KR101361117B1 - Jump Lope for Exercise Management using Biometric information, and Method Using the Same - Google Patents

Abstract

The present invention relates to a rope skipping exercise management through the acquisition of biometric information, the exerciser grasps the current state of health of the person, and performs the exercise, according to the user to adjust the appropriate amount of exercise during exercise to virtual screen or handle vibration Since the user recognizes through the rope skipping exercise load to suit their purpose and to exercise.
An object of the present invention is a jump rope for exercise connected to the first and second handles, the first and second handles are key input unit for selecting the user's body information and the user's function; First and second sensor units respectively provided at each handle to measure biometric information by contacting a user's palm; The user's body information and function selection information input through the key input unit and the biometric information detected by the sensor unit are stored in the memory unit, and the user's recommended jump rope count, exercise amount and breathing information based on the input user body information and biometric information. A controller that calculates and outputs the same as display data; A liquid crystal display for displaying display data including user body information and function selection information under control of the controller; And a vibration motor which transmits a vibration signal to the user's palm under the control of the controller.

Description

Jump Lope for Exercise Management using Biometric information, and Method Using the Same}

The present invention relates to a skipping rope, and more particularly, to obtain biometric information through a sensor attached to a rope skipping handle, check and manage a user's health state by receiving personal information, and to display a skipping rope exercise method when using a skipping rope. The present invention relates to a rope skipping exercise management method through obtaining biometric information and a exercise management method using the same.

Jump rope has long been widely used by the public as part of health and beauty exercises. There are several types of skipping, such as doing it alone on a short line and doing several people on a long line. You can use one jump rope alone, such as X jump, twice a line when you run one time, another person in front of the person holding the line, jumping over or standing side by side in the same direction (forward). Many people use it as a tool for exercising and playing games.

Such exercise using rope skipping for a long time continuously stimulates the respiratory circulation function and muscles, which is effective in enhancing the endurance of the whole body, and there are various kinds of jumping movements, which are effective in raising the sense of systemic rhythm or timing. There is, and because it is a systemic exercise does not require a large place is used as a training means of sports.

Recently, various features have been added to the rope skipping handle and the rope to make it more convenient and interesting.

For example, the function of counting the number of times that the line is crossed over the handle is automatically displayed, or the speaker is provided with a voice output function. The function is added to be adjustable according to.

1 is a rope skipping type treadmill type portable treadmill having a virtual screen using an optical illusion according to the prior art input means (3, 4, 5) for inputting data to the rope skipping handle (10); Rotation number measuring unit (6, 7) for detecting the number of times the string rotates inside the handle (1); A rotation period measuring unit measuring a rotation period; A timer 8 for counting time; Storage means provided inside the handle and storing information and various information detected by the rotation speed measuring unit (6, 7); information stored in the storage means exposed to the outside of the handle and by a control signal A display unit 11 for displaying letters, numbers, or images, the housing having a predetermined size in the longitudinal direction of the string from a position on the string and maintaining a constant distance from the handle, and arranged closely in line with the housing A light emitting display unit 20 including a plurality of light emitting elements 21; a one-touch connecting member 30 that can be attached to and detached from a rope skipping rope at one end of the light emitting display unit 20; and the input means 3, 4, 5, and rotation The display information data is generated by calculating predetermined display information based on the data input from the number measuring unit 6 and 7 and the rotation period measuring unit, and displaying the display information on the display unit 11. And scan the area of the area displayed on the display unit 11 with the data in the area of the LCD pixel, store the scanned information area in the virtual matrix matrix area of a predetermined size or more, and display the area 11. ) Is processed, and the two-dimensional information displayed on the display unit 11 is stored in a virtual matrix matrix region having a row corresponding to the number of the light emitting elements 21 and stored in the matrix matrix. A control unit 10 for calculating a data corresponding to the control unit and outputting a control signal for adjusting a transmission speed of data transmitted based on the rotational speed of the rope skipping unit input from the rotational speed measuring unit 6 or 7; Generates a horizontal synchronization signal based on the clock signal and the corresponding clock signal, and corresponds to the corresponding column in the data of each matrix coordinate of the virtual matrix matrix. A display information transmitter 9 for outputting row data and controlling the output transmission speed of the row data output by the data transmission rate adjustment control signal by the controller 10; It is located inside the housing provided with 21 and is reset by the horizontal synchronizing signal outputted from the display information transmitting unit 9 and counts the clock signal by the number of the light emitting elements 21 to receive a counting completion signal. A counter to output; The light emitting device is located in a housing having the plurality of light emitting devices 21 and is reset by a horizontal synchronizing signal output from the display information transmitting unit 9. The light emitting device is shifted by shifting row data according to the clock signal. A shift register for matching matching in a line as in (21); Located in the housing in which the plurality of light emitting devices 21 are located, the row data stored in the shift register is transferred to the matched light emitting device 21 by the counting completion signal generated by the counter. And a signal transmission path opening and closing portion 21 for performing the blinking operation.

The connection portion of the handle and the string is fixed by the rope to the handle is connected by a rotating body to prevent twisting, the rotating body and the handle is connected by a hinge to the contact brush for supplying signals and driving power It is done.

