermal imager, and its specific scheme is not limited, and its main function lies in monitoring the human motion trajectory to obtain the relevant parameters of the user's motion process. Further, please refer to the above description for a method for determining whether the motion form of the user conforms to the standard motion form, which is not described herein again.

The monitoring component 4 is mainly used for monitoring the actual motion trail of the user, specifically, the motion form of the user in deep squatting motion can be obtained by monitoring the actual motion trail of the user, and data is provided for judging whether the actual motion form of the user meets the standard motion form.

Therefore, in order to improve the monitoring accuracy of the monitoring assembly 4, the monitoring assembly 4 should be at different heights according to the heights of different users. Illustratively, when monitoring subassembly 4 includes the radar, the probe wave that monitoring subassembly 4 sent is the toper and outwards radiates, does benefit to reflected wave and trigonometric function relation and can calculate user's height, and the motion trail when mainly used monitoring user actual motion in this scheme, consequently, does not need too accurate parameter can reachd the motion trail when user actual motion.

In the practical application process, the heights of different users may have larger differences, so that the monitoring component 4 adjusts the positions of the users according to the heights of the users, which is more favorable for detecting the actual motion tracks of the users, and is further favorable for optimizing the performance of the deep-squatting motion monitoring device.

Specifically, the distance of the monitoring component 4 from the ground can be measured, and the measurement can be preset in the memory of the monitoring component 4 or a data memory with data storage capacity during the debugging process of the squat exercise monitoring device, when the position of the monitoring component 4 is adjusted, the ground can be used as a reference, and then the height of the monitoring component 4 from the ground is adjusted to match the heights of different users.

The adjustment process is described in detail with reference to the above description of the monitoring assembly 4 including radar. That is, the specific position of the monitoring assembly 4 is adjusted by trigonometric function relationship, for example, the height of the monitoring assembly 4 from the ground may be one third or one fifth of the height of the user, and so on. The position of the monitoring component 4 away from the ground is determined by adopting a trigonometric function, and the volume of the deep-squatting motion monitoring device is mainly considered, namely the height of the deep-squatting motion monitoring device is not too high, so that the situation that the deep-squatting motion is too high and is not beneficial to placement is avoided.

In a possible solution, when the detection range of the monitoring unit 4 is large enough, the monitoring unit 4 may be fixed to the housing 5 without sliding. For example, the detection height of the monitoring component 4 is 0.1 meter to 3 meters, and at this time, since the possibility that the height of the human body exceeds 3 meters is low, the monitoring component 4 having the detection range does not need to move on the housing 5, even though the monitoring accuracy of the monitoring component 4 in the scheme is low, since the monitoring component 4 is only used for acquiring the actual motion form of the user, the monitoring component 4 does not need to have high detection accuracy, and the scheme can also meet the function of the monitoring component 4. In addition, this scheme is favorable to simplifying the structure of motion detection device squats deeply.

In this embodiment, the controller for controlling the driver 402 may be integrated into the user motion information generator 2, but of course, the controller may be independently configured, and the configuration scheme of the controller is not limited in detail and may be freely selected by those skilled in the art.

Specifically, after the controller obtains the height information of the user, the controller calculates the optimal position of the monitoring component 4 from the ground by using the trigonometric function relationship, and the optimal position may be, for example, one third of the distance of the monitoring component 4 from the ground. In this case, it is more beneficial for the monitoring component 4 to obtain the actual motion information of the user.

When the user who has different heights uses the motion monitoring devices of squatting deeply, because every user's height is different, this moment, the user's height information that the controller acquireed is also different, and then, utilizes the numerical value that trigonometric function obtained inequality, and at this moment, the controller is according to the information that trigonometric function acquireed, adjusts monitoring component 4 apart from the concrete position on ground.

In this embodiment, the controller may directly communicate with the information input device 1, and of course, when the controller is integrated with the user movement information generator 2, the information input device 1 communicates with the user movement information generator 2, and then the controller indirectly obtains the information input by the information input device 1.

In this embodiment, in order to improve the monitoring capability of the monitoring component 4, a monitoring window 502 for contacting the monitoring component 4 with the outside is further disposed on the housing 5, wherein the monitoring window 502 is in a strip shape, and the monitoring window 502 is disposed along a vertical direction, that is, the length direction of the monitoring window 502 is perpendicular to a horizontal plane.

Monitoring subassembly 4 can be with the surface parallel and level of casing 5, and monitoring subassembly 4 also can be indent in casing 5, and monitoring subassembly 4 should not bulge the surface of casing 5 to avoid monitoring subassembly 4 to bulge the 5 surfaces of casing, and then avoid monitoring subassembly 4 to damage because the collision.

