KR102053576B1 - Apparatus and system for tracking weight - Google Patents

Abstract

According to the present invention, a weight tracking device containing a plurality of weight plates having NFC tags attached thereto sets a weight of a weight stack by inserting a pin between pinholes formed at any one weight plate among the weight plates or between weight plates neighboring vertically among the weight plates, and traces a weight of the weight stack. The device comprises: a housing; a pin which protrudes from the housing and is inserted between pinholes or weight plates neighboring weight plates vertically; an NFC reading module which is placed inside the housing, reads an NFC tag sensed when the pin is inserted and senses weight data indicating a weight of a weight stack set by the pin; a memory which is placed inside the housing; and a processor which is placed inside the housing. The processor receives the weight data sensed by the NFC reading module from the NFC reading module and stores the weight data in the memory.

Description

Weight tracking device and method {APPARATUS AND SYSTEM FOR TRACKING WEIGHT}

The present invention is a weight tracking device and method, and more specifically, has a NFC reading module to track the weight of the weight stack to be lifted by the user by reading the NFC tag attached to the weight plate of the weight lifting machine, the weight A weight tracking device for allowing information to be utilized for various purposes.

The fitness tech market, which combines exercise and IT technology, is growing worldwide. For example, in the case of aerobic exercise, such as running or cycling, use your smartphone or smartwatch to automatically track your workout history, such as travel route, travel speed, and exercise time, based on collected data. A variety of personalized fitness is provided.

However, in the case of weight training, there is no system or service that can automatically track the workout. In the case of weight training, the exercise details such as which exercise equipment, which body parts were exercised, how many kilograms of weight, how many times the exercise was repeated, and how many sets were exercised are important factors. No system or service can automatically track these elements (see Korean Patent Publication No. 10-2011-0066432).

Hereinafter, a background art for describing a weight tracking device according to the present invention will be described.

1 is a view showing a conventional weight lifting machine and weight setting pins used therein. 2 is a view showing various weight setting pins used in a conventional weight lifting machine.

Referring to FIG. 1, a weight lifting machine 70 is an exercise device that strengthens muscle strength by lifting a weight plate 20 having a predetermined weight in a vertical direction.

A plurality of weight plates 20 and 22 may be superimposed on the weight lifting machine 70. Each weight plate 20, 22 may have a predetermined weight (eg, 5 kg). In some embodiments, each weight plate may have the same weight, or may have different weights. Weight indicator stickers 33 and 34 may be attached to each weight plate 20 and 22.

For example, a weight indicator sticker 33 containing 5 kg may be attached to the top weight plate 20 of the overlapped weight plates, and 10 kg, which is the weight of two weight plates, may be attached to the weight plate 22 immediately below. Weight indicator sticker 34 may be attached. In other words, a weight indicator sticker may be attached to one weight plate describing the cumulative weight from the top.

The user may set the weight of the weight stack or the number of weight plates 20 and 22 that the user wants to lift using the weight selector pin 15. The weight stack 30 refers to a mass of a predetermined number of weight plates set by the weight setting pin 15.

Specifically, by inserting the weight setting pins 15 between the weight plates 20 and 22 adjacent to each other up and down among the plurality of weight plates 20 and 22, the number of weight plates 20 and 22 or the weight of the weight stack to be lifted by Can be set. Alternatively, by inserting the weight setting pin into the pinhole formed in any one of the weight plates, the number of weight plates or weight of the weight stack can be set.

Referring to FIG. 2, the shape of the weight setting pins 35 and 37 used to set the weight of the weight stack 30 may vary.

The weight setting pin may be configured as a part of a head and a pin. The shape of the head part and the pin part may be various. For example, the weight setting pin 35 according to an embodiment may be composed of one rod-shaped pin and the head portion located at the end of the pin (see FIG. 2 (a)), and according to another embodiment The pin 37 may be in the form of two flat pins (see FIG. 2B).

According to the embodiment, the weight setting pin 35 having one rod shape may be set in the weight of the weight stack by being inserted into the pinhole formed in the weight plate, and the weight setting pin 37 having two flat pins The weight of the weight stack 30 can be set by being inserted between the weight plates 20 and 22 adjacent to each other up and down.

In order to solve this problem, the weight tracking device that automatically tracks and processes the exercise history of the weight training exercise, and provides the generated information using IoT technology to accurately measure and analyze the user's strength exercise Necessity is emerging.

The problem to be solved by the present invention, by obtaining the weight information of the weight stack by using the NFC technology it is possible to know the exact weight of the weight stack used by the user when weight training.

Problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

Weight tracking device according to an embodiment of the present invention for solving the above problems, with respect to the weight lifting machine including a plurality of weight plates each attached NFC tag, formed on any one of the plurality of weight plate A weight tracking device that sets a weight of a weight stack by inserting it between a pinhole or a plurality of weight plates that are adjacent to a weight plate, and tracks the weight of the weight stack. The pin is inserted between the weight plate, the NFC reading module disposed inside the housing, the NFC reading module for detecting the weight data indicating the weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of the pin, housing Memory disposed in the interior of the, and disposed in the housing Includes a processor, and the processor, upon receiving the weight data is detected NFC reading module from the NFC reading module, and stores the weight data in memory.

Weight tracking device according to another embodiment of the present invention for solving the above problems, with respect to the weight lifting machine including a plurality of weight plates each attached NFC tag, formed on any one of the plurality of weight plate A weight tracking device for tracking the weight of a weight stack, which is set by inserting a weight setting pin between a pinhole or a plurality of weight plates up and down adjacent weight plates, the weight tracking device being disposed inside the housing, the housing detachable to the weight setting pin, NFC reading module for reading weight data indicating the weight of the weight stack set by the weight setting pin by reading the NFC tag detected after the insertion or completion of the weight setting pin, the memory disposed inside the housing, and the interior of the housing A processor disposed on the processor, the NFC reading Receives the weight data detected by the NFC reading module from the module, and stores the weight data in the memory.

According to the present invention, by obtaining the weight information of the weight stack using the NFC technology it is possible to know the exact weight of the weight stack used by the user when weight training.