By providing a skipping rope type treadmill with a virtual screen using optical illusions as described above, the mechanism of exercise has a rope skipping scheme, but it can be combined with a treadmill operating method that allows users to enjoy the amount of exercise, images, or games during exercise. During the skipping exercise, various information about the current exercise amount and information about the exercise time are displayed on the moving track of the rope used in the skipping rope due to the afterimage caused by the optical illusion of the user's visual abilities. The virtual screen using the optical illusion to be able to be displayed as the screen can be solved to various needs of the user.

However, the jumping rope-type portable treadmill having a virtual screen using an optical illusion according to the prior art helps to visually make more interesting when exercising with a rope skipping through the virtual screen, and does not actually manage the health status of the user. , Users do not know the amount of exercise or their current state of health when exercising using the rope skipping, because there is a problem to exercise or do not exercise because of the excessive exercise.

Accordingly, the present invention is to recognize the user through the virtual screen or the handle vibration to determine the current state of health of the person exercising, to perform the exercise according to the exercise, and to adjust the appropriate amount of exercise during exercise to improve the problems of the prior art Therefore, the purpose of the present invention is to provide an exercise management rope skipping and exercise management method using the same by acquiring biometric information which allows the user to identify and exercise the rope skipping exercise load that is suitable for them.

Exercise management rope skipping through the acquisition of biometric information to achieve the object of the present invention analyzes the user's biometric information acquisition and health status using the first and second handle rope jump rope connected to the display, and displays the analyzed health status In the jump rope for exercise management by obtaining biometric information for calculating and displaying an appropriate exercise amount, the first and second handles include a key input unit for selecting user's body information and a user's function; First and second sensor units respectively provided at each handle to measure biometric information by contacting a user's palm; The user's body information and function selection information input through the key input unit and the biometric information detected by the sensor unit are stored in the memory unit, and the user's recommended jump rope count, exercise amount and breathing are based on the input user body information and biometric information. A controller for calculating information and outputting the information as display data; A liquid crystal display for displaying display data including user body information and function selection information under control of the controller; And a vibration motor for transmitting a vibration signal to a user's palm under the control of the controller, wherein the rope skipping string is blinked by the control of the power and controller supplied from the handle to rotate the rope skipping character. Alternatively, a plurality of LEDs in which an image is displayed as an afterimage effect may be embedded.

The controller may include an A / D converter converting each signal input from the first and second sensor units into a digital signal; A wireless communication unit for wireless communication with an external mobile communication terminal; The amount of exercise and calorie consumption are calculated based on the input information from the key input unit or the personal information input through the wireless communication unit and the sensor value from the rotation speed / speed detection sensor input through the A / D converter, and the body fat sensor A microprocessor for converting a recommended number of skipping ropes based on body fat data (BMI) from the same, and calculating a heart rate based on ECG data (ECG) from the ECG sensor and calculating a maximum number of skipping ropes accordingly; A memory unit for storing data calculated by the microprocessor, user image information input through the key input unit or the wireless communication unit, and sensor data input through the A / D conversion unit; A liquid crystal display for displaying the user selection and data calculated by the microprocessor on a liquid crystal display provided in the handle under the control of the microprocessor; An LED driver for blinking each of the LEDs for displaying information by the afterimage effect when the jump rope is rotated by the control of the microprocessor; And a motor driving unit which drives the vibration motor under the control of the microprocessor and transmits a signal through a user's handle while using the skipping rope.

Exercise management method using a jump rope skipping biological information to achieve another object of the present invention obtains the bio signal and the skipping rope rotation speed from the sensor unit mounted on both handles (101a) (101b) of the jump rope, the user Exercise management method using exercise rope skipping after calculating the amount of exercise according to the state of health of the patient and obtaining biometric information indicating the amount of exercise by using the afterimage effect of each LED (LED1 ~ LED4) flashing in the rope skipping line during exercise In the above, when a test mode for checking the exercise amount suitable for oneself is selected from the key input unit 211 provided in the first handle 101a of the rope skipping, the heart rate before the rope skipping exercise is measured, the heart rate and the current rope skipping after the rope skipping exercise. A test procedure of setting the number of times to the maximum number of skipping ropes; A recommended number calculation step of calculating a recommended number of times of 70 to 80% of the maximum number of skipping ropes calculated in the test process as the exercise mode is selected from the key input unit 211 provided in the first handle 101a of the skipping rope; A motion information acquisition process of receiving a jump rope rotation speed and a rotation speed from the rotation speed and the speed sensor as the jump rope movement is started; An exercise information display process of displaying a recommended number of times, a skipping number of revolutions, a recommended number of times and a break time guide message through the afterimage effect of the LEDs (LED1 to LED4) provided in the rope skipping line as the rope skipping exercise starts; And if the signal is not input from the rotational speed and the speed sensor, characterized in that the end of the exercise for storing the current jump rope number.

Here, the test process is a step 1 to measure the pre-exercise heart rate through the ECG sensor; Inputting the rotation speed from the rotation speed / speed detection sensor together with the rope skipping motion; Determining that the exercise stops if there is no rotational speed, storing the current rotational speed, and then measuring the current heart rate through an ECG sensor; Setting and storing the current heart rate as the maximum heart rate; And five steps of setting and storing the current number of times as the maximum number of skipping ropes. In the second step, the skipping exercise of the user is characterized in that the user performs the maximum amount of exercise possible.