The portion of the housing 5 forming the monitoring window 502 may have a recessed feature to prevent the monitoring component 4 from protruding beyond the outer surface of the housing 5. A portion of the exemplary monitoring assembly 4 may be located within the monitoring window 502 to allow the monitoring assembly 4 to communicate with the outside, thereby improving the monitoring capability of the monitoring assembly 4 and preventing the housing 5 from interfering with the monitoring of the monitoring assembly 4.

In a possible embodiment, a closer 503 having elastic deformation capability and covering the monitoring window 502 is further disposed on the monitoring window 502, and the closer 503 cooperates with the monitoring component 4 to close the monitoring window 502. The main function of the closer 503 is to close the monitoring window 502 to prevent external dust from entering the installation space 501 through the monitoring window 502, optimize the working environment of the user motion information generator 2, and prolong the service life of the user motion information generator 2.

The shutter 503 may be formed of a corrugated tube-like sheet material having a score, i.e., the shutter 503 may have a score so that the shutter 503 may be easily opened or closed to close the monitoring window 502 in response to movement of the monitoring assembly 4.

One end of the shutter 503 may be fixed to the housing 5 and the other end of the shutter 503 may be fixed to the monitoring unit 4. Illustratively, one end of the shutter 503 may be bonded to the housing 5 and the other end of the shutter 503 may be bonded to the monitoring assembly 4. When the closer 503 has no supporting capability, that is, when the closer 503 has better flexibility, in order to optimize the connection performance between the half-clutch and the monitoring window 502, interfaces may be disposed on two sides of the closer 503, and the interfaces are connected to the side walls of the monitoring window 502. For example, the interface is provided with a slot that mates with a sidewall of the monitoring window 502. The interface may be a unitary structure with the closer 503.

One or more interfaces may be provided, and the number of interfaces is not limited and may be freely selected by those skilled in the art.

As a possible alternative, a sliding groove may be provided on the side wall of the monitoring window 502, and a slider cooperating with the sliding groove may be provided on the closer 503, and the slider may be of an integral structure with the closer 503. The slider and the sliding groove may be in line contact to reduce the friction coefficient between the slider and the sliding groove, thereby prolonging the wear between the slider and the sliding groove and prolonging the service life of the closer 503.

As a possible alternative, the shutter 503 may not have the elastic deformation capability, for example, the shutter 503 may be made of a rigid plate material, the shutter 503 is fixed to the monitoring member 4, and the shutter 503 moves together with the monitoring member 4. The area of the closer 503 is used to allow the closer 503 to close the monitoring window 502 during movement of the monitoring assembly 4.

A guide for guiding the closer 503 may be further provided on the housing 5, and the guide may have a guide groove that cooperates with the closer 503. The guide groove cooperates with the closer 503 to guide the closer 503. The guide may be fixed to the housing 5 by screws, or the guide may be welded to the housing 5.

As shown in fig. 4 and 5, in a possible embodiment, the driver 402 includes a linear servo motor, the linear servo motor includes an output block 403, the monitoring component 4 is fixed on the output block 403, a guide rail 404 is further disposed on the housing 5, a sliding slot matched with the guide rail 404 is disposed on the output block 403, and the guide rail 404 and the housing 5 are of an integral structure.

The driver 402 is mainly used to drive the monitoring assembly 4 to reciprocate in the vertical direction in the present embodiment. The linear servo motor has higher precision, and is simple in structure and easy to assemble. The output block 403 of the linear motor may be connected to the monitoring component 4 by screws, and the output block 403 of the linear motor may also be connected to the monitoring component 4 by other connection methods.

The linear servo motor acts according to the pulse current, and has high action precision. Of course, the linear servo motor may be replaced by other structures with linear output capability. Alternatively, the driver 402 may include a prime mover that outputs rotational motion that is converted to linear motion by a lead screw-nut pair, thereby driving the monitoring assembly 4 to reciprocate in a vertical direction.

The linear servo motor has stepping capability and does not need to be provided with an independent position detector. When the other actuator 402 having no stepping capability is used, a position measuring device for detecting the position of the monitoring unit 4 may be provided on the housing 5, and the position measuring device may be configured to have a position detecting capability such as a grating scale. The connection mode of the position detector and the housing 5 is not limited, and those skilled in the art can reasonably select the position detector according to the needs. Illustratively, the grating ruler may be fixed on the housing 5 by screws.

