TWI593385B - Cardiorespiratory endurance step exercise bench detector system and method thereof - Google Patents

Description

Cardiopulmonary endurance stage detector system and method thereof

The present invention relates to a detector system and method thereof, and more particularly to a cardiopulmonary endurance stage detector system and method therefor.

In recent years, due to the gradual attention of the health of the whole people, the development of various sports habits has continued to be promoted. Among them, physical fitness tests for measuring physical conditions such as cardiopulmonary ability, muscle strength, and softness are also implemented in schools and institutions at all levels. These fitness test results can not only serve as indicators of the health status of the whole people, but also provide reference for the development of relevant policies. More importantly, people can understand their own physical conditions, and then cooperate with appropriate sports types to continue to exercise and maintain good health. status.

In the test of related fitness, in addition to measuring the physical state of the special measurement equipment, such as the measurement of body mass index (BMI) weight scale, other measurements mostly rely on the general code table or manual statistical methods. That is to say, most of the subjects need to perform relevant measurements with the help of others (such as a coach or a teacher), so it is more difficult to obtain the results of the relevant measurements independently at the same time as these tests or trainings. Moreover, since it is calculated manually, whether the motion of each subject is standard, whether the movement of the body part or the position of the body is deviated, it is necessary for an experienced coach or teacher to distinguish, in the case of multiple subjects. When the time is being tested, the coach or teacher will not be able to master each name. It is inconvenient for the subject's actions to be true or not. In addition, in general, during the examination, the coach or teacher will read out the measurement results of the subject, so that the subject knows his physical condition. However, this will not only cause a comparative mentality between peers, but also make the subject feel embarrassed because of their physical condition and being known by the surrounding people.

In summary, the current physical fitness test still has many problems to be solved.

In view of the above problems of the prior art, it is an object of the present invention to provide a cardiopulmonary endurance stage detector system and method thereof for solving the problem that the automatic measurement cannot be achieved when performing cardiorespiratory endurance detection in the prior art. The issue of confidentiality and correct measurement of the number of times of cardiopulmonary endurance.

In order to achieve the foregoing objective, the present invention provides a cardiopulmonary endurance stage detector system, comprising: a step platform module, comprising a stepping platform, a guiding unit and at least one sensor, the guiding unit and the sensor being disposed on the treading platform The guiding unit sends a plurality of guiding signals at a fixed frequency in a predetermined time interval, and the sensor is triggered to generate a trigger signal; and an identity recognition module is used to identify one of the user's identity marks to generate An identity recognition signal; an output module for outputting a start command and an end command; a communication module for wirelessly transmitting a measurement result to a database; and a control module electrically connected A module, an identity recognition module, an output module, and a communication module. The control module outputs the start command according to the identity recognition signal, and causes the guiding unit to send a guiding signal at a starting time point of one of the preset time intervals, and the user advances according to the start command and the guiding signal. During the time, the two feet are stepped onto the treading platform, and then the two feet are sequentially removed from the treading platform to trigger the sensor to generate a trigger signal, and the control module counts the trigger signal as a valid number, and counts the preset time interval. The sum of the effective times gives a total effective number. And the control module is The end time point of one of the preset time intervals causes the output module to output an end command, so that the user stops the trigger sensor according to the end instruction, and the measurement result including the total effective number is wirelessly transmitted to the database by the communication module.

The step platform module further includes at least one support portion, and the stepping platform is disposed on the support portion.

Wherein, the number of the support portion and the sensor are two, and the two ends of the stepping platform are respectively disposed on the support portions, and the sensors are pressure switch sensors and are disposed inside the support portions or the support portions and the treading platform Contact surface.

The cardiopulmonary endurance stage detector system of the present invention further comprises a physiological sensor electrical connection control module, wherein the physiological sensor measures physiological information of the user, and the measurement result further comprises physiological information.

The cardiopulmonary endurance stage detector system of the present invention further comprises a reminder unit disposed on the stepping platform and electrically connected to the control module, wherein the control module determines whether the sensor is subjected to the preset time period within a preset time interval. Trigger to cause the reminder unit to output a reminder signal.

When the reminder unit outputs the reminder signal, the control module counts the trigger signal as an invalid number, and counts the sum of the invalid times in the preset time interval to obtain a total invalid number, and the measurement result further includes the total invalid number .

