KR-20260064359-A - Wearable Device:Smart Necklace to measure the health protection figures suitable to and the medicinal status for the individuals

Abstract

This is a wearable medical device tailored to the wearer's daily life, utilizing various sensors to integrate personalized medicine into everyday life, a feat that was difficult to achieve with existing wearable devices. By incorporating customized technologies such as Arduino algorithms and data mining, it reflects an individual's health status in the device in real time. Furthermore, equipped with features such as habit feedback, information on diseases of concern and hospitals, and an automatic emergency reporting function, it ensures that the "golden hour" in crisis situations is not missed, regardless of age. Since measurements are taken from the chest, the accuracy is higher than any other part of the body, minimizing the risk of misdiagnosis or overtreatment at secondary hospitals later on.

Inventors

• 김동현

Assignees

• 김동현

Dates

Publication Date

20260507

Application Date

20241031

Claims (1)

1. Based on real-time measurements from the built-in artificial intelligence, it displays the heart rate as a gauge movement in the form of an equalizer, and features a red gauge-increasing display widget for heart rate measurement that allows for intuitive status checking not only in daily life but also in crisis situations; A composite display widget for reflecting calorie consumption and exercise levels, in which the target calorie consumption is indicated by a gradual decrease in the yellow gauge and the target exercise (e.g., pedometer) level is indicated by a gradual decrease in the orange gauge; A danger indicator color light that is displayed in pink when the body enters a dangerous state based on heart rate, respiratory rate, etc., but is displayed in gray during normal conditions; A front light that emits light to enable immediate recognition by the surroundings if in danger during nighttime activities, and a front camera that can be utilized by first responders to assist in medical diagnosis after transport and can also be used for security purposes; Includes dual speakers on both sides installed so that AI can ring a distress bell to request help from a distance, anticipating even cases where it is difficult to find with only a single light. Wearable device.

Description

Wearable Device: Smart Necklace to measure personalized health protection figures and medical status The present invention relates to a wearable device and is an invention related to smart medical engineering because it is equipped with a real-time measurement and analysis tool of artificial intelligence and an automatic structure function. The wearable device measures and analyzes heart rate, respiratory rate, blood glucose, calories consumed, and exercise volume in real time using artificial intelligence. This includes Arduino algorithms, various technologies recently emerging in smart healthcare (such as sensors and data mining technologies), and other medical AI-related models (such as big data-based personalized models). Figure 1 is a drawing showing a necklace, which is a type of device of the present invention. First, I would like to provide a detailed description of the drawings. In this necklace (1), stainless steel material, which is harmless to the human body enough to be used even during surgical procedures, is used for the fixed bezel (2), the rotating bezel (5), and the connection part (3) of the device. In particular, the rotating bezel covers situations where touch is difficult, such as when wearing gloves. The necklace chain (4) is a vegan leather chain with a minimum length of 60 cm, and vegan leather has the following advantages. It is durable enough to be used without worry even in summer because there is little concern about damage from moisture. Furthermore, it is an eco-friendly material that targets the next generation and meets the requirements of the recently emerging ESG management and UN-SDGs, and it is much cheaper than real leather used in the body connection parts of existing wearable devices. The external and internal configuration of the display (7) is as follows. The outer part of the liquid crystal uses Gorilla Glass SR+, which is highly durable and relatively inexpensive. The inner part of the liquid crystal is Super AMOLED, which has low power consumption, and the refresh rate has been lowered from 120Hz, which is used in flagship smartphone lineups, to remain faithful to core functions. That is, the maximum refresh rate of the present invention is set to 60Hz, which is the minimum refresh rate of a smart device. The touch screen function is the default. There is a red gauge widget (13) that displays the individual's heart rate in the form of a gauge bar filling up. There are orange and yellow gauge widgets (14) that display the measurement of target exercise values as well as calories consumed and consumed in the form of a gauge bar decreasing. There is a danger indicator color light (11) that visualizes the user's abnormal condition by displaying normal in gray and abnormal in pink. The security bell function, which diffuses sound through the front light (12), camera (10), and dual speakers (15, 16) facing each other in a plane, is useful for requesting rescue regardless of day or night. The power button (6) and the sound control button (17) face each other in a plane. The app (8) icon is circular. The dotted line indicates the remaining side cross-section portion that is not visible when assuming the three-dimensional structure of the drawing. Secondly, I would like to explain the specific internal features. Equipped with NFC functionality, the device is configured to allow payments to be made immediately after receiving medical treatment. By introducing the Always-on Display feature, short specific messages (such as the user's name or disease precautions) can be displayed on the screen when not in use. Regarding the processors (CPU, GPU) that govern the device's functionality and actual lifespan, maximum, median, and minimum values were set, taking into account manufacturers and production costs. Qualcomm's Snapdragon Wear 4100+ was set as the maximum-value processor, while the first-generation Snapdragon W5+ was assumed as the median processor. For the minimum-value processor, MediaTek's Dimensity 720—for which TSMC of Taiwan handles the manufacturing process—was selected to achieve both cost reduction and functionality. The device's overall finish material was set to Glasstic. Glasstic is a relatively inexpensive material that offers higher durability compared to glass. Furthermore, it was selected to provide a more luxurious gloss than plastic, anticipating that focusing solely on cost reduction for the sake of the price point could potentially alienate consumer preferences. The material was determined by considering not only commercial viability but also actual sales volume. The front camera was set to a 14-megapixel lens, and based on the dual speakers mounted on both sides of the device, we embarked on maximizing the structural functionality of the security bell to expand the sound resonance range. In particular, the security bell operates via voice recognition under normal circumstances, but activates automatically if personalized health protection metrics are