1 is a view showing a conventional weight lifting machine and weight setting pins used therein.
2 is a view showing various weight setting pins used in a conventional weight lifting machine.
3 and 4 are views showing a state in which the weight tracking device according to an embodiment of the present invention is applied to the weight lifting machine.
5 is a perspective view of a weight tracking device according to an embodiment of the present invention.
6 is a block diagram of a weight tracking device according to an embodiment of the present invention.
7 is a view showing a state in which the NFC reading module installed in the weight tracking device according to an embodiment of the present invention communicates with a plurality of NFC tags.
8 is a view showing the installation position of the NFC reading module in the weight tracking device according to an embodiment of the present invention.
9 is a view showing the installation position of the metal plate in the weight tracking device according to an embodiment of the present invention.
FIG. 10 is a diagram of an NFC reading module installed in a weight tracking device according to an embodiment of the present invention to derive weight data of a weight stack actually lifted by a user from weight data read from an NFC tag while alternately maintaining a sleep mode and an active mode; Figure showing the process.
11 is a view showing an installation position of the acceleration sensor in the weight tracking device according to an embodiment of the present invention.
12 is a diagram illustrating a method for an NFC reading module installed in a weight tracking device to communicate with one NFC tag using an acceleration sensor according to an embodiment of the present invention.
13 and 14 illustrate a signal processing method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.
15 and 16 illustrate a first machine learning method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.
17 and 18 are diagrams illustrating a second machine learning method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.
FIG. 19 illustrates position data of a weight tracking device finally produced by using acceleration data input by a processor installed in the weight tracking device according to an embodiment of the present invention.
20 is a perspective view of a weight tracking device according to another embodiment of the present invention.
21 is a view showing a state in which the weight tracking device is mounted on the weight setting pin according to another embodiment of the present invention.
22 is a flowchart illustrating a weight tracking method according to an embodiment of the present invention.
23 is a flowchart illustrating a weight tracking method according to another embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the present embodiments are intended to complete the disclosure of the present invention, and the general knowledge in the art to which the present invention pertains. It is provided to fully convey the scope of the invention to those skilled in the art, and the present invention is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the words "comprises" and / or "comprising" do not exclude the presence or addition of one or more other components, steps, and actions.

3 to 6, a weight tracking device according to an embodiment of the present invention will be described. 3 and 4 are views showing a state in which the weight tracking device according to an embodiment of the present invention is applied to the weight lifting machine. 5 is a perspective view of a weight tracking device according to an embodiment of the present invention. 6 is a block diagram of a weight tracking device according to an embodiment of the present invention.

3 to 6, the weight tracking device 60 according to an embodiment of the present invention, the weight by reading the NFC tag 40 attached to the weight plate 20, 25 of the weight lifting machine 70 It may be an apparatus for tracking the weight data of the stack 30.

The weight lifting machine 70 may be provided with a plurality of weight plates 20 and 25, and an NFC tag 40 may be attached to each of the weight plates 20 and 25. At this time, the NFC tag is read by the NFC reading module in the weight setting device when the pin of the weight setting device or the weight setting pin to which the weight setting device is coupled is inserted between the pinhole or the weight plate neighboring the upper and lower sides. And may be attached to be located within the retractable area. According to an embodiment, when inserted, the NFC tag may be attached to the position where the NFC reading module and the NFC tag is superimposed.

The NFC tag 40 may store the total weight data of the weight plates 20 and 25 to which it is attached and the weight plates 20 and 25 superimposed on the weight plates 20 and 25. That is, the NFC tag 40 may have weight data of the weight stack 30 when the weight stack is set such that the weight plate to which the NFC tag 40 is attached is the weight plate located at the bottom. In other words, the NFC tag 40 attached to the n th weight plate from the top may have a weight data that is the sum of the weights of all the weight plates from the first weight plate to the n th weight plate from above.

For example, referring to FIG. 3, when each of the plurality of weight plates has a weight of 5 kg, (i) the NFC tag 40 attached to the uppermost weight plate may have 5 kg of weight data. , (ii) NFC tag 40 attached to the second weight plate from above, may have a weight data of 10kg, which is the sum of the weights of the first weight plate and the second weight plate.

In addition, the NFC tag 40 may provide this weight data to an external device, but may be in the form of a sticker, but is not limited thereto, and various forms may be applied if the NFC tag 40 may be attached to the weight plates 20 and 25.

Again, the weight tracking device 60 according to an embodiment may include a housing 125, a pin 10, an NFC reading module 80, a processor 100, a memory 110, and a communication module 120. Can be.

The housing 125 forms an outer shape of the weight tracking device 60 and may have a space in which various components of the weight tracking device 60 are built.

The pin 10 may be a member protruding from the housing 125 and having a predetermined length. As described above, the fin 10 may be configured to form a weight stack 30 in which the weight plates 20 and 25 overlap, and may have various shapes.

According to an embodiment, as shown in FIG. 3, the pin may consist of two flat shaped plates, and the user may use the pin 10 between the weight plates 20 and 22 neighboring up and down among the plurality of weight plates. ), The weight plates 20 and 22 stacked on the inserted pin 10, that is, the weight stack 30 may be lifted.

Alternatively, as shown in FIG. 4, the pin may have a single rod shape, and the user inserts the pin into the pinhole 45 formed in any one of the weight plates 25, and then the pinhole 45. The weight plate 25 formed on the weight plate 25 and the weight plate 25 on which the pinhole 45 is formed may be lifted, that is, the weight stack.

That is, the pin 10 is inserted between the weight plates 20 and 22 neighboring up and down among the plurality of weight plates 20 or the pinholes formed in any one of the weight plates 25. 45 can be inserted.

As such, the weight stack 30 may be formed by inserting the pin 10 between the pinhole 45 or the weight plates 20 and 22 adjacent to each other.

The NFC reading module 80 is a module disposed inside the housing 125 to read weight data indicating the weight of the weight stack 30 by reading the NFC tag 40.

Specifically, when the pin 10 is inserted, the NFC reading module 80 comes close to the NFC tag 40 attached to the weight plates 20 and 25, and the NFC tag sensed after the proximity process or insertion is completed. By reading 40, the weight data indicating the weight of the weight stack 30 set by the pin 10 may be sensed.

The processor 100 may be disposed in the housing 125 to receive weight data detected by the NFC reading module 80 from the NFC reading module 80. That is, the NFC reading module 80 may transmit the recognized weight data to the processor 100.

In addition, the memory 110 may be disposed in the housing 125, and the processor 100 may store weight data in the memory 110.

Meanwhile, the memory 110 may be inside or outside the processor 100 and may be connected to the processor 100 by various well-known means. The memory 110 is a mass storage medium such as a known semiconductor device or a hard disk which is known to record and erase data such as RAM, ROM, EEPROM, etc., and refers to a device for storing information regardless of the type of device. It does not refer to a particular memory 110 device.