In this scheme, the guide rail 404 is mainly used for guiding the output block 403, so that the output block 403 has higher movement precision, the guide rail 404 may be fixed on the rack by screws, and the guide rail 404 may also be arranged on the housing 5 by welding.

The fixing manner of the guide rail 404 is not limited, and can be freely selected as needed. The cross-sectional shape of the guide rail 404 may be a trapezoid, and the specific shape of the cross-section of the guide rail 404 is not limited and may be freely selected.

A receiving groove may be further provided in the guide rail 404, grease may be applied to the receiving groove, and the width of the guide rail 404 is smaller than the width of the output block 403. The grease mainly plays a role of lubrication, so that abrasion between the guide rail 404 and the output block 403 can be reduced, and the service life of the output block 403 is prolonged.

In a possible implementation, the information input device 1 comprises a portable intelligent electronic device 101, the portable intelligent electronic device 101 communicates with the user motion information generator 2 through a network, a graphic code 301 matched with the portable intelligent electronic device 101 is arranged on the display component 3, and an identifier for identifying the graphic code 301 is arranged on the portable electronic device.

The portable intelligent electronic device 101 in the present solution may be a smart phone or a tablet computer or other electronic devices with network access capability.

In this scheme, the fact that the portable intelligent electronic device 101 communicates with the user motion information generator 2 through the network means that the portable intelligent electronic device 101 can obtain information obtained by the user motion information generator 2, and the user motion information generator 2 can also obtain information obtained by the portable intelligent electronic device 101. The communication between the portable intelligent electronic device 101 and the user movement information generator 2 is bi-directional, i.e. both directions can transfer data to each other.

The network in the scheme can be an Ethernet or a local area network. The communication between the portable intelligent electronic device 101 and the user movement information generator 2 may also be implemented in a short-range wireless communication mode, such as bluetooth communication.

The graphic code 301 in the present embodiment may be a two-dimensional code or a bar code or other graphics with recognizable ability. The graphic code 301 in this embodiment may be disposed on the housing 5, for example, the substrate printed with the graphic code 301 may be adhered to the housing 5, or the substrate printed with the graphic code 301 may be fixed on the housing 5 by other means.

Specifically, the portable intelligent electronic device 101 scans the graphic code 301 and obtains the information contained in the graphic code 301, which the portable intelligent electronic device 101 then recognizes to form a communication or connection.

The graphic code 301 in the above-mentioned scheme is disposed on the housing 5 or the display module 3, but the graphic code 301 may also be displayed on the display screen of the portable intelligent electronic device 101 and recognized by the recognizer disposed on the housing 5. The position of the graphic code 301 is not limited, and those skilled in the art can reasonably select the position according to the needs.

The recognizer is a recognition device with the capability of recognizing the graphic code 301, and at least comprises an image capture device for collecting the information of the graphic code 301. For example, when the recognizer is disposed on the portable intelligent electronic device 101, the recognizer includes at least a camera component disposed on the portable intelligent electronic device 101.

The graphic code 301 and the recognizer in the present embodiment are mainly used to establish communication between the portable intelligent electronic device 101 and the user motion information generator 2, and implement data transmission between the portable intelligent electronic device 101 and the user motion information generator 2.

One possible solution, in this embodiment, may further include a cloud server. Specifically, the portable intelligent electronic device 101 recognizes the graphic code 301 and then performs data transmission with the user motion information generator 2 through the cloud server. At this time, the relevant data may be backed up in the cloud server. According to the scheme, due to the use of the cloud server, the local data storage capacity of the deep-squatting motion monitoring device can be reduced, and a user can inquire the body-building information of the user on the deep-squatting motion monitoring device at any position. The scheme optimizes the performance of the deep-squatting motion monitoring device, and a user can acquire fitness information at any position, so that the application range of the deep-squatting motion monitoring device is widened.

One possible embodiment, this deep squat sport monitoring device still includes the instruction sign of instructing the user motion region, instruction sign includes the step pad 7 be provided with pedal instruction label 701 on the step pad 7, pedal instruction label 701 bonds in on the step pad 7.

The foot mat 7 can be made of any material, and the foot mat 7 is mainly used for playing a prompting function and prompting a user to do deep squatting movement at a correct position so as to facilitate the monitoring assembly 4 to acquire a correct actual movement form of the user.

Specifically, the foot pad 7 may be made of a rubber material, and the foot pad 7 may be laid on the ground. In order to make the foot mat 7 have better contact ability with the ground, i.e., the pedals are not easy to slip on the ground, patterns can be arranged on the side of the foot mat 7 contacting with the ground to increase the friction between the foot mat 7 and the ground and optimize the performance of the foot mat 7.

