KR20140063374A - Anaerovic threshold presume device and method - Google Patents

Abstract

Disclosed is lactic acid threshold presumption device and method. The lactic acid threshold presumption device includes a heart rate detection part which detects heart rate corresponding to a potential signal sensed from a user; and an lactic acid threshold presumption part which presumes the lactic acid threshold of the user by using the change of the heart rate.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus and method for estimating a lactic acid threshold value,

One embodiment below relates to an apparatus and method for estimating a lactic acid threshold value. More particularly, the present invention relates to an apparatus and method for estimating a lactic acid threshold value by using a state change during a user's motion.

Conventionally, in order to measure a user's exercise load, a user performs exercise until the user's heart rate is raised to a maximum value, thereby measuring the exercise load on the user.

However, such a measurement method causes a discomfort to the user's body by continuously exercising until the user reaches the maximum heart rate. It has also been reported that the measurement method is overestimated rather than the user's exercise load.

And, the exercise load is easy to measure through the lactate threshold. At this time, the lactate threshold is measured using the blood of the user. However, the use of blood causes the user to feel uncomfortable, painful, and repulsive. In addition, the lactic acid threshold measurement equipment is used as a specific person and is not easy to measure by the general public.

Therefore, a method for measuring the lactate threshold without discomfort and discomfort should be suggested to minimize the strain on the user's body.

According to an embodiment of the present invention, there is provided a device for estimating a lactic acid threshold value, comprising: a heart rate detector for detecting a heart rate in response to a sensed potential signal; And a lactic acid threshold value estimating unit for estimating a lactic acid threshold value of the user based on the change in the heart rate, wherein the lactic acid threshold value estimating unit estimates a time and a time at which the heart rate is in a steady state based on a heart rate of a specific load by the user Lactic acid threshold can be estimated by heart rate at the time of state.

According to another aspect of the present invention, there is provided an apparatus for estimating a lactic acid threshold value, comprising: a kinetic energy calculation unit for calculating a kinetic energy corresponding to a physical motion corresponding to a sensed physical movement from a user; And a lactic acid threshold value estimating unit for estimating a lactic acid threshold value of the user by using a change in heart rate by the kinetic energy, wherein the lactic acid threshold value estimating unit estimates the lactic acid threshold value based on the heart rate of the user, And the lactate threshold value can be estimated by the value of the heart rate at the steady state.

According to an embodiment of the present invention, there is provided a method for estimating a lactic acid threshold value, comprising: detecting a heart rate corresponding to a sensed potential signal from a user; And estimating the lactic acid threshold value of the user using the change in the heart rate, wherein the step of estimating the lactic acid threshold value includes: determining a time when the heart rate is in a rest state based on the heart rate of the specific load by the user; Lactate threshold can be estimated from the heart rate at steady state.

According to another aspect of the present invention, there is provided a method for estimating a lactic acid threshold value, comprising: calculating a kinetic energy corresponding to a physical movement sensed by a user; And estimating a lactic acid threshold value of the user based on a change in heart rate due to the kinetic energy, wherein the step of estimating the lactic acid threshold value comprises: And the lactic acid threshold value can be estimated by the heart rate at the steady state.

1 is a view for explaining a lactic acid threshold value estimating apparatus according to an embodiment of the present invention.
2 is a view for explaining a lactic acid threshold value estimating unit according to an embodiment of the present invention.
3 is a view for explaining a lactic acid threshold value estimating apparatus according to the second embodiment.
FIG. 4 is a view illustrating a process of estimating a lactic acid threshold value operating in a user terminal according to an exemplary embodiment of the present invention.
FIG. 5 is a detailed block diagram illustrating a process of estimating a lactic acid threshold value operating in the user terminal of FIG.
6 is a view illustrating a process of estimating a lactic acid threshold value operating in a user terminal according to the second embodiment.
FIG. 7 is a detailed block diagram illustrating a process of estimating a lactic acid threshold value operating in the user terminal of FIG.
8 is a view for explaining a motion guide device according to an embodiment.

 Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.

1 is a view for explaining a lactic acid threshold value estimating apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the lactic acid threshold value estimating apparatus 102 may include a heart rate detector 103 and a lactic acid threshold value estimator 104.

The heart rate detection unit 103 can sense the potential signal of the user. In other words, the heart rate detection unit 103 can sense a potential signal with respect to a state change during movement of the user. The heart rate detection unit 103 may include a heart rate sensor for sensing a potential signal, an EMG sensor, and the like. In addition, the state change may be a pulse or heartbeat in the body which is changed by the user in comparison with the normal state of the user.