In addition, the interior of the housing 125 may further include a communication module 120 for communicating with an external device. The processor 100 may control the communication module 120 to transmit weight data to an external device. Here, the external device may include a user's mobile phone, a management server, and other terminals.

That is, the weight data may be provided to the outside under the control of the processor 100, and the provided weight data may be processed to provide useful information to the user.

In the following, in order to help the understanding of the present invention, a weight lifting machine in which pins are sandwiched between upper and lower weight plates is described in the above-described types of weight lifting machines (see FIG. 3).

7 to 10, a method of acquiring weight data of the weight stack 30 set by the weight setting pin in the process of the NFC reading module 80 communicating with the NFC tag 40 will be described.

7 is a view showing a state in which the NFC reading module installed in the weight tracking device according to an embodiment of the present invention communicates with a plurality of NFC tags. 8 is a view showing the installation position of the NFC reading module in the weight tracking device according to an embodiment of the present invention. 9 is a view showing the installation position of the metal plate in the weight tracking device according to an embodiment of the present invention.

FIG. 10 is a diagram illustrating weight data of a weight stack set by a weight setting pin among weight data read from an NFC tag while an NFC reading module installed in a weight tracking device alternately maintains a sleep mode and an active mode according to an embodiment of the present invention; A diagram illustrating a process of doing so.

First, referring to FIG. 7, the NFC tags 40 and 43 may be attached to the plurality of weight plates 20, respectively. In the process of inserting the weight tracking device 60, the NFC reading module 80 may itself Communication with other NFC tags 43 in addition to the NFC tag 40 (ie, the NFC tag 40 of the weight plate 20 located directly above the inserted weight tracking device 60). May occur.

In this case, weight recognition by the NFC reading module 80 may not be properly performed, or incorrect weight data may be recognized even if performed, thereby degrading accuracy and reliability of weight recognition.

Referring to FIG. 9, which is a view as seen in the L direction in FIGS. 8 and 8, in consideration of the above-described problem, the NFC reading module 80 may include a front surface 150 of the housing 125 facing the weight stack 30. It may be disposed in the housing 125 while contacting the inner side 155.

Since the NFC reading module 80 communicates with the NFC tag 40 of the weight plate 20, the NFC reading module 80 needs to be disposed to be as close as possible to the NFC tag 40 in the housing 125. In this regard, the NFC reading module 80 may be disposed in the housing 125 while contacting the inner side 155 of the front surface 150 of the housing 125 facing the weight stack 30.

That is, among the components disposed in the housing 125, the NFC reading module 80 may be located closest to the weight stack 30.

Further, according to an embodiment, the NFC reading module 80 may be in contact with the NFC reading module 80 at the inner side 155 of the front surface 150 of the housing 125 such that the NFC reading module 80 communicates with only one NFC tag 40. The metal plate 140 may be attached to the top of the portion.

In some cases, the metal plate 140 may be attached to all parts of the inner side 155 except for the part in contact with the NFC reading module 80. Alternatively, the metal plate 140 may be attached to a portion other than the position of the target NFC tag.

As such, the metal plate 140 is attached to the upper or strategic position of the NFC reading module 80, thereby preventing communication with other NFC tags 43 in addition to the NFC tag 40 intended for communication, so that the NFC reading module 80 is accurate. The weight of the weight stack 30 may be recognized.

According to another embodiment, referring to FIG. 10, the NFC reading module 80 may repeat the sleep mode S and the active mode A. FIG. In this case, the NFC reading module 80 may determine the weight data having the highest frequency among the weight data read in the active mode A as the weight of the weight stack 30.

Specifically, while the user moves the weight tracking device 60 to the weight stack 30, the NFC reading module 80 is in the sleep mode (S) for a predetermined time (for example, 1 second) and then active. After switching to the mode (A), the sleep mode (S) again for a predetermined time, and then to the active mode (A), the sleep mode (S) and the active mode (A) can be repeated.

In this process, the NFC reading module 80 may recognize and read different NFC tags 40 and 43 in the active mode (A), and perform more communication with the nearest NFC tag, thus reading weight The weight of the weight stack 30 to be lifted with the most frequent weight data among the data can be determined.

For example, when the NFC reading module 80 reads 5 kg, 5 kg, 10 kg, and 5 kg as the weight data under the active mode A, since the weight data with the highest frequency among the read weight data is 5 kg, it will be lifted. The weight of the weight stack 30 is determined to be 5 kg, and may transmit information that the weight of the weight stack 30 is 5 kg to the processor 100 to be described later.

According to another embodiment, the size of the NFC tag 40 attached to the weight plate 20 is made smaller than the predetermined size (for example, the width and length of 10 to 15 mm) or less with the NFC tag 40 The communication range can be reduced.

In this case, the NFC reading module 80 may read the NFC tag 40 only when the NFC reading module 80 is close to the NFC tag 40. After the weight tracking device 60 is inserted, the NFC reading module 80 may be closest to the NFC tag 40. Only the NFC tag 40 can be recognized.

Additionally, referring to FIGS. 6 and 11, the weight tracking device 60 according to the embodiment of the present invention may further include an acceleration sensor 90. 11 is a view showing an installation position of the acceleration sensor in the weight tracking device according to an embodiment of the present invention.

The acceleration sensor 90 may be disposed inside the housing 125 and may be a sensor that senses acceleration data indicating an acceleration value of the weight tracking device 60. In some embodiments, the acceleration sensor 90 may be a three-axis acceleration sensor.

That is, the user lifts or lowers the weight stack 30, and in this process, the weight stack 30 also moves up and down, and at the same time, the weight tracking device 60, which is integrated with the weight stack 30, can also move up and down. have.

In this process, the acceleration sensor 90 may sense an acceleration value or an acceleration change of the weight tracking device 60.

Subsequently, the processor 100 receives the acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90 and performs a signal processing on the received acceleration data to indicate the position change of the weight tracking device 60. You can generate data.

In addition, the processor 100 may control the communication module 120 to transmit the location data to an external device, and store the location data in the memory 110.

As described above, the NFC reading module 80 may be disposed while contacting the inner side 155 of the front surface 150 of the housing 125 facing the weight stack 30, wherein the acceleration sensor 90 is It may be located immediately after the NFC reading module 80 with respect to the front surface 150 of the housing 125 (see Fig. 11 (a)). According to another embodiment, the acceleration sensor 90 may be positioned side by side up, down, left, or right of the NFC reading module 80 to be disposed in contact with the inner side 155 of the front surface 150 of the housing 125.

