KR20240016166A - Heartbeat communication device using network - Google Patents

Abstract

Heart rate recording: HeartSync uses a wearable device to record. It detects the heart rates of celebrities, singers, and sportsmen in real time to capture each individual's unique biorhythm.
NFT compatibility: HeartSync's videos and music can be sold as NFTs. Users can own the history of celebrities and experience their performances in new and immersive ways.
Customized playback: HeartSync's NFTs can be played on demand, giving users the ability to customize their viewing or listening experience based on their preferences.
High-quality audio and video: HeartSync’s NFTs provide high-quality audio. It provides users with a realistic experience of celebrity performances through sound and video.
Broad appeal: HeartSync's NFTs offer a unique and personalized way to experience celebrities, singers, and favorite performers.
Therefore, in the heart rate communication device using a network, the heart rate data is converted from the wearable device 120 that collects heart rate data 130 from the wearer into a format that can be used for any of visual, auditory, and tactile displays. The converted heart rate data 140 is transmitted using the HeartSync technology 110 and recorded in the NFC 150, and the recorded converted heart rate data 140 is transferred from the NFC 150 to the visualization unit. We propose a heartbeat communication device using a network, which is characterized by receiving data from various output devices such as (160), an audible unit (170), and a tactile unit (180) and interacting with the user through a user interface (190).

Description

Heartbeat communication device using network}

In the present invention, biosync is defined as a technology that samples a subject's biological signals, especially heart rate, with a wearable device such as a smart band or smart vest and converts it into content, and the converted content can be saved and played again. The present invention is designed to provide users with an immersive experience by integrating biological rhythms into media consumption.

In the present invention, heart sync is defined as sampling only the heart among bio-signals and converting it into content during bio-synchronization of all bio-signals.

The term Biosync is a unique word of the present invention that refers to a technology that samples a person's biological signals and converts them into content. However, the term "synchronization" has been used in a variety of fields to describe the synchronization of data or processes. For example, in music production, "synchronization" means synchronizing audio and video files. In the medical field, “synchronization” can mean synchronizing the electrical activity of the heart. Overall, the term 'biosync' may be relatively new, but the concept of synchronizing biological signals with technology has likely been explored in a variety of fields throughout history.

The technologies applied to the present invention are listed as follows.

Wearable device integration: BioSync is compatible with a variety of wearable devices such as smart bands, smart vests, and other biometric sensors that can track heart rate and other vital signs.

Biosignal Sampling: BioSync continuously samples a subject's biosignals and converts them into data that can be analyzed and used to create unique media content.

Customizable Content: BioSync provides users with the ability to customize media content by choosing from a variety of options such as music, videos or images that can be stored on the device.

Feedback in real time or offline: BioSync provides real-time feedback to users by sensory (visual, auditory or tactile) of heart rate and other vital signs, allowing them to monitor their physiological responses and consume media accordingly. It is a technology that allows you to save and watch offline.

HeartSync is a cutting-edge technology that records the heart rates of celebrities, singers, and athletes using wearable devices and converts them into video or audio. They can be sold through NFTs (non-fungible tokens) and can be played later.

The technologies and features related to HeartSync are as follows.

Heart rate recording: HeartSync uses a wearable device to record. It detects the heart rates of celebrities, singers, and sportsmen in real time to capture each individual's unique biorhythm.

NFT compatibility: HeartSync's videos and music can be sold as NFTs. , users can own the history of celebrities and experience their performances in new and immersive ways.

Customized playback: HeartSync's NFTs can be played on demand, giving users the ability to customize their viewing or listening experience based on their preferences.

High-quality audio and video: HeartSync’s NFTs provide high-quality audio. It provides users with a realistic experience of celebrity performances through sound and video.

Broad appeal: HeartSync's NFTs offer a unique and personalized way to experience celebrities, singers, and favorite performers.

The HeartSync of the present invention is a sophisticated technology that records the heart rate of celebrities, singers, and athletes in real time using a wearable device and converts it into video or sound that can be sold as NFT. HeartSync's background technology includes several key components:

Wearable devices: HeartSync uses wearable devices, such as smart bands or smart vests, to record heart rate. Wearable devices must be designed to be comfortable and non-invasive so that they can be worn for long periods of time during performances or activities.

Biometric sensor: Wearable devices are equipped with biosignal sensors to measure the electrical activity of the heart and convert it into digital data that can be processed by HeartSync software.

This also applies to wristbands or smart watches.