The heart rate detector 103 can amplify the potential signal according to the intensity of the potential signal. The heart rate detecting unit 103 may filter the potential signal to a band capable of detecting the heart rate. For example, the heart rate detection unit 103 may filter the heart rate detection band based on the sensed potential signal through the heart rate sensor and the EMG sensor.

Also, the heart rate detector 103 can monitor the heart rate change with respect to the detected heart rate. Therefore, the lactic acid threshold value estimating apparatus 102 can calculate data on the state change according to the movement of the user by monitoring the heart rate change. In addition, the lactic acid threshold value estimating apparatus 102 can monitor the heart rate change to measure the user's lactate threshold value.

The lactic acid threshold value estimating unit 104 can estimate the user's lactic acid threshold value using the change in the heart rate. The lactic acid threshold value estimating unit 104 may estimate the user's lactic acid threshold value based on the heart rate of the specific load due to the user.

The lactic acid threshold value estimating device 102 can estimate the user's lactic acid threshold value by sensing the potential signal of the user through a separate sensor. At this time, the lactic acid threshold value estimating device 102 senses the potential signal of the user through the sensor regardless of the place and time, thereby minimizing the influence of the external environment. For example, the lactic acid threshold value estimating apparatus 102 may estimate the user's lactic acid threshold value by sensing the potential signal of the user, without discriminating between users who exercise outside or inside.

Then, the lactic acid threshold value estimating apparatus 102 can receive the estimated lactate threshold of the user from the user. The lactic acid threshold value estimating device 102 can estimate the user's lactic acid threshold value through a running machine / cycle capable of applying a constant gradual load.

2 is a view for explaining a lactic acid threshold value estimating unit according to an embodiment of the present invention.

Referring to FIG. 2, the lactic acid threshold value estimating unit can estimate the lactic acid threshold value using a specific load by the user. The specific load may be to specify the exercise load, such as defining the exercise load at a constant magnitude, while estimating the lactate threshold. The lactic acid threshold value estimating unit can measure a change in heart rate corresponding to a specific load. In addition, the lactic acid threshold value estimating unit can estimate the lactic acid threshold value using the measured state of the heart rate. The steady state may be a state in which a physical response such as a heart rate during a user's exercise is balanced. In other words, the lactate threshold value estimator can estimate the lactate threshold value by the heart rate at the time of steady state and the heart rate at steady state.

For example, the lactic acid threshold value estimator may measure the heart rate of the user A (201) and the user B (202) corresponding to a specific load. At this time, a1 302 and b1 205 shown in Fig. 2 may be the time to reach the steady state. The a2 204 and the b2 206 shown in FIG. 2 may be the average heart rate of the starburst.

The user A 201 may occur in the a1 302 state. And, the a1 (302) section can be kept stable for a long time. Then, the user B 202 may occur in the b1 (205) interval. The b1 (205) section may have a short steady state.

At this time, the higher the lactate threshold, the shorter the time as in the comparison of b1 (205) and a1 (302) according to the constant exercise load, and the heart rate is lower than a2 (204) . That is, the higher the lactate threshold, the shorter the exercise load interval and the lower the heart rate.

Thus, the higher the lactate threshold, the higher the lactate threshold of user B 202, which includes steady state characteristics, than user A 201. Then, the user B (202) can estimate the intensity of the motion with high lactate threshold.

The lactic acid threshold value estimating unit may estimate the lactic acid threshold value using the personal information related to the user's exercise. Personal information may include the user's body mass index (BMI), age, gender, and Rest HR.

3 is a view for explaining a lactic acid threshold value estimating apparatus according to the second embodiment.

Referring to FIG. 3, the lactic acid threshold value estimating apparatus 301 may include a kinetic energy calculating unit 302 and a lactic acid threshold value estimating unit 303.

The kinetic energy calculating unit 302 may sense the physical motion from the user. The kinetic energy calculating unit 302 can sense the physical motion of the user through a sensor such as an acceleration sensor. The physical motion may be the vector magnitude (VM), the step number, etc. according to the motion. The kinetic energy calculating unit 302 can calculate the kinetic energy according to the physical motion. At this time, the kinetic energy calculating unit 302 can calculate kinetic energy by performing signal integration of physical motion.

The lactic acid threshold value estimating unit 303 may estimate the lactate threshold value based on the time at which the heart rate is at rest and the heart rate at the steady state based on the heart rate of the specific load by the user.

Accordingly, the lactic acid threshold value estimating apparatus 301 can estimate the user's lactic acid threshold value by using the heart rate of the user, the heart rate according to the user's activity, and the heart rate of the specific load by the user.