According to another embodiment, the acceleration sensor 90 may be located at the center of the width of the front surface 150 of the housing 125 (see FIG. 11B).

In this regard, after the pin 10 is inserted between the weight plates 20 adjacent up and down among the plurality of weight plates 20, the weight tracking device 60 also moves up and down as the weight stack 30 moves up and down. You can move.

In this case, as the acceleration sensor 90 is located farther from the weight stack 30 based on the length direction of the weight tracking device 60, the acceleration sensor 90 may have a greater degree of vertical swing. Therefore, as the acceleration sensor 90 moves away from the weight stack 30, the accuracy of the measured acceleration value may be lowered.

In addition, based on the width direction of the weight tracking device 60, as the acceleration sensor 90 is positioned farther from the center, the acceleration sensor 90 may swing up and down or left and right. Therefore, as the acceleration sensor 90 moves away from the center of the width, the accuracy of the measured acceleration value may be lowered.

In view of this, the acceleration sensor 90 is positioned next to the NFC reading module 80 with respect to the front face 150 of the housing 125 and also in the center of the width of the front face 150 of the housing 125. Can be located.

Next, with reference to FIG. 12, a method of allowing the NFC reading module 80 to communicate only with the NFC tag 40 of the weight plate 20 located directly above the weight tracking device 60 using the acceleration sensor 90. Take a look.

12 is a diagram illustrating a method for an NFC reading module installed in a weight tracking device to communicate with one NFC tag using an acceleration sensor according to an embodiment of the present invention.

Referring to FIG. 12, in the process of moving for insertion of the weight tracking device 60, the NFC reading module 80 does not read the NFC tag 40, and after the insertion of the weight tracking device 60 is completed, the NFC is completed. The reading module 80 may allow the NFC tag 40 to read.

In other words, when the insertion of the weight tracking device 60 is completed, the NFC reading module 80 may be converted to the active mode A, and is likely to communicate with the nearest NFC tag 40, where The nearest NFC tag 40 may be the NFC tag 40 of the weight plate 20 located directly above the inserted weight tracking device 60.

Therefore, the NFC reading module 80 may read the NFC tag 40 of the weight plate 20 located directly above the inserted weight tracking device 60 to enable accurate weight data recognition by the user.

In this regard, referring to the manner in which the NFC reading module 80 is converted to the active mode A after the insertion of the weight tracking device 60 is completed, the NFC reading module 80 may be inserted in the direction in which the pin 10 is inserted ( When the acceleration value of the axis X parallel to D) becomes equal to or less than a preset reference value, the NFC tag 40 may be read by switching from the sleep mode S to the active mode A. FIG.

That is, when the acceleration value of the axis X parallel to the direction D into which the pin 10 is inserted is equal to or less than a preset reference value, the weight tracking device 60 considers that the insertion is completed and the NFC reading module 80 is in the active mode. It can be converted to (A) to read the nearest NFC tag 40.

Alternatively, the NFC reading module 80 enters the active mode A from the sleep mode S when the acceleration value of two or more axes falls below the reference value among the three-axis acceleration values greater than or equal to the reference value, thereby reading the NFC tag 40. can do.

Specifically, when the user moves the weight tracking device 60 in order to use the weight tracking device 60, a change occurs in the three-axis acceleration value may be more than the reference value.

Subsequently, when the insertion of the weight tracking device 60 is completed, the movement of the weight tracking device 60 decreases, and the acceleration value of two or more axes among the three axis acceleration values may be less than or equal to the reference value. Therefore, when the acceleration value of two or more axes falls below the reference value among the three-axis acceleration values that are greater than or equal to the reference value, the weight tracking device 60 considers the insertion completed and the NFC reading module 80 performs the active mode (A) in the sleep mode (S). May be converted to read the nearest NFC tag 40.

Meanwhile, the reason why the insertion completion time of the weight tracking device 60 is selected as the case where the acceleration value of two or more axes other than three axes is less than or equal to the reference value is that weight training is performed after a certain time after the weight tracking device 60 is inserted. The weight stack 30 may move up and down, but if weight training is performed as soon as the weight tracking device 60 is inserted, and the weight stack 30 moves up and down, one axis (eg, Z-axis) is accelerated. It is considered that the value may be above the reference value.

Hereinafter, a signal processing scheme of a processor will be described with reference to FIGS. 13 and 14. 13 and 14 illustrate a signal processing method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.

As described above, the processor 100 receives the acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, and performs signal processing on the received acceleration data to change the position of the weight tracking device 60. Position data indicating a can be generated.

In addition, the processor 100 may control the communication module 120 to transmit location data to an external device, or store location data in the memory 110.

Referring to FIGS. 13 and 14, referring to a signal processing scheme of the processor 100, the processor 100 may perform signal processing by applying filtering or integration operations to sensed acceleration data. The processor 100 according to an embodiment may filter the acceleration data to generate purified acceleration data, and then generate position data by performing an integral operation on the purified acceleration data.

In another example, the processor 100 may receive acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, and may filter out the received acceleration data to remove noise. Alternatively, the processor 100 may remove the influence of the weight acceleration from the acceleration data.

Thereafter, the processor 100 may derive the velocity data by first integrating the acceleration data from which the noise is removed.

In addition, the processor 100 may perform signal processing by applying filtering or integration operations to the velocity data, thereby obtaining position data from the velocity data.

Hereinafter, a method of acquiring position data by a processor using machine learning will be described with reference to FIGS. 15 and 16. 15 and 16 illustrate a first machine learning method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.

Referring to FIGS. 15 and 16, the processor 100 according to an embodiment of the present invention learns (i) a machine learning model that is selected in advance in order to obtain advanced position data through machine learning. And a recognition step of obtaining the advanced position data P ′ by inputting the signal-processed position data P to the trained machine learning model.

Referring to FIG. 15, in the learning phase, the processor 100 may select any one of various kinds of machine learning models. According to an embodiment, the processor 100 may include (i) various types of neural network models such as a deep neural network (DNN), a convolutional neural network (CNN), a deep neural network (DNN), and a recurrent neural network (RNN). ), And (ii) setting a hyper parameter for the selected neural network model to select a machine learning model to be trained.

When the machine learning model to be trained is selected, the processor 100 may input a training data set prepared in advance to the selected machine learning model to train the selected machine learning model. At this time, the training data set performs signal processing on (i) measured actual position data Q and (ii) sensing value sensed by the acceleration sensor 90 with respect to the position of the weight stack 30 moving up and down. It may be composed of the sensing position data (P) obtained by. The measured position data Q is data obtained by measuring a change in height of the weight stack 30 using a tape measure, an encoder 160, or the like, and may be required to have high accuracy over a predetermined reference.