HeartSync software: HeartSync software processes digital data from biosignal sensors. By analyzing heart rate in real time, an individual's unique biological rhythm is captured and converted into video or sound.

NFT platform: Through HeartSync's NFT platform, users purchase and own videos or music produced with the technology. The NFT platform uses blockchain technology to ensure the authenticity and ownership of NFTs.

HeartSync-based technologies continue to evolve and improve with new advances in biosignal detection and processing. HeartSync captures the heart rates of celebrities, singers and sportspeople in real time and converts them into unique videos or audio recordings, giving fans a personalized and authentic way to experience their favorite celebrities.

Republic of Korea Patent Registration Publication No. 10-1966752 (Publication date: April 9, 2019, hereinafter referred to as ‘Prior Document 1’). In the abstract of the invention regarding “Medical Institution Relay System for Mobile Health Data,” “The present invention relates to mobile health data. It relates to a medical institution relay system, where a medical information format analysis unit extracts platform information by analyzing the format of medical information collected from a mobile terminal; a medical information format analysis unit parses the collected medical information using the platform information extracted from the medical information format analysis unit. A medical information parsing unit that extracts raw data; and a metagenerator that receives raw data from the medical information parsing unit and generates metadata that conforms to standard medical information, and Standard medical information generation, including a medical standard terminology converter that converts the data format into a medical standard terminology code, and a data generator that generates data that meets standard medical data specifications using data converted to medical standard terminology codes and raw data. It standardizes the format of the medical information collected from the mobile terminal and relays it to be delivered to the medical institution server. As a result, the medical information collected from the mobile terminal is converted into standard medical information data used by the medical institution server and transmitted to the medical institution server. It is stated, “It will be possible to provide this.”

The mobile health data relay system and HeartSync, which are the preceding literature 1, are two technologies with different purposes.

Previous literature 1, a mobile health data relay system, was designed for medical institutions to collect and standardize medical information from mobile terminals. Like a smartphone or tablet. This system includes various units such as a medical information format analysis unit, medical information parsing unit, and standard medical information generator to extract raw data and convert it into standardized medical information that can be easily transmitted to the medical institution server.

On the other hand, HeartSync is a technology that records the heart rate of celebrities, singers, and athletes in real time using wearable devices and converts them into videos or sound sources that can be sold as NFTs. . HeartSync's technology includes the use of biosignal sensors, heart rate analysis software, and an NFT platform for ownership and authenticity.

Previous literature 1, a mobile health data relay system, was designed to help medical institutions collect and standardize medical information. HeartSync is designed for entertainment purposes and provides a personalized and authentic way for fans to experience their favorite performers.

HeartSync's benefits include the ability to capture and preserve an individual's unique biological rhythms. And a real experience for the fans. Additionally, the use of blockchain technology in the NFT platform ensures the authenticity and ownership of the video or sound source.

Republic of Korea Patent Registration No. 10-0927473 (announcement date: November 23, 2009, hereinafter referred to as 'Prior Document 2') "Wireless heart rate monitor system for group use" means "The present invention relates to a wireless heart rate monitor system for group use, and further In detail, each wireless heart rate measuring device worn by multiple people is activated when ECG data is detected, directly calculates the user's heart rate and transmits it along with the remaining battery capacity to a single receiving device, and the receiving device wirelessly We aim to provide a wireless heart rate monitoring system for groups that automatically derives exercise information (e.g. physical efficiency index, cardiorespiratory endurance level, etc.) for the user based on the user's heart rate data received from the heart rate measuring device. To this end, this The invention includes wireless heart rate measuring devices each worn by a plurality of users; and at least one receiving device provided on the measuring device, wherein each wireless heart rate measuring device detects electrocardiogram data for each user. It is driven to calculate the user's heart rate data, and transmits the calculated heart rate data and remaining battery capacity to the receiving device, wherein the receiving device receives each user's heart rate data from each wireless heart rate measuring device. Based on this, exercise information for the user is derived, and includes a repeater for relaying each user's heart rate data and remaining battery power transmitted from each wireless heart rate measuring device to the receiving device, and each wireless heart rate measuring device includes a heart rate measurement transmitter and an electrocardiogram meter, wherein the electrocardiogram meter and the heart rate measurement transmitter are coupled (attached) through a predetermined connection member, so that electrocardiogram data detected by the electrocardiogram meter is transmitted to the heart rate measurement transmitter, and each wireless heart rate The measuring device is implemented as a clothing type or portable type, such as a chest belt type, sports bra, racing tank, or cardio shirt, and the heart rate measurement transmitter is connected to the electrocardiogram measuring device. In the single wireless heart rate monitor system including a control unit, an electrocardiogram measuring device connection unit, and a power supply unit that turns on the power unit to drive the heart rate measurement transmitter when user electrocardiogram data is detected from the electrocardiogram measuring device, The measurement transmitter directly calculates the heart rate by calculating the interval between pulses (R wave) from the plurality of ECG waveforms detected from the electrocardiogram measuring device and transmits it to the receiving device. The receiving device is a user "It is equipped with an application to determine the intensity and time of exercise before starting exercise, an application to view the user's exercise status, an application to check the user's current exercise status, and an application to check the user's exercise results." It is listed.