Exercise management skipping rope through the biological information acquisition according to the present invention and the exercise management method using the same display the information acquired through the biometric information acquisition sensor and the rotational speed / speed sensor built into the rope skipping handle, using the present to the user By displaying the state of health and the number of skipping rope, the user can perform the exercise according to his or her health.

In addition, since the amount of exercise or calorie consumption is calculated and displayed to the user using biometric information and the number of rotations obtained after the skipping exercise, there is an effect of confirming the amount of exercise of the user.

In addition, according to the health status of the user, the maximum number of skipping rope is calculated and displayed every time, daily, weekly, monthly, so that the user can manage the amount of exercise according to the schedule.

In addition, the present invention transfers count information through the virtual screen by the LED driving during exercise, such as the recommended number of skipping rope, the maximum number of jumps or the number of skipping rope according to the calculated health state, so that the user can easily check the exercise state while exercising It can work.

In addition, the present invention transfers the breath (inhale, exhale, stop breathing) signal, etc. to the user during the rope skipping movement by embedding the vibration motor in the rope skipping handle through the period and time control of the motor vibration, so that the user recognizes simple information during exercise It can work.

1 is a block diagram of a jumping rope type portable treadmill having a virtual screen using an optical illusion according to the prior art,
2 is a block diagram of a jump rope skipping exercise management according to the present invention;
3 is a block diagram of a rope skipping exercise management through biometric information acquisition according to an embodiment of the present invention,
4 is a flowchart of an exercise management process using exercise management rope skipping through biometric information acquisition according to an embodiment of the present invention.

With reference to the accompanying drawings, the specific configuration and operation of the exercise management rope skipping through biometric information acquisition according to an embodiment of the present invention will be described in detail as follows.

2 is a block diagram of a jump rope skipping exercise management according to an embodiment of the present invention, the first and second handles 101a and 101b, and the first and second handles 101a and 101b. It consists of a line 102 to connect.

The first handle 101a includes a key input unit 211 for selecting a user's body information and a user's function, and a first sensor unit 110 provided at each handle to measure biometric information by contacting a user's palm. And store the user's body information and function selection information input through the key input unit 211 and the biometric information detected by the first sensor unit 120, and based on the input user body information and biometric information. A controller 200 that calculates the recommended number of skipping ropes and the amount of exercise and outputs it as display data, and a liquid crystal display 221 which displays display data including user body information and function selection information under control of the controller 200; The vibration motor 222a transmits a vibration signal to the user's palm under the control of the controller 200.

The second handle 101b includes a second sensor unit 120 for allowing a user to detect a biosignal in response to a biosignal detected by contacting the first sensor unit 110 of the first handle 101a. It is composed of a vibration motor 222b for driving together with the vibration motor 222a of the first handle portion 101a under the control of the controller 200 to transmit a vibration signal to the user.

The rope skipping rope 102 has a built-in power and data lines for power and data transmission of both handles 101a and 101b, and is supplied with power through the power line, and the rope skipping rope 102 is rotated. There are a number of LEDs (LED 1 ~ N) that are blinking so that text or images can be displayed as afterimage effects.

Here, the key input unit 211, the liquid crystal display unit 221, the controller 200, and the power supply unit 212 are embedded in one of the two handles 101a and 101b, and the sensor unit 110 and 120. And the vibration motors (222a, 222b) are to be embedded in each of the two handles (101a, 101b), it is possible to add a weight (not shown in the figure) therein for the weight balance of both handles.

3 is a block diagram of the exercise management skipping rope through biometric information acquisition according to an embodiment of the present invention. Referring to this, the sensor units 110 and 120 and the controller 200 will be described in more detail as follows. .

The first sensor unit 110 performs an electrocardiogram sensor (111) for measuring ECG, a skin electrical resistance sensor (112) for measuring skin electrical resistance (GSR) of the palm, and a skin temperature (SKT) measurement. Skin temperature sensor 113, the body fat sensor (BMI) for measuring the body fat 114, and the number of times skipping speed and speed / speed sensor 115 for detecting the speed.

The second sensor unit 120 includes an electrocardiogram sensor 121 and a body fat sensor 124 constituting different electrodes from the ECG sensor 111 and the body fat sensor 114 of the first sensor unit 110.

Meanwhile, the power supply unit 212 may use a general battery or a rechargeable battery, and a power generation unit (not shown) may be connected to the first or second handle portions 101a and 101b and the rope skipping rope 102. In addition, when the user rotates the rope jump rope, it is possible to add the charging unit 213 for charging the battery built in the power supply unit 212 with the power generated by the rotational force.