When the learning is completed, the processor 100 may input test data into the machine learning model on which the learning is completed to evaluate the performance of the learned machine learning model. For example, the processor 100 inputs some of the sensing position data P obtained by performing signal processing on the sensing value sensed by the acceleration sensor 90 to the learned machine learning model, and the output value is input. By checking the degree of correspondence with the corresponding part of the measured position data, the performance of the learned machine learning model can be evaluated.

When the performance evaluation value is higher than a preset criterion, the processor 100 may acquire the learned machine learning model as a machine learning model for obtaining advanced position data. However, if the performance evaluation value is equal to or lower than the preset criterion, the processor 100 returns to selecting the machine learning model, until the learned machine learning model that satisfies the performance evaluation value is obtained. Can be repeated.

Referring to FIG. 16, in the recognition step, the processor 100 may generate the sensing position data P by performing signal processing on a sensing value sensed by the acceleration sensor 90. In addition, the processor 100 may obtain the advanced position data P ′ by inputting the generated sensing position data P to the trained machine learning model.

Hereinafter, another method of obtaining position data by a processor using machine learning will be described with reference to FIGS. 17 and 18. 17 and 18 are diagrams illustrating a second machine learning method performed by a processor installed in a weight tracking device according to an embodiment of the present invention.

Referring to FIGS. 17 and 18, in order to obtain advanced position data through machine learning, the processor 100 according to an embodiment of the present invention may include: (i) learning a pre-selected machine learning model; And a recognition step of acquiring the enhanced acceleration data R ′ by inputting the sensing acceleration data R sensed by the acceleration sensor 90 to the learned machine learning model. In this case, when the advanced acceleration data R 'is obtained, the processor 100 performs signal processing, such as filtering and integration, on the advanced acceleration data R', thereby obtaining the advanced position data P '. Can be obtained. '

Referring to FIG. 17, in the learning step, the processor 100 may select a machine learning model to be trained and train the machine learning model in the same manner as described with reference to FIG. 15.

However, at this time, the training data set includes (i) actual measured acceleration data S and (ii) sensing acceleration data R sensed by the acceleration sensor 90 with respect to the acceleration of the weight stack 30 moving up and down. It can be composed of). The measured acceleration data R is not suitable to be used in the weight tracking device 60 because the price R is very high or large, but the acceleration change of the weight stack 30 using another acceleration sensor having a high precision is used. As the measured data, it may be required to have a high accuracy over a predetermined criterion.

When the learning is completed, the processor 100 may input test data into the machine learning model on which the learning is completed to evaluate the performance of the learned machine learning model. When the performance evaluation value is higher than a preset criterion, the processor 100 may acquire the learned machine learning model as a machine learning model for obtaining advanced position data.

Referring to FIG. 18, in the recognition step, the processor 100 may obtain sensing acceleration data R sensed by the acceleration sensor 90. In addition, the processor 100 may obtain the advanced acceleration data R ′ by inputting the acquired sensing acceleration data R into the learned machine learning model. The processor 100 may perform signal processing such as filtering and integration operations on the advanced acceleration data R ′ to obtain the advanced position data P ′. '

Referring to FIG. 19, the position data of the weight tracking device generated through signal processing or machine learning of a processor will be described. FIG. 19 illustrates position data of a weight tracking device finally produced by using acceleration data input by a processor installed in the weight tracking device according to an embodiment of the present invention.

As described above, the NFC reading module 80 may recognize the NFC tag 40 having the weight data of the weight stack 30 and provide the recognized weight data to the processor 100.

Through this, the processor 100 may determine how much weight the user lifted.

In addition, the acceleration sensor 90 may provide acceleration data to the processor 100 by sensing an acceleration value of the weight tracking device 60 (or the weight stack 30).

Thereafter, the processor 100 may signal the received acceleration data or perform machine learning to produce position data of the weight tracking device 60 or the weight stack 30.

Through this position data, the number of sets of exercise, the number of liftings per set, the range of motion of the joint, the amount of exercise, calories burned, exercise time and rest time can be determined.

Referring to FIG. 19, in more detail, when the time when the position data becomes 0 or less than a predetermined value is more than a predetermined time, it may be determined that one set is finished, and the total number of sets may be determined based on the predetermined time. Can be.

In addition, since the number of peaks in the graph means the number of times, one can grasp the number of times per set, and in FIG. 19, it can be seen that four times are performed per set.

In addition, since the height of the peak is the amount of change in position, it is possible to determine the range of joint movement of the user.

In addition, the lower area (T) of the peak indicates the amount of exercise, the amount of exercise can be determined by calculating the lower area (T) of the peak, through which calorie consumption can be calculated.

In addition, the X-axis of the potential energy graph may indicate a time to check the exercise time and the rest time.

In this way, a variety of information can be grasped through the location data, and this information can be provided to the user, or processed once more to utilize for various purposes.

The weight tracking device according to the embodiment of the present invention has been described above. Hereinafter, a weight tracking device according to another embodiment of the present invention will be described with reference to FIGS. 20 and 21. 20 is a perspective view of a weight tracking device according to another embodiment of the present invention. 21 is a view showing a state in which the weight tracking device is mounted on the weight setting pin according to another embodiment of the present invention.

20 to 21, the weight tracking device 200 according to another embodiment of the present invention is detachable to the weight setting pin 230, so that the weight stack 30 of the weight setting pin 230 is set. It may be a device capable of tracking the weight.

The weight tracking device 200 may include the same configuration as the weight tracking device 200 according to an embodiment of the present invention described above, the housing 190 constituting the appearance of the weight tracking device 200 is set to the weight The pin 230 may be detachable.

More specifically, the weight setting pin 230 may include a pin portion 215 inserted between the pinhole of the weight plate and the upper and lower weight plates, and a head portion 210 positioned at one end of the pin portion 215.

The housing 190 of the weight tracking device 200 may include a detachable part 180 detachably attached to the weight setting pin 230, and the detachable part 180 may include the head portion 210 of the weight setting pin 230. It may have a shape that meshes with).

For example, if the head portion 210 is spherical, the detachable portion 180 may have a concave shape that can accommodate the spherical head portion 210. In order to couple the weight tracking device 200 to the weight setting pin 230 under such a shape, the detachable part 180 of the housing 190 accommodates the head part 210, and the head part 210 is a detachable part ( 180 may be engaged while being engaged.