The heart rate measurement transmitter of Prior Literature 2 is a device that directly calculates the user's heart rate by analyzing the electrocardiogram waveform and transmitting the information to the receiving device. The receiving device can then use various applications to determine the intensity and duration of the user's exercise, monitor exercise status, and track progress over time.

Compared to the preceding document 2, HeartSync technology records the athlete's heartbeat and converts it. It is converted into a video or sound source that can be sold and secured through NFT technology. This technology offers several benefits, including creating unique and personalized experiences for fans, preserving players' biological rhythms, and providing new ways to monetize sports content.

One advantage of HeartSync technology is that it provides a more immersive experience for fans. By recreating an athlete's heartbeat through video or audio, fans can feel a closer connection with their favorite sports star and gain a deeper understanding of the athlete's physical activity during the game.

Additionally, HeartSync technology is a new way to monetize sports content. By securing videos or music using NFT technology, they become valuable and unique assets that can be bought and sold on the blockchain. This could potentially lead to new revenue streams for athletes and sports organizations.

Overall, the purposes of the heart rate measurement transmitter and HeartSync technology in Prior Literature 2 are different, but HeartSync provides a more immersive and customized sports experience and a new way to monetize sports content.

The main difference between heart rate measurement transmitters and Heart Sync technology lies in their technical approach and purpose.

A heart rate measurement transmitter is a device that directly calculates the user's heart rate by analyzing the interval between pulses of the electrocardiogram waveform. The device then transmits the calculated heart rate to the receiving device. The receiving device can use various applications to determine the user's exercise intensity and time, check the user's exercise status, and check the user's exercise results.

On the other hand, Heart Sync technology is designed to record an athlete's heartbeat and play it back as a video or audio source. The technology uses wearable vital sign sensors and heart rate analysis software to capture and record an athlete's unique circadian rhythm. The generated video or sound source is protected using NFT technology and sold to fans as a personalized and authentic experience.

In summary, while a heart rate transmitter is a tool that measures and tracks a user's heart rate during exercise, Heart Sync technology is a platform for providing fans with a unique and immersive experience related to the circadian rhythm of their favorite sportsmen.

Looking at prior literature 1 and 2, the conventional technology is not technically provided in combination with video and sound sources offline, and is not for fans of celebrities, singers, or sportsmen, and is not due to combination with NFT, nor is it a new source of revenue. There was a problem in that it could not provide the means to create .

The present invention was proposed to solve the above problems of previously proposed methods, and its first purpose is to provide a means to record the real-time heartbeat of celebrities, singers, and athletes using wearable devices.

The second purpose is to provide a means of converting the heartbeat recorded above into a video or sound source that can be sold as an NFT.

There is a third purpose: to provide a means to provide fans with a personalized and authentic way to experience the unique biological rhythms of their favorite celebrities, singers, sportsmen and performers.

A technology that uses wearable devices to record the real-time heart rate of celebrities, singers, athletes, and performers uses biosignal sensors such as smart bands, smart vests, and smart watches. These sensors detect electrical signals generated by the heart and transmit them to heart rate analysis software for processing.

Heart rate analysis software calculates the interval between pulses (R waves). Multiple electrocardiogram waveforms are measured to determine the wearer's heart rate. The software can also analyze heart rate variability and provide insight into the wearer's physical condition and stress levels.

Heart rate data can be converted to video or audio using special software. This process involves assigning sensory elements, including visual, auditory or tactile elements, to specific heart beats or intervals to create a unique and personalized expression of the wearer's biological rhythm.

The resulting video or sound recording can be safely stored and sold as an NFT, allowing fans to own a unique piece of their favorite performer's biological rhythms. This technology provides a new way for fans to connect with their idols and experience their artistry on a more intimate level.

HeartSync has a variety of ripple effects in both the entertainment industry and healthcare technology.