The suction disc can be arranged on the pedal pad 7 and is adsorbed on the ground, after the pedal pad 7 is placed on the ground, the suction disc on the pedal pad 7 is adsorbed on the ground, at the moment, the pedal pad 7 is not easy to move, and the stability of the pedal pad 7 is improved.

The suction cup can be adhered to the pedal pad 7, the suction cup can also be integrated with the pedal pad 7, the connection mode of the suction cup and the pedal pad 7 is not limited, and the suction cup can be freely selected by a person skilled in the art. Illustratively, the suction cup may also be secured to the footpad 7 using an interference fit.

The foothold indicator 701 provided on the foothold 7 in the present embodiment is mainly used to indicate the correct standing posture of the user, i.e. a possible correct position between the feet. The step indication label 701 may be fixed on the step pad 7 by other methods, for example, the step indication label 701 may be directly coated on the step pad 7. The specific setting mode of the foot indication label 701 is not limited, and those skilled in the art can reasonably select the foot indication label according to needs, and the setting mode is not limited herein.

In this scheme, the setting of step pad 7 mainly used suggestion user's the position of standing to do benefit to monitoring subassembly 4 and monitor the actual motion form of user, consequently, step pad 7 should be in reasonable within range apart from the position of casing 5, with the monitoring precision that improves monitoring subassembly 4. Illustratively, the distance between the foot pad 7 and the casing 5 may be 1 to 2 meters, wherein the distance between the foot pad 7 and the casing 5 is 1 meter, which is more reasonable, on one hand, the monitoring precision of the monitoring component 4 is improved, on the other hand, the user can observe the actual motion form of the user for the standard motion form played on the display component 3, and the user can correct the wrong motion track in time.

For this purpose, a first position detector may be provided on the housing 5, and a second position detector may be provided on the step pad 7, wherein the first position detector and the second position detector are used in cooperation, and when the distance between the first position detector and the second position detector is 1 meter, the first position detector gives a prompt to prompt the user that the step pad 7 may be placed at the current position. The first position detector and the second position detector for implementing the scheme are conventional structures in the prior art, can be obtained by purchase, and are not limited herein.

The first position detector can be fixed on the casing 5 through screws, an LED lamp can be further arranged on the first position detector, and when the distance between the first position detector and the second position detector is within a certain range, such as 1 meter, the LED lamp is lightened to play a role in prompting. The second position detector may be fixed to the step pad 7 in any manner, for example, an installation recess may be formed in the step pad 7, the second position detector may be disposed in the installation recess in an interference fit manner, and the second position detector may be bonded to the installation recess. The second position detector should be located completely within the mounting pocket to avoid damage to the second position detector from stepping on.

In a possible embodiment, a hook may be further disposed on the housing 5, the hook may be fixed to the housing 5 by a screw, or the hook may be integrated with the housing 5, and the hook is mainly used for hooking an article. For example, a user may carry an object with him or her during exercise, and at the same time, the object may be hung on the hook to facilitate exercise.

A possible optimization scheme is that the machine shell 5 can be further provided with a storage bag, the storage bag can be arranged on the machine shell 5 in a bonding mode, the storage bag can also be arranged on the machine shell 5 in other modes, and the storage bag is mainly used for storing articles and is beneficial to body building of a user. For example, when the user carries a personal object, which is not suitable for hanging, the object can be placed in the storage bag.

A monitoring device for deep squat exercise mainly comprises an information input device 1, a user exercise information generator 2, a display component 3 and a monitoring component 4, and the relationship among the components of the monitoring device for deep squat exercise is described with reference to the above introduction, and is not described again. And the function and operation of the components are described with reference to the above description.

As shown in fig. 2, the squat exercise monitoring device provided by the present solution generally does not have a region limitation, that is, any user in a certain interval can obtain a corresponding virtual valuable carrier through any squat exercise monitoring device. Based on the user's range of motion considerations, the squat exercise monitoring device has a more reasonable hardware environment in conjunction with an implementation that includes a cloud server.

Specifically, after the related data information is backed up or stored in the cloud server, the user may obtain the fitness information and the obtained virtual valuable carrier at any position through the portable intelligent electronic device 101, and further, may obtain the corresponding virtual valuable service at any position through the virtual valuable carrier. According to the scheme, the data storage pressure and the operation pressure of the portable intelligent electronic equipment 101 and the deep-stepping motion monitoring device are reduced, and the performance of the deep-squatting motion monitoring device is optimized.