Alternatively, one or more protrusions are formed in the head portion of the weight setting pin, and a fitting hole into which the protrusion is fitted is formed in the detachable portion of the weight tracking device, and the weight tracking device is attached to the weight setting pin by fitting the protrusion into the fitting hole. Can be.

That is, the weight tracking device 200 according to another embodiment of the present invention has high utilization in that it can be applied to the weight setting pin 230 which is a ready-made product.

The weight tracking device according to the present invention has been described above. Hereinafter, the weight tracking method according to an embodiment of the present invention will be described with reference to FIG. 22. 22 is a flowchart illustrating a weight tracking method according to an embodiment of the present invention.

Weight tracking method according to an embodiment of the present invention, with respect to the weight lifting machine including a plurality of weight plates each attached NFC tag, using a weight tracking device according to an embodiment of the present invention, It may be a weight tracking method for tracking the weight of the weight stack consisting of the lifting weight plate.

The weight tracking method may include inserting a pin between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring the up and down neighboring weight plates among the plurality of weight plates (S10), and the NFC reading module inserts the pins. Detecting weight data indicating the weight of the weight stack set by the pin by reading the NFC tag detected at the time (S20), and receiving, by the processor, the weight data detected by the NFC reading module from the NFC reading module (S30) And, in step S40, the processor stores the weight data in the memory.

The step S10 of inserting the pins between the pinholes formed in any one of the plurality of weight plates or the weight plates neighboring up and down among the plurality of weight plates may be performed to set the weight stack 30 to be lifted by the user. The weight plate 20 of the user who pins the pin 10 of the weight tracking device 60 up and down among the plurality of weight plates or the pinhole 45 formed in the weight plate 25 of the plurality of weight plates, 22) can be inserted between.

By doing so, the weight stack 30 in the form of the stacked weight plates 20 can be set, and as a result, the weight to be lifted by the user can be set.

In the step S20 of detecting, by the NFC reading module, a weight tag indicating the weight of the weight stack set by the pin by reading the NFC tag detected when the pin is inserted, the user weighs the weight stack 30 to set the weight stack. While taking the tracking device 60 to the weight plate, the pin 10 can be inserted between the pinhole 45 or the upper and lower weight plates 20 and 22, and in this process, the NFC reading module of the weight tracking device 60 ( 80 may detect the weight data indicating the weight of the weight stack 30 set by the pin 10 by reading the NFC tag 40 attached to the weight plate 20.

When the processor receives the weight data detected by the NFC reading module from the NFC reading module (S30), after the NFC reading module 80 detects the weight data indicating the weight of the weight stack 30, the weight tracking device The processor 100 of 60 may receive the weight data detected by the NFC reading module 80 from the NFC reading module 80.

In step S40, the processor stores the weight data in the memory, after the processor 100 receives the weight data detected by the NFC reading module 80 from the NFC reading module 80, the weight data in the memory 110. The controller may store the weight data and transmit weight data to an external device by controlling the communication module 120 of the weight tracking device 60.

In addition, the acceleration sensor 90 of the weight tracking device 60 senses the acceleration data of the weight tracking device 60, and the processor 100 receives the sensed acceleration data from the acceleration sensor 90 and then receives the received acceleration. Signal processing may be performed on the data to generate position data indicating a change in the position of the weight tracking device 60.

In addition, the processor 100 may store location data in the memory 110, and transmit the location data to an external device by controlling the communication module 120 of the weight tracking device 60.

Alternatively, the processor 100 receives the acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, generates the position data by integrating the received acceleration data, and converts the position data into the machine learning model 170. ) Can generate machining position data.

In addition, the processor 100 may store the machining position data in the memory 110, and transmit the machining position data to an external device by controlling the communication module 120.

Alternatively, the processor 100 receives acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, applies the acceleration data to the machine learning model 170, generates processing acceleration data, and generates processing acceleration. The machining position data can be generated by integrating the data.

In addition, the processor 100 may store the machining position data in the memory 110, and transmit the machining position data to an external device by controlling the communication module 120.

The weight tracking method according to an embodiment of the present invention has been described above. Hereinafter, the weight tracking method according to another embodiment of the present invention will be described with reference to FIG. 23 is a flowchart illustrating a weight tracking method according to another embodiment of the present invention.

Weight tracking method according to another embodiment of the present invention, with respect to the weight lifting machine including a plurality of weight plates each attached NFC tag, using a weight tracking device according to another embodiment of the present invention, It may be a weight tracking method for tracking the weight of the weight stack consisting of the lifting weight plate.

The weight tracking method may include inserting a weight setting pin between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates (S50), and weight tracking to the weight setting pin. Mounting the device (S60), the NFC reading module, reading the detected NFC tag to detect the weight data indicating the weight of the weight stack set by the weight setting pin (S70), the processor, from the NFC reading module Receiving the weight data sensed by the NFC reading module (S80), and the processor may include the step of storing the weight data in the memory (S90).

In the step S50 of inserting a weight setting pin between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the weight stack 30 to be lifted by the user is set. In order to do this, the user sets the weight setting pin 230 between the pinhole 45 formed in the weight plate 25 of the plurality of weight plates or the weight plates 20 and 22 neighboring up and down among the plurality of weight plates. Can be inserted into

By doing so, the weight stack 30 in the form of a stacked weight plate can be set, and as a result, the weight to be lifted by the user can be set.

Mounting the weight tracking device to the weight setting pin (S60), the weight tracking device 200, which is a separate configuration from the weight setting pin 230, is mounted on the weight setting pin 230 and the weight tracking device 200 The weight setting pin 230 may be integrally formed.

On the other hand, unlike the case described above, after the weight tracking device 200 is mounted on the weight setting pin 230, the weight setting pin 230 between the pinhole 45 or the weight plate 20, 22 neighboring up and down Can also be inserted.

The NFC reading module detects the weight data representing the weight of the weight stack set by the weight setting pin by reading the detected NFC tag (S70), the user sets the weight tracking device 200 by the weight setting pin 230 The NFC reading module 80 of the weight tracking device 200 reads the NFC tag 40 attached to the weight plates 20 and 25 after the mounting process or the mounting is completed, and is set by the weight setting pin 230. Weight data representing the weight of the weight stack 30 may be detected.

When the processor receives the weight data detected by the NFC reading module from the NFC reading module (S80), after the NFC reading module 80 detects the weight data indicating the weight of the weight stack 30, the weight tracking device The processor 100 of the 200 may receive weight data detected by the NFC reading module 80 from the NFC reading module 80.