In the entertainment industry, Heartsync provides a new way for celebrities, singers, athletes, and performers to connect with their fans. Heart Sync provides fans with an immersive and authentic experience by providing a personalized and unique representation of biological rhythms, allowing them to feel closer to their favorite performers. This technology also provides new revenue generation opportunities as videos or music can be sold as NFTs (Non-Fungible Tokens).

In the medical industry, celebrities, singers, athletes, and performers use wearable devices and special software to record and analyze heart rate data, which could have a significant impact on the prevention and management of various medical conditions. For example, a wearable heart rate monitor can help detect irregular heartbeats, which can be a sign of various heart diseases. By analyzing heart rate data over time, medical professionals can identify patterns and trends that may indicate the need for further medical intervention.

Figure 1 is an example of a singing video and heart sync visualization according to the present invention.
Figure 2 is an example of auralization of HeartSync according to the present invention.
Figure 3 is an example of a tactile version of the heart sink according to the present invention.
Figure 4 is an example of HeartSync recording on a blockchain according to an embodiment of the present invention.
Figure 5 is a background diagram of HeartSync.
Figure 6 is a block diagram showing that heart rate data is converted into heart rate data through heart sync technology.
Figure 7 is a device block diagram of an embodiment in which a heart sync is implemented as a device.
Figure 8 is a device block diagram of another embodiment in which a heart sync is implemented as a device.

Hereinafter, with reference to the attached drawings, preferred embodiments will be described in detail so that those skilled in the art can easily practice the present invention.

As described above, HeartSink is

Biosync is a technology that samples a subject's biological signals, especially heart rate, using wearable devices such as smart bands or smart vests and converts them into content. Heart Sync refers to sampling only the heart among biological signals and converting it into content. define.

The clear meaning of expression after sampling and turning it into content is presented as follows.

HeartSync technology samples a target individual's heartbeat and converts it into content that can be visualized, heard, or tactile.

In terms of visualization, this technology can display the waveform of the heartbeat on the screen. Allows users to view an individual's unique heart rate pattern. This provides a captivating visual representation of an individual's biological rhythms and can be used for a variety of applications such as art installations or personal keepsakes.

On the hearing side, HeartSync can amplify the sound of an individual's heartbeat to make it audible to the listener. The pounding sound of the heartbeat can be amplified or slightly modified to make it more pleasant or aesthetically appealing. This allows us to provide fans and listeners with a unique auditory experience.

HeartSync technology can also create a tactile sensation through vibration. Wearable devices used to record heartbeats can be programmed to vibrate in synchronization with an individual's heartbeat, providing a physical sensation that corresponds to the recorded biological rhythm. This provides users with a unique and immersive experience, allowing them to feel a deeper connection with the individual whose heartbeat is being recorded.

Overall, HeartSync technology offers a new way to experience and appreciate your unique biological rhythm. It has the potential to be used for a variety of purposes, from personal souvenirs to artistic expression.

Visualizing the heartbeat requires the use of special software that can turn heart rate data into a visual representation of the wearer's biological rhythm. Simply assign a visual element to a specific beat or interval in your heart rate data.

One common way to visualize heart rate is to create a waveform graph that displays heart rate changes over time. Graphs typically display time on the x-axis and heart rate on the y-axis, with each heartbeat represented as a peak on the graph. Waveforms can also be color-coded to indicate changes in heart rate intensity. Warm colors indicate a high heart rate and cool colors indicate a low heart rate.

Another way to visualize the heartbeat is to create a 3D model. It represents the heart and its movements. The model can show how the heart expands and contracts with each beat and can also highlight abnormalities or irregularities in the heartbeat.

In addition to these techniques, there are more creative ways to visualize the heartbeat. For example, heart rate data could be used to create abstract works of art that reflect the wearer's biological rhythm. Visual elements can create unique, personalized representations of the heartbeat based on the wearer's preferences, such as color scheme or style.

Overall, visualizing the heartbeat allows us to understand and evaluate the complex workings of the human mind.

Figure 1 is an example of a singing video and heart sync visualization according to the present invention.

Audiovisualizing the heartbeat in HeartSync involves using special software to convert heart rate data collected from the wearable device into an audio representation. This audio representation can then be manipulated and enhanced to provide users with a unique and personalized auditory experience.

Software used to sonify heartbeats analyzes heart rate data to identify specific patterns and intervals of beats. Audio elements are then assigned to these patterns and intervals to create a rhythmic, musical representation of the heartbeat. These audio elements can range from simple beats to complex musical compositions, depending on the user's preferences.