In addition, the controller 200 includes an A / D converter 201 for converting each signal input from the first and second sensor units 110 and 120 into a digital signal, and an external mobile communication terminal 100. A wireless communication unit 202 for wireless communication with the mobile terminal, input information from the key input unit 211 or personal information input through the wireless communication unit 202 and the rotation input through the A / D conversion unit 201. Calculate the amount of exercise and calorie consumption by the sensor value from the water / speed sensor 115, converts the recommended number of skipping ropes based on the body fat data (BMI) from the body fat sensor 114, the ECG sensor 111 A microprocessor 203 for calculating a heart rate from the ECG data from Equation (ECG) and calculating a maximum number of skipping ropes, data calculated by the microprocessor 203 and the key input unit 211 or a wireless communication unit. User profile input via 202 The user selects the memory unit 204 for storing sensor data input through the beam and the A / D conversion unit 201 and the liquid crystal display unit 221 provided in the handle under the control of the microprocessor 203. Liquid crystal display unit 221 for displaying the matters and data calculated by the microprocessor 203, and the respective LEDs for displaying information by the afterimage effect during the skipping rope rotation under the control of the microprocessor 203 (LED 1 LED driver 207 flashing ~ N), and the motor driving unit for driving the vibration motors (222a, 222b) under the control of the microprocessor 203 to transmit a vibration signal through the user's handle during rope skipping use ( 209).

Here, the mobile communication terminal 100 is composed of a smartphone or tablet PC equipped with a health care application, transmits the user's personal information to the wireless communication unit 202 of the controller 200, and stored in the controller 200 It is configured to receive and manage the information or exercise management information via the wireless communication unit 202.

Referring to Figures 2 and 3 attached to the action of the exercise management skipping rope through the biological information acquisition according to an embodiment of the present invention configured as described above are as follows.

First, the present invention registers a user through the key input unit 211 provided in the rope skipping handle 101a as shown in FIG. 2. When the user registers basic user information such as height, weight, age, and gender of the user, the microprocessor 203 of the controller 200 detects this information and displays it on the liquid crystal display 221 and stores it in the memory 204. do.

In another method of inputting personal information, user's personal information stored in the mobile communication terminal 100 shown in FIG. 3 is input through the wireless communication unit 202, or a button of the mobile communication terminal 100 is pressed by a direct input method. The personal information is input through the wireless communication unit 202 and stored in the memory unit 204.

In this way, a plurality of users can be registered by using the key input unit 211 or the mobile communication terminal 100, and the user reads the registered information from the memory unit 204 before starting the exercise with a rope skipping and skipping the rope. Start exercise management according to the exercise.

For exercise management, the user first holds the rope skipping handles 101a and 101b in both hands, and acquires biometric information through the first and second sensor units 110 and 120 to check the health state before exercise.

That is, the electrocardiogram (ECG), skin electrical resistance (GSR), through the ECG sensor 111, 121, skin electrical resistance sensor 112, skin temperature sensor 113, body fat sensor 114, 124 from both hands, Obtain skin temperature (SKT) and body fat (BMI) data.

The biometric information obtained through the first and second sensor units 110 and 120 is input to the A / D converter 201 of the controller 200, converted into digital data, and output to the microprocessor 203. .

The microprocessor 203 may refer to the body fat data input through the A / D converter 201 and the user's personal information (key, weight, age, gender) stored in the memory 204 or not. If the amount of body fat is high, calculate the target body fat amount to be lowered compared to the normal body fat. The target body fat amount is converted into a target calorie consumption to determine how much calories to consume, and the target calorie consumption is again calculated by referring to the calorie consumption consumed per jump rope. The target jump rope count calculated as described above is provided to the user as the recommended number of skipping ropes to lower the user's current normal body fat mass.

The recommended number of skipping ropes calculated through the above process is stored in the memory unit 204, displayed on the liquid crystal display unit 221, and displayed through the LEDs (LED1 to LED4) during the skipping exercise.

In addition, the recommended number of skipping rope skipping once, daily, weekly, monthly, quarterly, annually calculated and displayed accordingly, and provides the user to exercise accordingly, not only store the recommended number of information in the memory unit 204, The mobile communication terminal 100 transmits and stores it.

The body fat is obtained through the body fat sensor 114 and 124 even after exercise, and displays the amount of body fat reduction through the liquid crystal display unit 221 as compared with the body fat measured before exercise, thereby allowing the user to numerically determine the effect of skipping exercise. Make sure to check.

In addition, the microprocessor 203 sets the maximum heart rate so that the user does not exercise excessively due to the increase in heart rate during the rope skipping exercise, and calculates the maximum number of rope skipping so as not to exceed the maximum heart rate.

 Here, the maximum heart rate is different for each person, but according to the maximum heart rate calculation method of a general person using the personal information (key, weight, age, gender) input at the time of user registration as shown in Equation 1 below.

The microprocessor 203 is the rotational speed / speed sensor 115 when the user's heart rate obtained from the electrocardiogram sensors 111 and 121 during the exercise becomes the maximum heart rate of the user calculated by Equation 1 The number of skipping ropes obtained through) is determined as the maximum number of skipping ropes, and the alarm is alerted using the vibration motors 222a and 222b or LEDs (LED1 to LED4) afterimage effects.

The microprocessor 203 stores the calculated maximum number of skipping ropes and calorie consumption at this time in the memory unit 204, and drives the liquid crystal display unit 221 or LEDs (LED1 to LED4) during exercise to use an afterimage effect. Display as text or image.