In addition, the present invention also provides a method for detecting the cardiopulmonary endurance, comprising: providing a cardiopulmonary endurance stage detector system, the cardiopulmonary endurance stage detector system having a board module, a identity recognition module, An output module, a communication module and a control module, the step platform module includes a treading platform, a guiding unit and at least one sensor; performing an identity identification step to identify the user by the identity recognition module One of the identity marks and generates an identification signal to the control module; a first command output step, wherein the control module causes the output module to output a start command according to the identity recognition signal; and a guiding step, the guiding unit sends a guiding signal at a start time of a preset time interval, and Sending a plurality of pilot signals at a fixed frequency in a preset time interval; performing a measurement step, wherein the user sequentially mounts the feet on the treading platform according to the start command and the pilot signals in a predetermined step time and then The two feet are sequentially removed from the treading platform to generate a plurality of trigger signals by multiple triggering sensors; and a counting step is performed, the control module counts each triggering signal as a valid number of times, and counts the effective times in the preset time interval. The total number of times is obtained; a second command output step is performed, and the control module terminates the time point in one of the preset time intervals to cause the output module to output an end command, so that the user stops triggering the sensor according to the end command. And performing an integrated transmission step, the control module wirelessly including the measurement result of the total effective number by the communication module Lose to a database.

The method for detecting the cardiopulmonary endurance of the present invention further includes performing at least one reminding step, wherein the control module determines whether the sensor is triggered within the preset time interval within a preset time interval, so as to be disposed on the treading platform and One of the electrical connection control modules reminds the unit to output a reminder signal.

When the reminder unit outputs the reminder signal, the control module counts the trigger signal as an invalid number, and counts the sum of the invalid times in the preset time interval to obtain a total invalid number, and the measurement result further includes the total invalid number .

The method for detecting the cardiopulmonary endurance of the present invention further comprises performing a physiological information measuring step, wherein a physiological sensor is used to measure physiological information of the user, and the measuring result further comprises physiological information.

In view of the above, a cardiorespiratory stage detector system and method thereof according to the present invention may have one or more of the following advantages:

(1) The cardiopulmonary endurance stage detector system and method of the present invention, comprising a cardiopulmonary endurance stage comprising a step platform module, an identity recognition module, an output module, a communication module and a control module The detector system can automatically measure the cardiopulmonary endurance order of the subject, without manual testing and interpretation, and no one will have problems such as interpretation error, data transmission error, labor cost and no confidentiality. .

(2) The cardiopulmonary endurance stage detector system of the present invention and the method thereof, wherein the guiding unit issues a plurality of guiding signals at a fixed frequency in a preset time interval, so that the user can follow the guiding signal for a preset time period. The two feet are sequentially stepped on the pedaling platform, and then the feet are sequentially removed from the pedaling platform to trigger the sensor to generate a trigger signal, and then the control module is used to count the trigger signal as a valid number, and the preset time is counted. The sum of these effective times in the interval gives a total effective number. In this way, it can be determined whether the user has stepped up and left the pedaling platform in the preset time (ie, whether the rhythm of the platform is up and down with the guiding signal), thereby avoiding the user's stepping rhythm. The problem of incorrect measurement results in inaccuracies.

(3) The cardiopulmonary endurance stage detector system and method of the present invention, wherein the control module determines whether the sensor is triggered, so that the reminder unit outputs a reminder signal. In this way, during the measurement process, if the user does not mount and leave the pedaling platform in accordance with the frequency or rhythm of the pilot signal, the reminder unit will send a reminder signal to remind the user that the rhythm is not up. Correctly, the pace or frequency of the steps should be corrected to facilitate the smooth measurement steps.

(4) The cardiopulmonary endurance stage detector system of the present invention and the method thereof, wherein the physiological information measuring step can be performed during or after the user performs the step-up measurement to measure the user's condition by the physiological sensor Physiological information such as pulse or body temperature is wirelessly transmitted to the database by the communication module to obtain and record the user's cardiorespiratory endurance index.

(5) The cardiopulmonary endurance stage detector system and method of the present invention, by encrypting the measurement result by the encryption module, can avoid the problem of the leakage of the capital. Moreover, the user can also identify the user's identity mark by the identity recognition module after the measurement to view or compare the measurement results of the user.