In addition to creating a unique and personalized hearing experience, auditoryizing the heartbeat may have therapeutic benefits. Listening to the rhythmic sound of your own heartbeat promotes relaxation and reduces stress, making it a useful tool for people suffering from anxiety or other stress-related conditions.

Overall, audiovisualizing the heartbeat is an attractive and innovative technology. It is a technology that adds a new dimension to the way we experience our own biological rhythms.

Heart Sync technology converts the wearer's heartbeat into a personalized, unique sound source that can be sold as an NFT. One of the techniques used is to convert heartbeats into beautiful melodies.

To convert heartbeat into melody, the software first analyzes heart rate data collected from the wearable device. Identify the peaks and troughs of your heartbeat and assign notes to each peak and trough based on amplitude and duration. You can then arrange these notes into a melody to create a more enjoyable sound.

The formula for converting heartbeats to notes may vary depending on the software you use, but a basic example is:

Amplitude of peak/valley = volume of note

Duration of peak/valley = length of note

Frequency of heart rate = tempo of melody

For example, if the peak of your heartbeat has an amplitude of 0.5 mV and a duration of 0.2 seconds, assign a note with a volume of 50% and a length of 0.2 seconds. The overall tempo of the melody is determined by the wearer's heart rate frequency.

Figure 2 is an example of auralization of HeartSync according to the present invention.

HeartSync is a technology that samples and receives biometric information, such as the heartbeat of celebrities, singers, athletes, and actors, through wearable devices. This information is then converted into a video or sound source using special software that assigns visual or auditory elements to specific heart beats or intervals, creating a unique, personalized representation of the wearer's biological rhythm.

Biometric information can also be transmitted to fans through visual and auditory expressions and vibrations. This is achieved using haptic technology, which creates tactile feedback through vibration or motion. The wearable device captures the wearer's heartbeat and transmits the information to the fan's device, which then converts the data into haptic feedback. This allows fans to feel the heartbeat of their favorite performers, providing a more immersive and personalized experience.

The technology behind this process involves collecting and processing data using sensors, software algorithms, and wireless communication protocols. Sensors capture the wearer's heartbeat, and algorithms analyze the data to extract relevant features, such as heart rate variability, which can be used to create a nuanced representation of biological rhythms. Data can be transmitted to fans' devices through wireless communication protocols, allowing them to experience biometric information in real time.

Haptic technology is a technology that communicates with users using touch. Users can experience sensation and feedback through physical interaction. This technology is often used in wearable devices and is becoming increasingly popular in the gaming and entertainment industries.

Haptic technology works by using small actuators, or motors, to create vibration, pressure, or other physical sensations that can be felt. by user. These senses can be used to convey information, simulate real-world experiences, or enhance the user experience in a variety of ways.

One example of haptic technology is the use of vibration feedback in smartphones and smartwatches. When a user receives a notification, the device can vibrate to alert them. This provides a physical sensation that users can feel even if they are not looking at the device.

Another example of haptic technology is the use of force feedback in game controllers. As the player interacts with the virtual environment, the controller can provide physical feedback that simulates the sensation of touching or manipulating objects in the game world. For example, a controller could vibrate when the player's character is hit by an enemy or provide resistance when the player tries to push an object.

The use of haptic technology is also being explored in virtual and augmented applications. Real life application. By providing physical feedback that simulates the sensation of touching or manipulating objects in a virtual environment, users can have a more immersive and realistic experience. This is achieved using actuators or motors that generate vibration, pressure, or other physical sensations corresponding to the virtual object being interacted with.

Below is an example of a formula that can be used for haptic technology.

Frequency Modulation: This formula can be used to create different vibrations by changing the frequency of the haptic feedback. For example, a lower frequency may indicate a softer touch and a higher frequency may indicate a harder touch.

Amplitude Modulation: This formula can be used to create different levels of touch. The amplitude of vibration is changed and expressed as the intensity of tactile feedback. For example, a low amplitude may indicate a light touch and a high amplitude may indicate a stronger touch.

Waveform synthesis: This formula can be used to create complex haptic feedback patterns. By combining different waveforms. For example, a waveform simulating the sensation of a heartbeat can be combined with a waveform simulating the sensation of breathing to create a more realistic and immersive experience.

Figure 3 is an example of a tactile version of the heart sink according to the present invention.

Heart Sync technology allows you to record your heart rate and convert that data into visual, auditory or tactile format.