On the other hand, the microprocessor 203 checks the heart rate from time to time before exercise, during exercise or after the exercise through the ECG sensor 111, 121, when the maximum heart rate is reached, the vibration motor 222a (222b) ) Or LED (LED1 ~ LED4) alarm using afterimage effect.

In addition, the microprocessor 203 guides the user to adjust the respiration rate when he / she wants to change the exercise load according to the user's selection.

That is, when exercising while controlling the respiratory rate, the exercise load increases and the time to reach the maximum heart rate is shortened by using the principle that the user's respiratory rate during exercise is the vibration motor (222a) (222b) or LED (LED1 ~ LED4) It displays by using afterimage effect by driving.

If the user selects the exercise load according to the respiratory rate through the key input unit 211 and selects a set level such as high, medium, or low, the microprocessor 203 selects the respiratory rate corresponding to the exercise load selected by the user. By calculating, the user is to pass the exhalation, inhalation, breathing cycle during exercise through the vibration motor (222a) (222b) or LED (LED1 ~ LED4).

That is, in the case of the vibration motors (222a) and 222b, when the user exhales, exhales, and stops breathing according to the vibration cycle, the user is vibrated transmitted to the palm by driving the vibration motors (222a) and (222b) during exercise. Exhales, inhales, and breathing stops according to the signal.

Here, the user's respiratory rate control signal may be transmitted in various forms, such as vibration intensity of the vibration motors 222a and 222b, as well as vibration intensity and vibration patterns.

On the other hand, the vibration motors (222a, 222b), as well as the respiratory rate control signal, instructs the amount of exercise using the vibration intensity, vibration period, vibration pattern, and the like, the rope skipping recommended number of times or target number completion notification, maximum heart rate notification function Do this.

When the number of revolutions inputted from the revolution / speed sensor 115 reaches the set recommended number or maximum number, the microprocessor 203 may output the vibration motors 222a and 222b or LEDs (LED1 to LED4). ), And the completion data is stored in the memory unit 204 and transmitted to the mobile communication terminal 100 through the wireless communication unit 202 to use as exercise management data.

If the skipping of the jump rope is not performed without the recommended number of jumps or the maximum number of jumps, the microprocessor 203 stores the skipping count at the time when the jump rope is input from the rotation speed / speed sensor 115. Stored in the unit 204 or transmitted to the mobile communication terminal 100 through the wireless communication unit 202 to use as exercise management data.

On the other hand, the microprocessor 203 receives the jump rope rotation speed obtained by the rotation speed / speed sensor 115, and adjusts the flashing period of the LED (LED1 ~ LED4) according to the rotation speed, afterimage jump, Make information displayed by effects more clearly.

The exercise management data calculated by the microprocessor 203 or the mobile communication terminal 100 calculates a change amount of health information such as an amount of exercise and a change in body fat for a predetermined period for each day, week, month, quarter, and year, thereby calculating the statistics. The display window of the terminal 100 or the afterimage effect of the LED (LED1 ~ LED4) can be displayed.

4 is a flowchart of an exercise management process using a jump rope for exercise management through biometric information acquisition according to an embodiment of the present invention. First, a mobile communication terminal 100 or a jump rope handle for managing a jump rope movement in conjunction with a jump rope before using the jump rope. User identification information is input through the key input unit 211 provided in the 101a and 101b, and the input user information is stored in the memory unit 204 through the microprocessor 203.

In order to manage the skipping exercise of the user, first, it is necessary to calculate the recommended number of exercise and the number of repetition sets.

In other words, the proper amount of exercise using rope skipping depends on various variables such as the user's age, gender, and health condition, and thus it is not easy to calculate the appropriate amount of exercise of the user.

Therefore, the recommended number of skipping rope calculates the maximum heart rate of the user through the test exercise mode before the exercise and calculates the recommended number of skipping rope from the maximum number of skipping performed at this time, and calculates the total amount of calories to be consumed from the user's personal information and body fat information. After that, there is a method of calculating the total number of skipping ropes to be performed to burn calories.

First, as shown in FIG. 4, the method for calculating the recommended number of rope skipping through the test exercise mode measures the user's heart rate before starting the exercise, and calculates the heart rate and the number of skipping turns when the user jumps as much as possible. Set the maximum amount of exercise, and the recommended number of skipping rope is about 70-80% of the calculated maximum amount of exercise, and set the recommended number of times and sets the number of times to guide the user to the set number of times and sets during the skipping exercise .

In more detail, when the user selects the test mode through the key input unit 211 or the mobile communication terminal 100 provided in the rope skipping handle (S103), the ECG sensors 111 and 121 provided in both rope skipping handles. Receives an ECG signal through, obtains a pre-exercise heart rate, and starts a skipping exercise. (S105) (S107)

Simultaneously with the skipping rope movement, the rotation speed / speed detection sensor 115 receives the rotation speed to drive the LEDs (LEDs 1 to N) to display the count number as an afterimage effect of the LED. (S111)

If the user stops skipping because he thinks that his / her maximum exercise amount, the heart rate at this time is measured and set and stored as the user's maximum heart rate. (S113 to S117)

At this time, the number of jump ropes acquired is set and stored as the maximum number of jump ropes (S119).