100‧‧‧ Cardiopulmonary Endurance Stage Detector System

10‧‧‧Stepping platform module

12‧‧‧Stepping platform

14‧‧‧Guide unit

16‧‧‧ sensor

18‧‧‧Support

181‧‧‧First support

182‧‧‧second support

20‧‧‧ Identity Identification Module

30‧‧‧Output module

40‧‧‧Communication module

50‧‧‧Control module

60‧‧‧Encryption Module

70‧‧‧Power supply unit

80‧‧‧ Physiological sensor

90‧‧‧Reminder unit

D‧‧‧Database

M‧‧‧ identity mark

S10, S20, S30, S40, S50, S60, S70, S80, S90, S100, S110‧‧

1 is a circuit block diagram of a cardiopulmonary endurance stage detector system of the present invention.

2 is a schematic cross-sectional view of a stepping platform module of the present invention.

3 is a cross-sectional view showing the stepping platform of the inductor disposed on the contact surface of the first support portion and the second support portion in the present invention.

4 is a schematic flow chart of a first preferred embodiment of the method for detecting cardiorespiratory endurance of the present invention.

FIG. 5 is a schematic flow chart of a second preferred embodiment of the method for detecting cardiorespiratory endurance of the present invention.

Figure 6 is a schematic illustration of the subject using the invention.

In order to understand the technical characteristics, content and advantages of the creation and the effects that can be achieved by the examiner, the author will cooperate with the schema and explain the following in the form of the embodiment, and the schema used therein The subject matter is only for the purpose of indicating and supporting the manual. It is not necessarily the true proportion and precise configuration after the implementation of the original creation. Therefore, the proportion and configuration relationship of the attached drawings should not be interpreted or limited. The scope of rights in actual implementation. In addition, in order to facilitate understanding, the same elements in the following embodiments are denoted by the same reference numerals.

Please refer to FIG. 1 and FIG. 2 together. FIG. 1 is a circuit block diagram of a cardiopulmonary endurance stage detector system of the present invention, and FIG. 2 is a cross-sectional view of the step platform module of the present invention. As shown in FIG. 1 , the cardiopulmonary endurance stage detector system 100 of the present invention comprises a step platform module 10 , an identity recognition module 20 , an output module 30 , a communication module 40 , and a control module 50 . As shown in FIG. 2, the stage module 10 includes a stepping platform 12, a guiding unit 14 and at least one sensor 16. The guiding unit 14 and the sensor 16 are disposed on the stepping platform 12, and the guiding unit 14 is attached to a preset time. A plurality of pilot signals are sent at a fixed frequency in the interval, and the sensor 16 is triggered to generate a trigger signal. The identity recognition module 20 is configured to identify one of the user's identity marks M to generate an identity recognition signal. The output module 30 is configured to output a start command and an end command, for example, voice. The communication module 40 is configured to wirelessly transmit the measurement result to the database D. The control module 50 can be electrically connected to the step platform module 10, the identity recognition module 20, the output module 30, and the communication module 40, for example, by wires.

The control module 50 causes the output module 30 to output a start command according to the identity recognition signal, and causes the guiding unit 14 to send a guiding signal at the starting time of the preset time interval, and the user pre-sets the command according to the start command and the guiding signal. The pedals are sequentially stepped on the treading platform 12 and then the feet are sequentially removed from the treading platform 12 to trigger the sensor 16 to generate a trigger signal. The control module 50 counts the trigger signal as a valid number and counts the presets. The sum of these effective times in the time interval gives a total effective number. Moreover, the control module 50 causes the output module 30 to output an end command at the end time of the preset time interval, so that the user stops the trigger sensor 16 according to the end command, and the communication module 40 will include the total effective number. The measurement results are wirelessly transmitted to the database D. The database D can be, for example, a network database or a fitness integration center, and the measurement results are transmitted to the database D to store, record and integrate the user's physical data. The database D can be set inside or outside the platform module 10 to measure the measurement results by wired or wireless The mode is transferred to the database D. In addition, after the measurement, the user can identify the user's identity mark M by the identity recognition module 20, so that the user can view or compare the measurement results of the user (for example, the user can measure once every other time) The number of times the cardiopulmonary endurance is upgraded to assess whether the physical condition improves.)