When converting the heartbeat into an auditory format, the technology can quantify heart rate data such as various aspects of the heartbeat, highs, lows, and intervals between heartbeats. For example, the high pitch of a heartbeat can be quantified by measuring the peak frequency of the R wave in the ECG signal, while the low pitch can be quantified by measuring the frequency of the T wave. The interval between heartbeats can be quantified by measuring the time between successive R waves in the ECG signal.

Likewise, when converting the heartbeat into visual form, the technology can assign specific visual elements to different aspects of the heart. Speed data. For example, the amplitude of the R wave can be expressed as the height of the visual waveform, and the interval between heartbeats can be expressed as the distance between successive waveforms.

Finally, when converting heartbeat into tactile sensations, the technology can utilize haptic feedback to represent various aspects of heart rate data. For example, if the vibration frequency is high, the heart rate speeds up, and if the vibration frequency is low, the heart rate slows down.

To convert and record heart sounds into numeric format, you can follow these steps:

Acquire heart sounds using a microphone or other audio recording device.

Isolate single beats from heart sound recordings.

Signal processing techniques are used to identify the highest and lowest pitch and beat duration of the beat.

Convert the identified pitch to a frequency value that can be expressed in Hertz (Hz).

Numeric values for each beat, such as highest pitch frequency, lowest pitch frequency, and beat duration, are recorded in the database.

For example, suppose we recorded a single beat from a human heart sound. After processing the signal, we identify that the highest pitch frequency is 100 Hz, the lowest pitch frequency is 50 Hz, and the beat duration is 0.8 seconds. This information can be expressed numerically as follows.

A single beat of 1 beat (highest pitch, lowest pitch, duration of one beat) = (100 Hz, 50 Hz, 0.8 seconds)

By recording this, the information in the database can be used to create a visual, auditory or tactile representation of the heartbeat using special software, as in the case of Heart Sync.

Heart Sync technology allows a person's heartbeat data, including the highest pitch, lowest pitch and duration of a beat, to be recorded and then stored on the blockchain as a non-fungible token (NFT). This provides a secure and unique record of an individual's biometric information.

Electrocardiogram (ECG) signals are captured from a wearable device, such as a smartwatch or chest strap, using special software to record heart rate data. The ECG signal is then processed to identify the R peak that corresponds to the individual's heartbeat. The software can then extract relevant information from each beat, including the highest pitch, lowest pitch, and duration.

Once heart data is extracted, it can be stored as an NFT on the blockchain. NFTs are unique digital assets that provide proof of ownership and authenticity. By storing heart rate data as an NFT, it can be safely transferred or sold to interested parties such as fans, collectors, or medical researchers.

The following is an example of a series of numbers recorded for 10 seconds of a celebrity's heartbeat.

(120Hz, 80Hz, 0.8 seconds), (125Hz, 82Hz, 0.7 seconds), (122Hz, 85Hz, 0.9 seconds), (128Hz, 78Hz, 0.6 seconds), (124Hz, 81Hz, 0.8 seconds), (118Hz, 79Hz, 0.7 seconds), (121Hz, 83Hz, 0.9 seconds) ), (129Hz, 77Hz, 0.6 seconds), (123Hz, 80Hz, 0.8 seconds), (119Hz, 82Hz, 0.7 seconds)

These numbers represent the highest and lowest pitch. The time of each heartbeat recorded and the duration of each beat. It can be used to create a unique, personalized representation of an individual's heartbeat that can be further visualized, heard or tactile using special software that is part of the Heart Sync technology.

Using blockchain technology means that NFTs are immutable. Once data is recorded, it cannot be altered or tampered with. This adds an additional layer of security and trust to the process of recording and sharing biometric information.

Heart Sync technology allows the recorded heartbeat to be expressed visually, audibly, and tactilely. In the case of a singer's performance, the recorded heartbeat can be synchronized with the music to provide an immersive experience for the listener.

For example, when a singer sings a high note, you can visualize the corresponding heartbeat. It is amplified on the monitor or screen through speakers or headphones and felt through a haptic feedback device. By quantifying the highest notes, lowest notes, and duration of a beat, the heartbeat can be synchronized with music and converted into various sensory outputs.

When feeling the fastest and strongest heartbeat, the haptic feedback device can be programmed to vibrate with increasing intensity and frequency as the singer reaches higher notes or more intense parts of the performance. This provides listeners with a visceral and immersive experience, enhancing the emotional impact of the performance.