In this way, the recommended number of times is calculated from the maximum number of skipping ropes calculated through the test process, and the recommended number is set to about 70-80% of the calculated maximum number of skipping ropes as the recommended number of times.

In another embodiment of the test process, the user sets the number of rotations performed at the maximum speed for 1 minute to the maximum number of times, and the recommended frequency is set to the recommended frequency of 1 minute to 70 to 80% of the maximum number of times.

On the other hand, as another embodiment of the calculation of the recommended number of skipping ropes will be described in detail how to calculate based on the user's personal information and body fat information input before exercise.

To calculate the user's obesity through the user's height, weight, gender and body fat (BMI) calculated through the body fat sensor 114, 124, and lower the calculated obesity to normal weight. Convert calorie information to consume.

The converted calorie information calculates the recommended number of times by referring to the amount of calories burned per one jump rope. That is, the recommended number of skipping ropes is calculated by the following equation (2) which divides the amount of calories consumed per revolution of the rope skipping to the target calorie consumption to be lowered to normal weight.

Here, the recommended number of times to set the recommended number of rotations and the number of sets at the time of exercise to guide the exercise to divide the total recommended number of times in one or two or more sets during the actual rope skipping exercise can be more effective exercise.

The recommended number of sets may be the same or set to increase the recommended number as the number of sets increases.

In addition, it is possible to set to gradually increase the recommended number of times per day / week / month.

That is, as shown in Table 1 below, if five sets of 120 times were performed in the first week (7 days), five sets of 180 times or more in the next two weeks and five sets of 240 times or more in the next week, the first recommended number of times Increase the amount of exercise by increasing by about 120%.

Main unit Recommended frequency (minutes) rest Number of sets 1 parking 120 times (1 minute) 2 minutes 5 sets 2 parking 180 times (1 minute 30 seconds) 1 minute 30 seconds 6 sets 3 parking 240 times (2 minutes) 1 minute 7 sets 4 parking 320 times (2 minutes 30 seconds) 1 minute 8 sets

The recommended number of skipping ropes, established as the number of revolutions and the set number of times calculated in this manner, is counted to the user in the exercise mode and displayed using the LED afterimage effect.

That is, in the exercise mode (S121), as shown in Figure 4, when the user starts the exercise, and displays the recommended number of settings and stored as the afterimage effect by driving the LED (LED 1 ~ N) (S125 ~ S127).

At this time, the controller 200 receives the rotational speed from the rotational speed / speed sensor 115 and displays the number of rotations and the current set count as an afterimage effect by driving the LED (S129) (S131).

When the user completes the set recommended number of times, this is displayed, and the rest time (1-2 minutes) is displayed. (S135)

If the user continues without stopping the movement, the number of revolutions inputted through the rotation speed / speed sensor 115 is counted and displayed as text. (S137)

When the user stops the exercise, the set key is selected, or the set time elapses while the exercise is stopped, it is determined that the current set ends, and the current jump rope count and the current set number are stored. (S139) (S141)

At this time, when the heart rate measurement key is input through the key input unit 211, the current heart rate is calculated and stored from the ECG signals of the ECG sensors 111 and 121 (S143).

When the user starts the next set exercise again, the process returns to step S125 displaying the current set and the recommended number of times to complete the recommended number of times.

The steps (S125 to S145) are repeated from the first set to the final set of the exercise start, and if the current set is the last set of the set recommended number of times, the afterimage effect with the number of jump rope counts before the start or the end of the exercise. (S147) (S149)

The heart rate is measured from an electrocardiogram signal periodically measured by the ECG sensors 111 and 121 during the skipping rope movement, and when it is determined as the maximum risk of heart rate, it is displayed as an LED afterimage effect.

100: mobile communication terminal 101a, 101b: rope skipping handle
102: rope skipping rope 110,120: first, second sensor
111,121 ECG sensor 112: skin electrical resistance sensor
113: skin temperature sensor 114,124 body fat sensor
115: speed / speed detection sensor
200: controller 201: A / D converter
202: wireless communication unit 203: microprocessor
204: memory unit 207: LED driver
208 LCD driver 209 Motor driver
211: key input unit 212: power supply unit
221 LCD 222a, 222b Vibration motor

Claims (19)