The user's identity mark M can be, for example, a wafer card in which the user's identity is recorded or a user's fingerprint. Any wafer card or component that can be used to represent a user is the identity mark M claimed in the present invention.

The preset time interval, that is, the time during which the user performs the step measurement, may be, for example, 3 minutes, but is not limited thereto. The fixed frequency may be, for example, 96 beats per minute, so the guiding unit 14 may issue a pilot signal at a fixed frequency of 96 beats per minute, for example, within a preset time interval of 3 minutes. The pilot signal can be, for example, a voice signal and/or a light signal, but is not limited thereto. In addition, the user can adjust the frequency at which the guiding unit 14 sends the guiding signal according to actual needs, for example, setting the fixed frequency to 80 beats per minute or 100 beats per minute. When the user wants to climb at a faster speed, the fixed frequency of the guiding signal sent by the guiding unit 14 can be set to 100 beats per minute, for example, by the control module 50; and when the user wants to slow down, When the step is up, the fixed frequency at which the guiding unit 14 sends the guiding signal can be set to 80 beats per minute by the control module 50. The above preset time interval and the fixed frequency are only examples, and are not limited, and the user can adjust the setting according to actual needs.

In an embodiment, the step platform module 10 further includes at least one support portion 18 , and the stepping platform 12 is disposed on the support portion 18 . The number of the support portions 18 may be, for example, two, and the number of the inductors 16 may be, for example, two or more. For example, as shown in FIG. 2, the number of the support portions 18 is two, and the number of the inductors 16 is four, and the two ends of the stepping platform 12 are respectively disposed on the two support portions 18, and each support Two inductors 16 are disposed inside the portion 18. The sensor 16 can be electrically connected to the control module 50, for example, by wires (for the sake of simplicity, the wires and control module 50 are not shown in FIG. 2). The sensor 16 can be, for example It is a pressure switch sensor, but is not limited to this. Any sensing device that can be used to trigger a trigger signal is the sensor 16 claimed in the present invention.

The inductor 16 can be disposed, for example, inside the support portion 18 (FIG. 2), or the inductor 16 can be disposed on the contact surface of the support portion 18 and the stepping platform 12. In addition, as shown in FIG. 3 , the support portion 18 may include a first support portion 181 and a second support portion 182 , and the inductor 16 is disposed on a contact surface of the first support portion 181 and the second support portion 182 . When the number of the inductors 16 is two or more, the inductor 16 is disposed inside the support portion 18 or is disposed on the contact surface of the support portion 18 and the stepping platform 12 or the first support portion 181 and the second support portion 182. On the contact surface, as long as one of the sensors 16 is triggered to generate a trigger signal within a preset time, the control module 50 will total the trigger signals generated during the preset time period to a valid number of times. Therefore, the user does not need to worry about whether the position of the two feet on the treading platform 12 corresponds to the sensor 16 , and only needs to push the two feet to the treading platform 12 according to the guiding of the guiding signal, so that the stepping can be easily completed. Measure.

In a preferred embodiment, the cardiopulmonary endurance stage detector system 100 of the present invention may further include an encryption module 60 electrically connected to the control module 50 to encrypt the measurement result (see FIG. 1). The encryption module 60 can be disposed inside the board module 10 and electrically connected to the control module 50, or the user can also set the encryption module 60 outside the board module 10 according to actual needs.

In a preferred embodiment, the cardiopulmonary endurance stage detector system 100 of the present invention further includes a power supply unit 70 electrically connected to the control module 50 for supplying power to the control module 50 (see FIG. 1). . The power supply unit 70 can be disposed inside the board module 10 and electrically connected to the control module 50, or the user can also set the power supply unit 70 outside the board module 10 according to actual needs.

In a preferred embodiment, the cardiopulmonary endurance stage detector system 100 of the present invention may further include a physiological sensor 80 electrically connected to the control module 50, and the physiological sensor 80 is used to measure the user's A physiological information, and the measurement results more include physiological information. The physiological sensor 80 can be disposed on a wristband, for example, and the user can set the wristband provided with the physiological sensor 80 on the wrist of the user during the user's measurement or completion. After the step measurement, the physiological sensor 80 senses the user's pulse or body temperature and other physiological information, and the control module 50 wirelessly transmits the user's physiological information to the database D through the communication module 40. Thereby, the cardiopulmonary endurance index of the user after performing the step-up measurement or after performing the ranking measurement can be known.