As shown in fig. 4, in one possible embodiment, the virtual value carrier in the present solution may be carried by a virtual carrier, for example, a card or a paper sheet. In particular, the virtual value carrier may be a bar code or a pictorial or textual information with recognizable capabilities, which information is printed on a paper or card, which is held by the user for relevant use. Based on the scheme, in a possible hardware environment, a printer 505 is further provided in the housing 5, the printer 505 is connected with the user movement information generator 2, the printer 505 is controlled by the user movement information generator 2, a paper outlet 504 of the printer 505 is further provided on the housing 5, and a paper outlet for discharging paper for the printer 505 is further provided on the housing 5.

The specific structures of the paper output port 504 and the paper output port are not limited, and those skilled in the art can freely select the structures as needed.

As described above, the user motion information generator 2 in the present disclosure should have certain control capability in addition to the necessary logical motion calculation capability, for example, the user motion information generator 2 should at least include the necessary features for realizing the logical operation and control capability, such as a central processing unit. The central processing unit implementing this function is of conventional construction in the prior art and may be obtained commercially.

In addition, it should be noted that the specific embodiments described in the present specification may differ in the shape of the components, the names of the components, and the like. All equivalent or simple changes made according to the structure, characteristics and principle of the utility model are included in the protection scope of the utility model. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims (10)

1. The utility model provides a motion monitoring devices squats deeply which characterized in that:

the device comprises an information input device (1) for inputting basic information of a user, wherein the basic information of the user at least comprises the age, the sex, the height and the weight of the user;

the user motion information generator (2), the user motion information generator (2) generates user motion information according to the user basic information;

the display component (3) is used for playing the standard motion form and the actual motion form of the user;

and the monitoring component (4) is used for monitoring the actual motion form of the user, wherein the actual motion information of the user is calculated if the actual motion form of the user accords with the standard motion form, and the actual motion information of the user is not calculated if the actual motion form of the user does not accord with the standard motion form.

2. The squat exercise monitoring device of claim 1, wherein: this motion monitoring devices squats deeply still includes casing (5), display module (3) set up in on casing (5), display module (3) include the touch-control screen, information input ware (1) integrate in display module (3) be provided with installation space (501) in casing (5), monitoring subassembly (4) reach user motion information generator (2) all set up in installation space (501), wherein, monitoring subassembly (4) with user motion information generator (2) communication, information input ware (1) display module (3) all with user motion information generator (2) communication.

3. The squat exercise monitoring device of claim 2, wherein: monitoring subassembly (4) include human action orbit scanner (401), monitoring subassembly (4) sliding connection in on casing (5) be provided with the drive on casing (5) monitoring subassembly (4) along vertical direction reciprocating motion's driver (402), still be provided with the control in casing (5) the controller of driver (402) work, the controller with information input ware (1) communication, the controller basis the user's height control of information input ware (1) input driver (402) work.

4. A squat exercise monitoring device as claimed in claim 3, wherein: the driver (402) comprises a linear servo motor, the linear servo motor comprises an output block (403), the monitoring component (4) is fixed on the output block (403), a guide rail (404) is further arranged on the casing (5), a sliding groove matched with the guide rail (404) is formed in the output block (403), and the guide rail (404) and the casing (5) are of an integrated structure.

5. The squat exercise monitoring device of claim 1, wherein: the information input device (1) comprises portable intelligent electronic equipment (101), the portable intelligent electronic equipment (101) is communicated with the user motion information generator (2) through a network, a graphic code (301) matched with the portable intelligent electronic equipment (101) is arranged on the display component (3), and an identifier for identifying the graphic code (301) is arranged on the portable electronic equipment.

6. The squat exercise monitoring device of claim 2, wherein: this motion monitoring devices squats deeply still includes the instruction sign that instructs the user motion region, instruction sign includes pedal pad (7) be provided with pedal instruction label (701) on pedal pad (7), pedal instruction label (701) bond in on pedal pad (7).

7. The squat exercise monitoring device of claim 6, wherein: the pedal pad (7) is provided with a sucker for fixing the pedal pad (7) at a target position, and the sucker is adhered to the pedal pad (7).

8. The squat exercise monitoring device of claim 6, wherein: a first position detector is arranged on the housing (5), a second position detector is arranged on the foot pad (7), wherein the first position detector is in communication with the second position detector, and the distance between the foot pad (7) and the housing (5) is detected by the first position detector and the second position detector.

9. The squat exercise monitoring device of claim 8, wherein: the first position detector includes an LED lamp that lights up when a distance between the step pad (7) and the housing (5) reaches a set distance.

10. The squat exercise monitoring device of claim 8, wherein: the first position detector is fixed on the casing (5) through screws.

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