Overall, Heart Sync technology provides a new way to experience music and performance, allowing audiences to connect with performers on a more intimate and emotional level.

Figure 4 is an example of HeartSync recording on a blockchain according to an embodiment of the present invention.

Figure 5 is a background diagram of HeartSync.

The sequence of operations according to the background diagram of FIG. 5 begins with the wearable device 120 collecting heart rate data 130 from the wearer. Heart rate data is transmitted to HeartSync technology 110, which converts the data into a format that can be used for visualization, auditory display, and tactile use. The converted heart rate data 140 is transmitted from the NFC 150 to various output devices such as the visualization unit 160, the audible unit 170, and the tactile unit 180. Finally, the user interacts with the converted heart rate data through the user interface 190.

That is, according to one embodiment of the present invention, the following configuration was created.

In a heartbeat communication device using a network,

The heart rate data is transmitted from the wearable device 120, which collects heart rate data 130 from the wearer, to HeartSync technology 110, which converts the data into a format that can be used for any of visual, auditory, and tactile displays. , the converted heart rate data 140 is recorded in the NFC 150, and the recorded converted heart rate data 140 is transmitted from the NFC 150 to the visualization unit 160, the audible unit 170, and the tactile unit. We propose a heartbeat communication device using a network, which is characterized by receiving data from various output devices such as (180) and interacting with the user through a user interface (190).

If the device implementing the heart sync technology is defined as the heart sync device 210, the heart sync device is equivalent to the heartbeat communication device using the network of the present invention.

Figure 6 is a block diagram showing that heart rate data is converted into heart rate data through heart sync technology.

As described above, heart rate data 130 is,

It can be expressed as (120Hz, 80Hz, 0.8 seconds), (125Hz, 82Hz, 0.7 seconds), (122Hz, 85Hz, 0.9 seconds), (128Hz, 78Hz, 0.6 seconds), (124Hz, 81Hz, 0.8 seconds).

After going through the heart sync technology, the visualization data is expressed as the above heart rate data (130) and the converted heart rate data (140) as follows.

(0, 12)(0.8, 8)(0.8, 12.5)(1.5, 8.2)(1.5, 12.2)(2.4, 8.5)(2.4, 12.8)(3, 7.8)(3, 12.4)(3.8, 8.1)

To visualize the first heart rate data (120 Hz, 80 Hz, 0.8 sec), we can convert 120 Hz to a Y value of 12, 80 Hz to a y value of 8, and 0.8 sec to an x value of 0.8. This gives us two (x,y) coordinates that can be plotted on a graph by connecting the two points with a line. Because the

Figure 7 is a device block diagram of an embodiment in which a heart sync is implemented as a device.

The present invention employing heart sync technology is ultimately the heart sync device 210.

A heartsync device is a device used to monitor and record heart rate using NFC technology. It consists of three main components and has a heart sink device control unit 250 that controls them.

Heart rate receiver 220: This component receives heart rate data from the user's wearable device or other device capable of measuring heart rate, such as a chest strap monitor, finger clip monitor, or smartwatch. The heart rate receiver detects and captures the user's heart rate data 130.

Heart rate converter 230: When heart rate data 130 is received, the heart rate converter generates converted heart rate data in a format that allows the data to be easily interpreted and recorded. This involves converting heart rate data into a standard format and converting timestamp data into cumulative x values that can be displayed on a graph. The transducer can also filter the data and remove noise to ensure accurate readings. The heart rate converter converts heart rate data into converted heart rate data (140).

NFC Recorder 240: This component is responsible for recording heart rate data in a format that can be easily accessed by compatible devices using Near Field Communication (NFC) technology. NFC recorders store heart rate data on an NFC chip and can easily transfer the data to compatible devices such as smartphones or tablets. The recorded data can also be analyzed and interpreted by medical professionals or users to monitor heart health and detect abnormalities.

Figure 8 is a device block diagram of another embodiment in which a heart sync is implemented as a device.

The present invention further proposes a heart rate transmitter 260. When heart rate data is received and converted heart rate data is obtained through a heart rate converter, the heart rate transmitter transmits the data through a communication module so that other users can easily use the data. The heart rate transmitter 260 is advantageous for real-time transmission. The heart rate transmitter can transmit while the NFC recorder is recording, and heart rate data can be transmitted even after the NFC recorder has recorded. The heart rate transmitter 260 can operate separately regardless of whether or not the NFC recorder records.

With reference to the above, the first aspect of the present invention is as follows.