In a preferred embodiment, the cardiopulmonary endurance stage detector system 100 of the present invention may further include a reminder unit 90 disposed on the stepping platform 12 and electrically connected to the control module 50 to control the mode in a preset time interval. The group 50 determines whether the sensor 16 is triggered within a preset time period to cause the reminder unit 90 to output a reminder signal. The reminder unit 90 can be, for example, an alarm or an illuminator, and the alert signal can be, for example, a voice signal and/or a light signal, but is not limited thereto. Any reminder device that can issue a reminder signal is the reminder unit 90 claimed in the present invention.

When the reminding unit 90 outputs the reminder signal, the control module 50 counts the trigger signal as an invalid number, and counts the sum of the invalid times in the preset time interval to obtain a total invalid number, and the measurement result further includes total invalid. frequency.

For example, if the guiding unit 14 issues a pilot signal at a fixed frequency of 96 beats per minute (ie, a pilot signal is sent every 0.625 seconds), the preset time is 2.5 seconds. In other words, the user must step on the stepping platform 12 in a preset time of 2.5 seconds and then remove the feet from the pedaling platform 12 in sequence to complete the stepping action. If the user completes a step-up action within a preset time of 2.5 seconds, the control module 50 counts the trigger signal generated by the step-up as a valid number of times. If the user does not complete the step-up action within the preset time of 2.5 seconds, the control module 50 controls the reminder unit 90 to output a reminder signal, and counts the trigger signal generated by the step-by-step as none. Number of times. Since the user must complete a step-up action within the preset time-to-step time as an effective number, it is ensured that the user's step-up measurement is correct and the posture is correct.

The identity recognition module 20 and the output module 30 can be disposed, for example, at one end of the pedaling platform 12, and the guiding unit 14 and the reminder unit 90 can be disposed, for example, at the other end of the pedaling platform 12. For example, as shown in FIG. 2 and FIG. 3, when the user performs the ranking measurement, the identity recognition module 20 and the output module 30 are located on the left side of the user, and the guiding unit 14 and the reminding unit 90 are in use. The right side of the person. Alternatively, as shown in FIG. 6, when the user boardes the treadmill 12, the identity recognition module 20 and the output module 30 are located in front of the user, and the guiding unit 14 and the reminder unit 90 are located behind the user. The setting positions of the identity recognition module 20, the output module 30, the guiding unit 14, and the reminding unit 90 are merely examples and are not limitative. The user can change the setting positions of the identity recognition module 20, the output module 30, the guiding unit 14, and the reminding unit 90 according to actual needs.

Please refer to FIG. 4. FIG. 4 is a schematic flow chart of a first preferred embodiment of the method for detecting cardiorespiratory endurance of the present invention. As shown in FIG. 4, in the first preferred embodiment, the cardiopulmonary endurance step detection method of the present invention includes at least steps S10 to S80. In step S10, a cardiopulmonary endurance stage detector system is provided, and the cardiopulmonary endurance stage detector system has a step platform module, an identity recognition module, an output module, a communication module and a control module, and the step platform The module includes a stepping platform, a guiding unit and at least one sensor. In step S20, an identity recognition step is performed to identify the identity of the user and generate an identity recognition signal to the control module by the identity recognition module. In step S30, a first command output step is performed, wherein the control module causes the output module to output a start command according to the identity recognition signal. In step S40, a guiding step is performed, the guiding unit sends a guiding signal at a starting time point of the preset time interval, and issues a plurality of guiding signals at a fixed frequency within a preset time interval. In step S50, a measuring step is performed, in which the user sequentially steps on the two feet according to the start command and the guiding signal within a preset time limit. The platform is stepped and then the feet are sequentially removed from the pedaling platform to generate a plurality of trigger signals by triggering the sensor multiple times. In step S60, a counting step is performed, and the control module counts each trigger signal as a valid number of times, and counts the sum of the effective times in the preset time interval to obtain the total effective number. In step S70, a second command output step is performed, and the control module outputs an end command to the output module at the end time of the preset time interval, so that the user stops the trigger sensor according to the end command. In step S80, an integrated transmission step is performed, and the control module wirelessly transmits the measurement result including the total effective number to the database by using the communication module.