Analyze the user's biometric information acquisition and health state using the exercise rope skipping rope connected with the first and second handles 101a and 101b, and display the analyzed health state, and the amount of exercise according to the health state. In the rope skipping exercise management through obtaining the biometric information to calculate the display,
The first and second handles 101a and 101b may include a key input unit 211 for selecting a user's body information and a user's function;
Electrocardiogram sensor 111 for measuring ECG in contact with the palm of the user, skin electrical resistance sensor 112 for measuring skin electrical resistance (GSR) of the palm, and skin temperature for skin temperature (SKT) measurement A first sensor unit 110 comprising a sensor 113, a body fat sensor 114 for measuring body fat (BMI), and a rotation speed / speed detection sensor 115 for detecting the number of skipping ropes and the speed of skipping a rope;
The ECG sensor 121 and the body fat sensor 124 provided on the handle different from the first sensor unit 110 to form different electrodes from the ECG sensor 111 and the body fat sensor 114 of the first sensor unit 110. The second sensor unit 120 including;
The user body information and function selection information input through the key input unit 211 and the biometric information detected by the sensor unit 110 and 120 are stored in the memory unit 204, and the input user body information and biometric information are stored. A controller 200 for calculating a user's recommended number of skipping ropes, exercise amount, and breathing information based on the output, and outputting the same as display data;
A liquid crystal display 221 provided on the handle to display display data including user body information and function selection information under control of the controller 200; And
And a vibration motor 222a and 222b for transmitting a vibration signal to the palm of the user under the control of the controller 200.
The rope skipping rope 102 is flashed under the control of the controller 200 and the power supplied from the handles 101a and 101b so that a plurality of characters or images are displayed as an afterimage effect when the rope skipping rope 102 rotates. Built-in LED (LED 1 ~ N),
The controller 200 includes an A / D converter 201 for converting each signal input from the first and second sensor units 110 and 120 into a digital signal;
A wireless communication unit 202 for wireless communication with an external mobile communication terminal 100;
Input information from the key input unit 211 or image information input through the wireless communication unit 202 and the sensor value from the rotation speed / speed sensor 115 input through the A / D conversion unit 201 Calculates the amount of exercise and calorie consumption, converts the recommended number of rope skipping based on the body fat data (BMI) from the body fat sensor 114, calculates the maximum heart rate using the input personal information, and the ECG sensor A microprocessor 203 for determining the maximum number of rope skipping times during which the heart rate during exercise obtained from (111) 121 is reached to the calculated maximum heart rate;
Data stored by the microprocessor 203 and user identification information input through the key input unit 211 or the wireless communication unit 202 and sensor data input through the A / D conversion unit 201 are stored. A memory unit 204;
An LCD driver 208 for displaying the user selection and data calculated through the microprocessor 203 on the liquid crystal display 221 provided in the handle under the control of the microprocessor 203;
An LED driver (207) for blinking each of the LEDs (LEDs 1 to N) for displaying information by the afterimage effect when the skipping rope is rotated by the control of the microprocessor (203); And
And a motor driver 209 for driving the vibration motors 222a and 222b under the control of the microprocessor 203 to transmit a vibration signal through a user's handle during rope skipping. Exercise management rope skipping through information acquisition. The method of claim 1,
The key input unit 211, the liquid crystal display unit 221, the controller 200, and the power supply unit 212 are embedded in one of the two handles 101a and 101b.
The sensor unit 110, 120 and the vibration motor (222a) (222b) is a rope skipping rope for exercise management by acquiring biological information, characterized in that each of the two handles (101a, 101b) is provided. delete The method of claim 1,
A power supply unit supplying power to the first and second sensor units 110 and 120, the controller 200, the liquid crystal display unit 221, the vibration motors 222a and 222b, and LEDs 1 to N; 212 is distributed in the first or second handle portion (101a) (101b),
The first and second sensor units 110 and 120 and the vibration motors 222a and 222b are disposed in the first and second handles 101a and 101b, respectively. Exercise rope skipping. 5. The method of claim 4,
The power supply unit 212 is a charging unit 213 for charging the battery built in the power supply unit 212 by the rotational force of the first or second handle portion (101a, 101b) when the user rotates the rope jump rope Exercise management rope skipping through the acquisition of biological information, characterized in that further comprises a. delete The method of claim 1,
The microprocessor 203 is the LED driver 207 or the motor driver to recognize the inhalation, exhalation and breathing stop timing during the jump rope use through the LED (LED 1 ~ N) or the vibration motor (222a, 222b) Exercise management rope skipping by obtaining biometric information, characterized in that for controlling (209). The method of claim 7, wherein
The microprocessor 203 is the exercise management jump rope skipping biological information, characterized in that for displaying the inhalation, exhalation, breathing stop signal as the vibration period and the vibration holding time of each vibration motor (222a) (222b). The method of claim 1,
The microprocessor 203 transmits rope skipping exercise management and biometric information stored in the memory unit 204 through the wireless communication unit 202 to the mobile communication terminal 100 through the wireless communication unit 202. Exercise rope skipping through the acquisition of biometric information. The method of claim 1,
The microprocessor 203 analyzes the biometric information and the number of rotations input from the first and second sensor units 110 and 120 after the exercise is finished, and converts the current heart rate, total exercise amount and calorie consumption into the memory. In addition to storing in the unit 204, the exercise management rope skipping through the biological information acquisition, characterized in that displayed on the liquid crystal display 221. The method of claim 1,
The microprocessor 203 calculates a skipping rope count in units of months, weeks, and days, and stores the memory in the memory unit 204 and displays it through the liquid crystal display unit 221. Jump Rope. After acquiring the bio signal and the number of skipping ropes from the sensor units mounted on both handles 101a and 101b of the rope skipping, calculating the amount of exercise suitable for the user's health state, and using each of the LEDs (LED1 ~ In the exercise management method using the rope skipping exercise management through the acquisition of biometric information indicating the amount of exercise using the afterimage effect of the LED4),