FIG. 4 is a view illustrating a process of estimating a lactic acid threshold value operating in a user terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the sensing device 401 may perform motion monitoring 402. The sensing device 401 can sense the potential signal of the user. And, the sensing device 401 can measure the potential signal with respect to the state change during the user's motion in order to estimate the lactic acid threshold value. Also, the sensing device 401 can transmit the potential signal of the user to the user terminal 403 capable of data transmission / reception. The sensing device 401 and the user terminal 403 may be interlocked / connected through wireless communication.

The user terminal 403 can estimate the user's lactic acid threshold value based on the sensed potential signal. Then, the user terminal 403 can set a user's exercise goal using the estimated lactic acid threshold value. In addition, the user terminal 403 may provide the user with a user's exercise goal.

The user terminal 403 can work with the server 405. The server 405 may receive data relating to the user's lactic acid threshold or the user's exercise goal from the user terminal 403. [ The server 403 may share the received data with different users of the social network.

In summary, the sensing device 401 can sense the potential signal of the user from the user and transmit it to the user terminal 403. The user terminal 403 can estimate the user's lactic acid threshold using the potential signal of the received user.

FIG. 5 is a detailed block diagram illustrating a process of estimating a lactic acid threshold value operating in the user terminal of FIG.

5, the sensing device 501 may include a potential signal electrode unit 502, a differential amplification unit 503, a motion sensing unit 504, and a transmission unit 505.

The potential signal electrode unit 502 can sense the potential signal of the user. The potential signal electrode unit 502 can measure the potential signal with respect to the state change during the user's motion in order to estimate the lactic acid threshold value.

The differential amplification unit 503 can perform differential amplification according to the intensity of the potential signal of the user. In other words, the differential amplification unit 503 can perform differential amplification according to the intensity to extract the potential signal of the user.

The motion sensing unit 504 can sense the physical motion of the user. In other words, the motion sensing unit 504 can sense a physical motion of a sensor capable of measuring acceleration, angular velocity, and motion. The motion sensing unit 504 can be used when the user does not have a separate timer or cycle to apply a progressive exercise load.

The transmitting unit 505 can transmit the measured potential signal or the physical motion to the user terminal 506.

The user terminal 506 includes a receiving unit 507, a heartbeat detecting unit 508, a kinetic energy calculating unit 509, a verification load evaluating unit 510, a heartbeat trend measuring unit 511, a lactic acid threshold value estimating unit 512, A target selection section 513, a motion guide section 514, a display section 515, and a communication section 517. [ The user terminal 506 may further include a speaker unit 516 according to the use environment.

The receiving unit 507 can receive the potential signal of the user or the physical movement from the sensing device 501. [

The heartbeat detecting unit 508 may filter the heartbeat based on the sensed potential signal in a band capable of detecting heart rate.

The kinetic energy calculating unit 509 can calculate the kinetic energy using the physical motion signal sensed by the motion sensing unit 504. [ In this case, the physical motion may be a vector magnitude (VM), a step number, or the like according to the motion. The kinetic energy calculating unit 509 can measure the amount of activity of the user through kinetic energy. The kinetic energy calculating unit 509 can calculate kinetic energy by performing signal integration of physical motion.

The verification load evaluation unit 510 can monitor the exercise load according to the amount of kinetic energy. In other words, the verification load evaluation unit 510 can monitor whether or not the exercise load is progressively increased for the measurement of the lactate threshold value. For example, the verification load evaluation unit 510 can calculate the amount of activity when the user walks or runs by monitoring the amount of activity. In addition, the verification load evaluation unit 510 can estimate the magnitude of the activity amount in accordance with the change in the heart rate. At this time, the amount of activity may increase in proportion to the exercise intensity of the user.

The heartbeat-trend measuring unit 511 can monitor a change in heart rate using a sensed potential signal and a physical motion signal. The heartbeat-trend measuring unit 511 can calculate data on the state change according to the motion flow of the user by monitoring the change in the heart rate.

The lactic acid threshold value estimating unit 512 may estimate the lactate threshold value using a specific load for a predetermined size by the user. Then, the lactic acid threshold value estimating unit 512 can measure a change in heart rate in response to a specific load. With respect to the steady state of the measured heart rate, the lactic acid threshold value estimating unit 512 can estimate the lactate threshold value by the time at which the heart rate is at rest and the heart rate at the steady state.

Here, the lactic acid threshold value estimating unit 512 can estimate the lactate threshold value using the characteristic that the exercise load interval is short and the heart rate is low as the lactic acid threshold value is higher in the steady state.