In the second preferred embodiment, the cardiopulmonary endurance step detection method of the present invention includes not only steps S10 to S80 but also steps S90, S100 and/or step S110. The second preferred embodiment of the present invention differs from the foregoing first preferred embodiment only in that the second preferred embodiment of the present invention further includes step S90, step S100, and/or step S110. Steps S10 to S80 are not described in detail. As shown in FIG. 5, FIG. 5 is a schematic flow chart of a second preferred embodiment of the method for detecting cardiorespiratory endurance of the present invention. In step S90, a reminding step is performed, and the control module determines whether the sensor is triggered during the preset time interval in the preset time interval, so that the reminding unit is disposed on the pedaling platform and electrically connected to the control module. Output a reminder signal. When the reminder unit outputs the reminder signal, the control module counts the trigger signal as the invalid number, and counts the sum of the invalid times in the preset time interval to obtain the total invalid number, and the measurement result further includes the total invalid number. In step S100, a physiological information measurement step is performed, and the physiological information of the user is measured by the physiological sensor, and the measurement result further includes physiological information. In step S110, an encryption step is performed to encrypt the measurement result by electrically connecting the encryption module of the control module. As shown in FIG. 5, step S100 can be performed, for example, between steps S70 and S110 (that is, the physiological information measurement step is performed after the user performs the measurement), but is not limited thereto. The user can follow the actual needs in the steps Step S100 is performed between S30 and S70 (that is, the physiological information measuring step is performed during the user's step-up measurement).

The following description describes how to perform cardiopulmonary endurance assessment using the cardiopulmonary endurance stage detector system of the present invention. Referring to FIG. 1 , FIG. 2 , FIG. 4 and FIG. 6 , the cardiopulmonary endurance stage detector system 100 is first provided (step S10 ), and the user may first place the user's identity mark M in the identity recognition module 20 . In the corresponding position (see FIG. 6, for example, the identity mark M is placed above the identity recognition module 20, or the identity mark M is moved to a position detectable by the identity recognition module 20). After the identity recognition module 20 recognizes the user's identity mark M (step S20), the control module 50 activates the output module 30 to issue a command such as a voice or video (step S30, for example, "heart and lung endurance" The detection starts, please prepare the voice, or display the screen of the subject standing on the plane before the landing platform 12 on the display screen (not shown). In the present invention, the sensor 16, the identification module 20, and the output module 30 can be electrically connected to the control module 50, for example, by wires (for the sake of simplicity, the wires are not shown in FIG. 6).

Subsequently, the user stands on the plane in front of the landing platform 12 in accordance with the aforementioned start command. Then, the guiding unit 14 emits a guiding signal such as voice or light at a starting time point of a preset time interval (for example, 3 minutes), and at a fixed frequency (for example, 96 beats per minute in a preset time interval of 3 minutes) A plurality of pilot signals are issued (step S40). The user sequentially steps the stepping platform 12 according to the instruction of the guiding signal (for example, 2.5 seconds as described above) and then sequentially removes the feet from the treading platform 12 to trigger the sensor. A trigger signal is generated (step S50). The manner in which the user climbs the treading platform 12 may be, for example, first placing the right foot on the treading platform 12, then placing the left foot on the treading platform 12, then stepping the right foot back to the plane, and finally stepping the left foot back to the plane; or Alternatively, the left foot is first placed on the treading platform 12, and then the right foot is placed on the treading platform 12, then the left foot is stepped back to the plane, and finally the right foot is stepped back to the plane. In other words, first step on the foot of the stepping platform 12 and step back on the plane. In the preset time zone of 3 minutes In the interval, the user can change the foot of the treading platform 12 first. For example, in a certain stepping action, the left foot first boardes the treading platform 12, and in the next step, the right foot first boardes the treading platform 12.