In a heartbeat communication device using a network,

The heart rate data is transmitted from the wearable device 120, which collects heart rate data 130 from the wearer, to HeartSync technology 110, which converts the data into a format that can be used for any of visual, auditory, and tactile displays. , the converted heart rate data 140 is recorded in the NFC 150, and the recorded converted heart rate data 140 is transmitted from the NFC 150 to the visualization unit 160, the audible unit 170, and the tactile unit. A heartbeat communication device using a network, characterized in that it receives information from various output devices such as (180) and interacts with the user through a user interface (190).

The second aspect of the present invention is as follows.

In the first sun,

A heartbeat communication device using a network is,

A heart rate receiver 220 that receives heart rate data from the user's wearable device or other device that can measure heart rate, such as a chest strap monitor, finger clip monitor, or smartwatch; and

When the heart rate data 130 is received by the heart rate receiver, a heart rate converter 230 that converts the data into converted heart rate data 140 in a format that can be easily interpreted and recorded;

An NFC recorder 240 that serves to record the converted heart rate data 140 in a format that can be easily accessed by compatible devices using NFC (Near Field Communication) technology; and

A heart rate communication device using a network comprising a heart rate receiver 220, a heart rate converter 230, and a heart sync device control unit 250 that controls and performs the NFC recorder.

The third aspect of the present invention is as follows.

In the first sun,

A heartbeat communication device using a network is,

A heart rate receiver 220 that receives heart rate data from the first user's wearable device or other device capable of measuring heart rate, such as a chest strap monitor, finger clip monitor, or smartwatch; and

When the heart rate data 130 is received by the heart rate receiver, a heart rate converter 230 that converts the data into converted heart rate data 140 in a format that can be easily interpreted and recorded;

A heart rate transmitter (260) that serves to transmit the converted heart rate data (140) in a format that can be easily accessed by a second user on a compatible device; and

A heart rate communication device using a network, comprising a heart sync device control unit 250 that controls and performs the heart rate receiver 220, the heart rate converter 230, and the heart rate transmitter 260.

Although the present invention has been described above with reference to specific embodiments, it is obvious to those skilled in the art that various changes are possible. Equivalents may be substituted for elements without departing from the true spirit and scope of the invention. Additionally, many modifications may be made without departing from the essential teachings of the invention.

110: Heart sync technology 120: Wearable device 130: Heart rate data 140: Converted heart rate data 150: NFC 160: Visualization unit 170: Audible unit 180 Tactile unit 190: User interface 210: Heart sync device 220: Heart rate receiver 230: heart rate converter

Claims (3)

In a heartbeat communication device using a network,
The heart rate data is transmitted from the wearable device 120, which collects heart rate data 130 from the wearer, to HeartSync technology 110, which converts the data into a format that can be used for any of visual, auditory, and tactile displays. , the converted heart rate data 140 is recorded in the NFC 150, and the recorded converted heart rate data 140 is transmitted from the NFC 150 to the visualization unit 160, the audible unit 170, and the tactile unit. A heartbeat communication device using a network, characterized in that it receives information from various output devices such as (180) and interacts with the user through a user interface (190). In clause 1,
A heartbeat communication device using a network is,
A heart rate receiver 220 that receives heart rate data from the user's wearable device or other device that can measure heart rate, such as a chest strap monitor, finger clip monitor, or smartwatch; and
When the heart rate data 130 is received by the heart rate receiver, a heart rate converter 230 that converts the data into converted heart rate data 140 in a format that can be easily interpreted and recorded;
An NFC recorder 240 that serves to record the converted heart rate data 140 in a format that can be easily accessed by compatible devices using NFC (Near Field Communication) technology; and
A heart rate communication device using a network comprising a heart rate receiver 220, a heart rate converter 230, and a heart sync device control unit 250 that controls and performs the NFC recorder. According to clause 1,
A heartbeat communication device using a network is,
A heart rate receiver 220 that receives heart rate data from the first user's wearable device or other device capable of measuring heart rate, such as a chest strap monitor, finger clip monitor, or smartwatch; and
When the heart rate data 130 is received by the heart rate receiver, a heart rate converter 230 that converts the data into converted heart rate data 140 in a format that can be easily interpreted and recorded;
A heart rate transmitter (260) that serves to transmit the converted heart rate data (140) in a format that can be easily accessed by a second user on a compatible device; and
A heart rate communication device using a network, comprising a heart sync device control unit 250 that controls and performs the heart rate receiver 220, the heart rate converter 230, and the heart rate transmitter 260.