The exercise target selection unit 513 can select a user's exercise goal based on the estimated lactate threshold of the user. In other words, the exercise target selection unit 513 can select a corresponding exercise goal according to the user's exercise goal based on the user's lactic acid threshold value and the heart rate.

The exercise guide unit 514 can guide the user to the exercise program using the selected exercise goals. Specifically, the exercise guide unit 514 can guide exercise programs, such as dieting, cardiopulmonary endurance, and the like, according to the purpose of exercise by a user's customized exercise program.

The display unit 515 can display an exercise program on the user terminal 506. [ The display unit 515 can display various information such as a user's motion target, a motion state, and the like. Then, the display unit 515 can provide the customized information according to the adjustment of the display item of the user.

The speaker unit 516 can provide the user's motion state through the speaker. At this time, the speaker unit 516 can provide data such as the number of sets of motion sets, heart rate, lactate threshold, and the like currently provided by the user through a speaker.

The communication unit 517 can operate in conjunction with the server 518. [ The server 518 may interface with the user terminal 506. The server 518 can receive and store data such as the user's lactic acid threshold value. The server 518 may provide the stored data to the user terminal 506 at the request of the user terminal 506. [ The server 518 may also perform community and trend analysis.

6 is a view illustrating a process of estimating a lactic acid threshold value operating in a user terminal according to the second embodiment.

Referring to FIG. 6, the sensing device 601 may perform exercise monitoring 602, lactic acid threshold estimation. The sensing device (601) senses the potential signal of the user in the sensing device (601) and can estimate the corresponding lactic acid threshold value. At this time, the sensing device 601 can sense the potential signal of the user or the physical motion of the user.

More specifically, the sensing device 601 can sense the potential signal of the user. Also, the sensing device 601 can perform differential amplification according to the intensity of the potential signal of the user. Then, the sensing device 601 can sense the physical movement of the user.

Then, the sensing device 601 can estimate the user's lactic acid threshold value using the potential signal of the user or the physical motion. More specifically, the sensing device 601 may monitor the potential signal and physical movement of the user. The sensing device 601 can monitor the user's potential signal and the physical movement using the change of the user's heart rate or the amount of kinetic energy. The sensing device 601 can estimate the lactic acid threshold value by the time at which the heart rate is at the steady state and the heart rate at the steady state.

In addition, the sensing device 601 can select a fitness target for the user using the lactate threshold value and the heart rate, and guide the exercise program accordingly. The sensing device 601 and the user terminal 604 may be interlocked / connected via wireless communication.

The user terminal 604 may receive and provide to the user a signal related to the user's lactate threshold and heart rate.

Then, the server 605 can perform community and trend analysis. The server 605 can operate in conjunction with the user terminal 604. [

FIG. 7 is a detailed block diagram for explaining a process of estimating a lactic acid threshold value in the user terminal of FIG.

The sensing device 701 includes a potential signal electrode unit 702, a differential amplifying unit 703, a heartbeat detecting unit 704, a motion sensor unit 705, a kinetic energy calculating unit 706, an incremental load evaluating unit 707, A heart rate trend measuring unit 708, a lactic acid threshold value estimating unit 709, a motion target selecting unit 710, and a motion guide unit 711.

The potential signal electrode unit 702 can sense the potential signal of the user. The differential amplification unit 703 can perform differential amplification according to the intensity of the potential signal of the user. The heartbeat detecting unit 704 can filter the heartbeat based on the sensed potential signal into a band capable of detecting heart rate. The heartbeat detecting unit 704 can measure a user's body change in addition to the heartbeat measuring sensor by filtering the potential signal. The motion sensor unit 705 can sense a user's physical motion using a sensor capable of measuring acceleration, angular velocity, and motion.

The kinetic energy calculator 706 can calculate the kinetic energy using the sensed physical motion. The kinetic energy calculating unit 706 can calculate the kinetic energy by performing signal integration of the physical motion.

The incremental load evaluating unit 707 can monitor the exercise load according to the amount of the kinetic energy. In other words, the verification load evaluating unit 707 can monitor whether or not the exercise load is progressively increased for the measurement of the lactate threshold value.

The heart rate trend measuring unit 708 can monitor a change in the heart rate using a sensed potential signal and a physical motion signal. The heartbeat-trend measuring unit 708 can calculate data on the state change according to the motion flow of the user by monitoring the change in the heart rate.

The lactic acid threshold value estimating unit 709 can estimate the user's lactic acid threshold value based on the heart rate of the specific load due to the user. More specifically, the lactic acid threshold value estimator 709 can estimate the lactic acid threshold value based on the time when the heart rate is in the steady state and the heart rate in the steady state.