During the preset time interval of 3 minutes, the control module 50 counts the trigger signals generated in the preset time period as the effective number, and counts the sum of the effective times in the preset time interval to obtain the total effective number of times. (Step S60). After the preset time interval of 3 minutes has elapsed, the control module 50 causes the output module 30 to issue an end command such as a voice (step S70, for example, "send the measurement, stop the action"). When the user hears the end command, the action is stopped and the stepping platform 12 is no longer mounted. Finally, the control module 50 integrates the total effective number with the user information (eg, identity) to integrate a measurement result (including the measured total effective number and user information), and the communication module 40 This measurement result is wirelessly transmitted to the database D (step S80). In the present invention, the communication module 40 can also be electrically connected to the control module 50, for example, by wires. (To simplify the drawing, the communication module 40 and the control module 50 are not shown in FIG. 6, and the communication module is 40, the way to connect the control module 50 is shown in Figure 1).

In addition, in the preset time interval of, for example, 3 minutes, if the user does not complete the step-up action within the preset time (ie, the user's step-up rhythm does not match the guide signal), the control module 50 The reminder unit 90 outputs a reminder signal such as a voice or a light (step S90 in FIG. 5), and counts the trigger signal generated by the current step as an invalid number of times. If the user's stepping rhythm does not match the pilot signal multiple times and the reminder unit 90 issues multiple reminder signals, the control module 50 counts the sum of these invalid times as the total number of invalid times. Moreover, in step S80, the control module 50 further integrates the total number of invalid times with the total effective number of times and the user information (for example, identity), and includes the measured total effective number and the total invalid number. The number of times and the user information are wirelessly transmitted to the database D by the communication module 40. Thereby, the user can know whether the rhythm of the cardiopulmonary endurance measurement is correct by reminding the unit 90 whether to issue a reminder signal. And, when the reminding unit 90 sends a reminder signal, The user can also immediately adjust and correct the action, avoiding the inaccurate number of invalid times of the incorrect rhythm after the preset time interval of 3 minutes, and the inconvenience of measuring again.

In addition, as shown in FIG. 5, after the step-up measurement is completed (step S70), physiological information such as pulse and/or body temperature of the user can be known by performing the physiological information measurement step (step S100), and the control mode is controlled. The group 50 then calculates the cardiorespiratory endurance index of the user by formula, and transmits the physiological information such as the pulse, body temperature and/or cardio endurance index of the user to the database D. As described above, the physiological information measurement step can also be performed simultaneously during the measurement of the ranking to know the cardiorespiratory index of the user during the period of the measurement and/or after the measurement.

In summary, the cardiopulmonary endurance stage detector system and method thereof of the present invention comprise cardiopulmonary endurance boarding including a step platform module, an identity recognition module, an output module, a communication module and a control module. The step detector system can automatically measure the cardiopulmonary endurance number of the subject, without manual testing and interpretation, no human error, data transmission error, labor cost and no confidentiality. The problem arises. Moreover, it can be determined whether the user's stepping rhythm is correct, and the problem that the measurement result is out of alignment due to the user's stepping rhythm or frequency is not avoided. In addition, the physiological information measurement step may be performed during or after the user performs the measurement, to measure the physiological information such as the pulse or body temperature of the user by the physiological sensor, and then the communication module will include The measurement results of the physiological information are wirelessly transmitted to the database to facilitate the acquisition and recording of the user's cardiorespiratory index. Moreover, by encrypting the measurement result by the encryption module, the problem of the leakage of the capital can be avoided. The user can also identify the user's identity mark by the identity recognition module after the measurement to view or compare the measurement results of the user.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of this creation shall be included in the scope of the appended patent application.

100‧‧‧ Cardiopulmonary Endurance Stage Detector System

10‧‧‧Stepping platform module

20‧‧‧ Identity Identification Module

30‧‧‧Output module

40‧‧‧Communication module

50‧‧‧Control module

60‧‧‧Encryption Module

70‧‧‧Power supply unit

80‧‧‧ Physiological sensor

90‧‧‧Reminder unit

D‧‧‧Database

Claims (8)