When the test mode for checking the exercise amount suitable for oneself is selected from the key input unit 211 provided in the first handle 101a of the rope skipping, the heart rate before the rope skipping exercise is measured, and the current heart rate and the current rope skipping count after the rope skipping exercise are measured. A test procedure for setting the maximum heart rate and the maximum number of skipping ropes respectively;
A recommended number calculation step of calculating a recommended number of times of 70 to 80% of the maximum number of skipping ropes calculated in the test process as the exercise mode is selected from the key input unit 211 provided in the first handle 101a of the skipping rope;
A motion information acquisition process of receiving a jump rope rotation speed and a rotation speed from the rotation speed and the speed sensor as the jump rope movement is started;
An exercise information display process of displaying a recommended number of times, a skipping number of revolutions, a recommended number of times and a break time guide message through the afterimage effect of the LEDs (LED1 to LED4) provided in the rope skipping line as the rope skipping exercise starts; And
If the signal is not input from the rotational speed and the speed sensor, the end of the exercise for storing the current number of skipping rope; including;
The test process is a step 1 to measure the pre-exercise heart rate through the ECG sensor;
Inputting the rotation speed from the rotation speed / speed detection sensor together with the rope skipping motion;
Determining that the exercise stops if there is no rotational speed, storing the current rotational speed, and then measuring the current heart rate through an ECG sensor;
Setting and storing the current heart rate as the maximum heart rate; And
And setting and storing the current rotation speed as the maximum number of skipping times.
In the step 2, the skipping exercise of the user is an exercise management method using the exercise management rope skipping by obtaining the biometric information, characterized in that the user performs the maximum amount of exercise possible. delete 13. The method of claim 12,
In step 2, if the heart rate acquired by the ECG sensor during the skipping exercise is determined to be a set risk heart rate, the user is displayed, the current heart rate is set as the maximum heart rate, and the step of setting the rope skipping number as the maximum rope skipping count is performed. Exercise management method using a rope skipping exercise management through the acquisition of biological information, characterized in that further comprises. After acquiring the bio signal and the number of skipping ropes from the sensor units mounted on both handles 101a and 101b of the rope skipping, calculating the amount of exercise suitable for the user's health state, and using each of the LEDs (LED1 ~ In the exercise management method using the rope skipping exercise management through the acquisition of biometric information indicating the amount of exercise using the afterimage effect of the LED4),
When the test mode for checking the exercise amount suitable for oneself is selected from the key input unit 211 provided in the first handle 101a of the rope skipping, the heart rate before the rope skipping exercise is measured, and the current heart rate and the current rope skipping count after the rope skipping exercise are measured. A test procedure for setting the maximum heart rate and the maximum number of skipping ropes respectively;
A recommended number calculation step of calculating a recommended number of times of 70 to 80% of the maximum number of skipping ropes calculated in the test process as the exercise mode is selected from the key input unit 211 provided in the first handle 101a of the skipping rope;
A motion information acquisition process of receiving a jump rope rotation speed and a rotation speed from the rotation speed and the speed sensor as the jump rope movement is started;
An exercise information display process of displaying a recommended number of times, a skipping number of revolutions, a recommended number of times and a break time guide message through the afterimage effect of the LEDs (LED1 to LED4) provided in the rope skipping line as the rope skipping exercise starts; And
If the signal is not input from the rotational speed and the speed sensor, the end of the exercise for storing the current number of skipping rope; including;
The recommended number calculation process is calculated by the recommended number and the set number, each set to the same or different recommended number of times,
The set number of the exercise management method using the exercise management rope skipping through the biological information acquisition, characterized in that the counting the set in the exercise stop mode for a set time, or when the set confirmation key is input. The method of claim 15,
The recommended number of times calculation process of the exercise management method using the rope skipping exercise management by obtaining biometric information, characterized in that the recommended number of each set is gradually increased by 120 ~ 150% of the initial recommended number of days, weeks or months . delete Calculate the amount of body fat from the body fat sensor provided in the rope skipping handle before skipping rope, obtain the number of revolutions in the rope skipping exercise, and use the afterimage effect by blinking each LED (LED1 ~ LED4) built in the rope skipping rope during exercise And in the exercise management method using the exercise management rope skipping through the acquisition of biometric information to display the exercise information,
Calculating a target calorie consumption amount according to the user's body fat and converting the exercise amount according to the calculated target calorie amount into a recommended number of skipping ropes;
A motion information acquisition process of receiving a jump rope rotation speed and a rotation speed from the rotation speed and the speed sensor as the jump rope movement is started;
An exercise information display process of displaying a recommended number of times, a skipping number of revolutions, a recommended number of times and a break time guide message through the afterimage effect of the LEDs (LED1 to LED4) provided in the rope skipping line as the rope skipping exercise starts; And
If the signal is not input from the rotational speed and the speed sensor, the end of the exercise for storing the current number of skipping rope; including;
The calculating of the recommended number of times includes calculating a user's obesity rate through a user's height, weight, gender, and body fat (BMI) calculated by the body fat sensor, which is input before the user skips a rope;
Converting the calculated obesity degree into a target calorie amount to be consumed to lower the normal weight; And
Calculating the number of revolutions of the rope skipping calculated by dividing the converted target calorie amount and the amount of calories consumed per one revolution of the rope skipping as the recommended number of times; How to manage. delete

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