The exercise goal selection unit 710 can select a corresponding exercise goal according to the user's exercise goal based on the user's lactate threshold and the heart rate. The exercise guide unit 711 can guide exercise programs such as diet, cardiopulmonary endurance, and the like according to the purpose of exercise with a customized exercise program of the user.

The user terminal 712 may include a display unit 713 and a communication unit 715. The user terminal 712 may further include a speaker portion 714 according to the use environment.

The display unit 713 can display the exercise program on the user terminal 712. [ The display unit 713 can display various information such as a user's motion target, a motion state, and the like. The display unit 713 can provide customized information according to the adjustment of the display items of the user.

Speaker unit 714 can provide the user's motion state through the speaker. At this time, the speaker unit 714 can provide data such as the number of sets of the current exercise set, the heart rate, and the lactate threshold value through the speaker.

The communication unit 715 can be used for interworking with the server 716. [ The server 716 may interwork with the user terminal 712. The server 716 can receive and store data such as the user's lactic acid threshold value. The server 716 may also perform community and trend analysis. The server 716 may provide the stored data to the user terminal 712 at the request of the user terminal 506.

The server shown in Figs. 4 and 6 described above may or may not be included according to the embodiment.

8 is a view for explaining a motion guide device according to an embodiment.

Referring to FIG. 8, the exercise guide device 802 may include a lactic acid threshold value receiving unit 803 and an exercise program providing unit 804.

The lactic acid threshold value receiving unit 803 can receive the lactic acid threshold value of the user estimated according to the user's heart rate from the lactic acid threshold value estimating apparatus.

The exercise program providing unit 804 may provide an exercise program corresponding to personal information related to a user's exercise goal using a lactic acid threshold value. The personal information may be information on the user's body weight, height, body fat, exercise intensity, and the like.

Thus, the exercise program providing unit 804 can provide the exercise program by adjusting the maximum value of the lactate threshold value, taking into account the personal information related to the exercise goal. For example, the exercise program provider 804 may estimate a user's athletic performance based on the lactate threshold. At this time, the exercise capacity may mean the size of the exercise that the user can accommodate during exercise. The athletic performance can mean the user's exercise intensity.

The exercise program providing unit 804 can provide an exercise program at a level higher than the maximum value of the lactate threshold to improve the athletic ability and the cardiopulmonary endurance for a user having a high exercise ability based on the lactate threshold. The exercise program providing unit 804 can provide a user with a low exercise ability based on the lactate threshold, an exercise program that can maintain the fitness while improving the exercise ability and cardiopulmonary endurance. That is, the exercise program providing unit 804 can provide the user's personalized exercise program according to the exercise ability based on the lactate threshold. And, the motion guide device can maximize the exercise effect within the same time by providing the optimized exercise program according to the exercise ability of the user.

 While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

101: Sensor
102: Lactic acid threshold value estimating device
103: potential signal sensing unit
104: Lactic acid threshold value estimating unit

Claims (4)

A heart rate detector for detecting a heart rate in response to a potential signal sensed by a user;
A lactic acid threshold value estimating unit for estimating a lactic acid threshold value of the user using the change in the heart rate,
Lt; / RTI >
Wherein the lactic acid threshold value estimating unit comprises:
And estimating a lactic acid threshold value based on a time at which the heart rate is at rest and a heart rate at a steady state based on the heart rate of the specific load by the user. A kinetic energy calculating unit for calculating a kinetic energy corresponding to the physical motion corresponding to a physical motion sensed by the user;
A lactic acid threshold value estimating unit for estimating a lactic acid threshold value of the user using the change in heart rate by the kinetic energy,
Lt; / RTI >
Wherein the lactic acid threshold value estimating unit comprises:
And estimating a lactic acid threshold value based on a time at which the heart rate is at rest and a heart rate at a steady state based on the heart rate of the specific load by the user. Detecting a heart rate in response to a potential signal sensed by a user;
Estimating a lactic acid threshold value of the user using the change in the heart rate
Lt; / RTI >
Wherein the step of estimating the lactic acid threshold value comprises:
And estimating a lactic acid threshold value based on a time at which the heart rate is at rest and a heart rate at a steady state based on the heart rate of the specific load by the user. Calculating kinetic energy according to the physical movement corresponding to the sensed physical movement from the user;
Estimating a lactic acid threshold value of the user using a change in heart rate due to the kinetic energy,
Lt; / RTI >
Wherein the step of estimating the lactic acid threshold value comprises:
And estimating a lactic acid threshold value based on a time at which the heart rate is at rest and a heart rate at a steady state based on the heart rate of the specific load by the user.

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