In step S90, the processor stores the weight data in the memory, after the processor 100 receives the weight data detected by the NFC reading module 80 from the NFC reading module 80, the weight data in the memory 110. The weight data may be stored, and the weight data may be transmitted to an external device by controlling the communication module 120 of the weight tracking device 200.

In addition, the acceleration sensor 90 of the weight tracking device 200 senses the acceleration data of the weight tracking device 200, and the processor 100 receives the sensed acceleration data from the acceleration sensor 90 and then receives the received acceleration. Signal processing may be performed on the data to generate position data indicating a change in position of the weight tracking device 200.

In addition, the processor 100 may store location data in the memory 110, and transmit the location data to an external device by controlling the communication module 120 of the weight tracking device 200.

Alternatively, the processor 100 receives the acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, generates the position data by integrating the received acceleration data, and converts the position data into the machine learning model 170. ) Can generate machining position data.

In addition, the processor 100 may store the machining position data in the memory 110, and transmit the machining position data to an external device by controlling the communication module 120.

Alternatively, the processor 100 receives acceleration data sensed by the acceleration sensor 90 from the acceleration sensor 90, applies the acceleration data to the machine learning model 170, generates processing acceleration data, and generates processing acceleration. The machining position data can be generated by integrating the data.

In addition, the processor 100 may store the machining position data in the memory 110, and transmit the machining position data to an external device by controlling the communication module 120.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. I can understand that. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive.

10: pin 20, 22, 25: weight plate
30: weight stack 40, 43: NFC tag
45: pinhole 35, 37, 230: weight setting pin
70: weight lifting machine 80: NFC reading module
90: acceleration sensor 100: processor
110: memory 120: communication module
125, 190: housing 60, 200: weight tracking device
140: metal plate 150: front
155: inner side 160: tape measure
180: removable part
210: head portion 215: pin portion

Claims (26)

A weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for setting a weight of a weight stack and tracking the weight of the weight stack,
housing;
A pin which protrudes from the housing and is inserted between the pinhole or the weight plate neighboring the upper and lower sides;
An NFC reading module disposed in the housing and reading weight data indicating a weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of insertion of the pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The NFC reading module is switched from the sleep mode to the active mode when the acceleration value of the axis parallel to the direction in which the pin is inserted is less than the reference value to read the NFC tag,
The processor,
Receive the weight data detected by the NFC reading module from the NFC reading module,
Weight tracking device for storing the weight data in the memory. The method of claim 1,
A communication module disposed inside the housing and in communication with an external device,
The processor,
Weight tracking device for controlling the communication module to transmit the weight data to the external device. The method of claim 1,
The NFC reading module,
Weight tracking device disposed in contact with the inner side of the front of the housing facing the weight stack. The method of claim 3, wherein
A weight tracking device having a metal plate attached to a part or all of the parts other than the part in contact with the NFC reading module inside the front of the housing. delete A weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for setting a weight of a weight stack and tracking the weight of the weight stack,
housing;
A pin which protrudes from the housing and is inserted between the pinhole or the weight plate neighboring the upper and lower sides;
An NFC reading module disposed in the housing and reading weight data indicating a weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of insertion of the pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The NFC reading module reads the NFC tag in an active mode in a sleep mode when the acceleration value of two or more axes falls below a reference value among three-axis acceleration values that are greater than or equal to a reference value.
The processor,
Receive the weight data detected by the NFC reading module from the NFC reading module,
Weight tracking device for storing the weight data in the memory. A weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for setting a weight of a weight stack and tracking the weight of the weight stack,
housing;
A pin which protrudes from the housing and is inserted between the pinhole or the weight plate neighboring the upper and lower sides;
An NFC reading module disposed in the housing and reading weight data indicating a weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of insertion of the pin;
A memory disposed inside the housing; And
A processor disposed inside the housing;
The processor,
And a weight tracking device for receiving the weight data detected by the NFC reading module in the active mode from the NFC reading module and storing the weight data having the highest frequency among the received weight data in the memory. The method of claim 1,
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
The processor,
Receiving the acceleration data sensed by the acceleration sensor from the acceleration sensor,
And a signal processing on the received acceleration data to generate position data indicating a change in position of the weight tracking device. A weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for setting a weight of a weight stack and tracking the weight of the weight stack,
housing;
A pin which protrudes from the housing and is inserted between the pinhole or the weight plate neighboring the upper and lower sides;
An NFC reading module disposed in the housing and reading weight data indicating a weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of insertion of the pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The processor,
Receiving the weight data detected by the NFC reading module from the NFC reading module, storing the weight data in the memory,
The processor,
Receiving the acceleration data sensed by the acceleration sensor from the acceleration sensor,
Performing signal processing on the acceleration data to generate position data indicating a change in position of the weight tracking device;
Weight tracking device to generate the advanced position data by applying the position data to the learned machine learning model (Machine Learning Model). A weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for setting a weight of a weight stack and tracking the weight of the weight stack,
housing;
A pin which protrudes from the housing and is inserted between the pinhole or the weight plate neighboring the upper and lower sides;
An NFC reading module disposed in the housing and reading weight data indicating a weight of the weight stack set by the pin by reading the NFC tag detected after the insertion process or completion of insertion of the pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The processor,
Receiving the weight data detected by the NFC reading module from the NFC reading module, storing the weight data in the memory,
The processor,
Receiving the acceleration data sensed by the acceleration sensor from the acceleration sensor,
Applying the acceleration data to the learned machine learning model (Machine Learning Model) to generate the advanced acceleration data,
And a signal processing on the advanced acceleration data to generate position data indicating a change in position of the weight tracking device. For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, a weight is set between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for tracking the weight of a weight stack set by inserting a pin,
A housing detachable from the weight setting pin;
An NFC reading module disposed in the housing and configured to detect weight data indicating the weight of the weight stack by reading the NFC tag detected after the insertion or completion of the insertion of the weight setting pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The NFC reading module is switched from the sleep mode to the active mode when the acceleration value of the axis parallel to the direction in which the pin is inserted is less than the reference value to read the NFC tag,
The processor,
Receive the weight data detected by the NFC reading module from the NFC reading module,
Weight tracking device for storing the weight data in the memory. The method of claim 11,
The housing includes a detachable portion detachable to the weight setting pin,
The detachable portion is a weight tracking device having a shape that is engaged with the head of the weight setting pin. For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, a weight is set between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for tracking the weight of a weight stack set by inserting a pin,
A housing detachable from the weight setting pin;
An NFC reading module disposed in the housing and configured to detect weight data indicating the weight of the weight stack by reading the NFC tag detected after the insertion or completion of the insertion of the weight setting pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The NFC reading module reads the NFC tag in an active mode in a sleep mode when the acceleration value of two or more axes falls below a reference value among three-axis acceleration values that are greater than or equal to a reference value.
The processor,
Receive the weight data detected by the NFC reading module from the NFC reading module,
Weight tracking device for storing the weight data in the memory. For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, a weight is set between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for tracking the weight of a weight stack set by inserting a pin,
A housing detachable from the weight setting pin;
An NFC reading module disposed in the housing and configured to detect weight data indicating the weight of the weight stack by reading the NFC tag detected after the insertion or completion of the insertion of the weight setting pin;
A memory disposed inside the housing; And
A processor disposed inside the housing
Including,
And a weight tracking device for receiving the weight data detected by the NFC reading module in the active mode from the NFC reading module and storing the weight data having the highest frequency among the received weight data in the memory. For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, a weight is set between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for tracking the weight of a weight stack set by inserting a pin,
A housing detachable from the weight setting pin;
An NFC reading module disposed in the housing and configured to detect weight data indicating the weight of the weight stack by reading the NFC tag detected after the insertion or completion of the insertion of the weight setting pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The processor,
Receiving the weight data detected by the NFC reading module from the NFC reading module, storing the weight data in the memory,
The processor,
Receiving the acceleration data sensed by the acceleration sensor from the acceleration sensor,
Performing signal processing on the acceleration data to generate position data indicating a change in position of the weight tracking device;
Weight tracking device to generate the advanced position data by applying the position data to the learned machine learning model (Machine Learning Model). For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, a weight is set between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates. A weight tracking device for tracking the weight of a weight stack set by inserting a pin,
A housing detachable from the weight setting pin;
An NFC reading module disposed in the housing and configured to detect weight data indicating the weight of the weight stack by reading the NFC tag detected after the insertion or completion of the insertion of the weight setting pin;
A memory disposed inside the housing;
A processor disposed inside the housing; And
An acceleration sensor disposed inside the housing and configured to sense acceleration data indicating an acceleration value of the weight tracking device;
Including,
The processor,
Receiving the weight data detected by the NFC reading module from the NFC reading module, storing the weight data in the memory,
The processor,
Receiving the acceleration data sensed by the acceleration sensor from the acceleration sensor,
Applying the acceleration data to the learned machine learning model (Machine Learning Model) to generate the advanced acceleration data,
And a signal processing on the advanced acceleration data to generate position data indicating a change in position of the weight tracking device. A weight tracking method for tracking the weight of the weight stack set by the pin of claim 1 using the weight tracking device of claim 1 for a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto. As
When the pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 1 inserts the pin. Or reading weight data indicating a weight of the weight stack by reading the NFC tag detected after completion of insertion;
The processor of claim 1, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 1. A weight tracking method for tracking the weight of a weight stack set by a pin according to claim 6 using a weight tracking device according to claim 6 for a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto. As
When the pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 6 inserts the pin. Or reading weight data indicating a weight of the weight stack by reading the NFC tag detected after completion of insertion;
The processor of claim 6, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory of claim 6. A weight tracking method for tracking the weight of a weight stack set by a pin according to claim 7, using a weight tracking device according to claim 7, for a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto. As
When the pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 7 inserts the pin. Or reading weight data indicating a weight of the weight stack by reading the NFC tag detected after completion of insertion;
Receiving, by the processor of claim 7, the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 7. The weight tracking method which tracks the weight of the weight stack set by the pin of Claim 9 using the weight tracking apparatus of Claim 9 with respect to the weight lifting machine which consists of a some weight plate with each NFC tag attached. As
When the pin is inserted between a pinhole formed in any one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 9 inserts the pin. Or reading weight data indicating a weight of the weight stack by reading the NFC tag detected after completion of insertion;
The processor of claim 9, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 9. A weight tracking method for tracking the weight of a weight stack set by a pin according to claim 10 using a weight tracking device according to claim 10 for a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto. As
When the pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 10 inserts the pin. Or reading weight data indicating a weight of the weight stack by reading the NFC tag detected after completion of insertion;
The processor of claim 10, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 10. For a weight lifting machine including a plurality of weight plates each having an NFC tag attached thereto, using the weight tracking device according to claim 11, the weight of the weight stack set by the weight setting pin equipped with the weight tracking device is tracked. As a weight tracking method
When the weight setting pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 11 sets the weight. Reading weight data indicating the weight of the weight stack by reading the NFC tag detected after a pin is inserted or completed;
Receiving, by the processor of claim 11, the weight data from the NFC reading module; And
And the processor storing the weight data in the memory of claim 11. For a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto, using the weight tracking device according to claim 13, the weight of the weight stack set by the weight setting pin equipped with the weight tracking device is tracked. As a weight tracking method
When the weight setting pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 13 sets the weight. Reading weight data indicating the weight of the weight stack by reading the NFC tag detected after a pin is inserted or completed;
The processor of claim 13, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 13. For a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto, using the weight tracking device according to claim 14, the weight of the weight stack set by the weight setting pin equipped with the weight tracking device is tracked. As a weight tracking method
When the weight setting pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 14 sets the weight. Reading weight data indicating the weight of the weight stack by reading the NFC tag detected after a pin is inserted or completed;
The processor of claim 14, further comprising: receiving the weight data from the NFC reading module; And
Storing, by the processor, the weight data in the memory of claim 14. For a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto, using the weight tracking device according to claim 15, the weight of the weight stack set by the weight setting pin equipped with the weight tracking device is tracked. As a weight tracking method
When the weight setting pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 15 sets the weight. Reading weight data indicating the weight of the weight stack by reading the NFC tag detected after a pin is inserted or completed;
The processor of claim 15, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory of claim 15. For a weight lifting machine comprising a plurality of weight plates each having an NFC tag attached thereto, using the weight tracking device according to claim 16, the weight of the weight stack set by the weight setting pin equipped with the weight tracking device is tracked. As a weight tracking method
When the weight setting pin is inserted between a pinhole formed in one of the plurality of weight plates or a weight plate neighboring up and down among the plurality of weight plates, the NFC reading module according to claim 16 sets the weight. Reading weight data indicating the weight of the weight stack by reading the NFC tag detected after a pin is inserted or completed;
The processor of claim 16, further comprising: receiving the weight data from the NFC reading module; And
And the processor storing the weight data in the memory according to claim 16.

Images