The cardiopulmonary endurance stage detector system comprises: a step platform module, comprising a stepping platform, a guiding unit and at least one sensor, wherein the guiding unit and the sensor are disposed on the pedaling platform, the guiding unit Sending a plurality of pilot signals at a fixed frequency within a predetermined time interval, the sensor being triggered to generate a trigger signal; and an identity recognition module for identifying a user identity mark to generate a identity recognition a signal output module for outputting a start command and an end command; a communication module for wirelessly transmitting a measurement result to a database; a control module electrically connecting the step module The identity recognition module, the output module, and the communication module; and a reminder unit disposed on the stepping platform and electrically connected to the control module, wherein the control module is configured according to the identity recognition signal The output module outputs the start command, and causes the guiding unit to send the guiding signal at a starting time point of the preset time interval, and the user according to the start command and the guiding signal The triggering signal is generated by sequentially driving the two feet to the treading platform and then sequentially releasing the two feet to trigger the sensor to generate the trigger signal, and the control module counts the trigger signal as one. The effective number of times, and counting the sum of the effective times in the preset time interval to obtain a total effective number, the control module outputs the end instruction at the end time point of the preset time interval to Having the user stop triggering the sensor according to the end instruction, and by using the The module wirelessly transmits the measurement information including the user information and the total effective number of the user to the database, wherein the control module determines whether the sensor is at the preset in the preset time interval. The triggering unit is triggered to output a reminder signal, wherein when the reminding unit outputs the reminder signal, the control module counts the trigger signal as an invalid number, and counts the preset time interval. The total number of invalid times is obtained by summing the number of invalid times, and the measurement result further includes the total number of invalid times. The heart-lung endurance stage detector system of claim 1, wherein the step platform module further comprises at least one support portion, and the stepping platform is disposed on the support portion. The cardiopulmonary endurance stage detector system of claim 2, wherein the number of the support portion and the sensor are two, and the two ends of the stepping platform are respectively disposed on the support portions, The sensors are pressure switch sensors and are disposed inside the support portions or the contact surfaces of the support portions and the pedaling platform. The cardiopulmonary endurance stage detector system of claim 1, further comprising a physiological sensor electrically connected to the control module, wherein the physiological sensor measures physiological information of the user, and The measurement result further includes the physiological information. The cardiopulmonary endurance stage detector system of claim 1, further comprising an encryption module electrically connected to the control module to encrypt the measurement result. The invention relates to a method for detecting cardiorespiratory endurance, comprising: providing a cardiopulmonary endurance stage detector system, the cardiopulmonary endurance stage detector system having a board module, an identity recognition module, an output module, a communication module and a control module, the step platform module includes a treading platform, a guiding unit and at least one sensor; Performing an identity identification step, wherein the identity recognition module identifies one of the user's identity marks and generates an identity recognition signal to the control module; performing a first command output step, wherein the control module identifies the identity according to the identity The signal command causes the output module to output a start command; and a guiding step is performed, the guiding unit sends a guiding signal at a starting time point of a preset time interval, and sends a plurality of signals at a fixed frequency within the preset time interval. a pilot signal; performing a measurement step, wherein the user sequentially mounts the feet on the treading platform according to the start command and the guide signals in a predetermined step time, and then sequentially removes the feet from the pedaling The platform generates a plurality of trigger signals by triggering the sensor in a plurality of times; performing a counting step, the control module counts each of the trigger signals as a valid number of times, and counting the effective times in the preset time interval And summing up a total effective number; performing at least one reminding step, the control module determining, in the preset time interval, whether the sensor is in the preset The triggering time is set to enable the reminder unit to be connected to the stepping platform and electrically connected to the control unit to output a reminder signal, wherein when the reminding unit outputs the reminder signal, the control module uses the trigger signal meter An invalid number of times, and counting the sum of the invalid times in the preset time interval to obtain a total number of invalid times, and the measurement result further includes the total invalid number; performing a second command output step, the control module Ending the time point in the preset time interval, causing the output module to output an end command, so that the user stops triggering the sensor according to the end instruction; Performing an integrated transmission step, the control module wirelessly transmits the measurement result including one of the user information and the total effective number to the data repository by the communication module. The method for detecting the cardiorespiratory endurance described in claim 6 further includes performing an encryption step of encrypting the measurement result by electrically connecting one of the control modules to the encryption module. The method for detecting the cardiopulmonary endurance described in claim 6 of the patent application further includes performing a physiological information measuring step, and measuring a physiological information of the user by using a physiological sensor, and the measuring result is obtained. It also contains this physiological information.