Smartwatches, activity trackers like the Fitbit Charge, virtual reality headsets, smart jewelry, web-enabled glasses, and Bluetooth headphones are all examples of the modern wearable technology spectrum. Different types of wearables, those designed for health and fitness or for fun and games, have specialized functions. Most commonly, microprocessors, batteries, and internet connectivity are included into wearable gear to allow for data collection and subsequent synchronization with other devices. The sensors inside wearables can detect motion, collect biometric data for identification purposes, or help you maintain tabs on your position. Most wearables, including activity trackers and smartwatches, are designed to be worn on the wrist and keep tabs on the wearer’s movements and vitals at all times. If you are interested in IoT Development, You can take the help of IoT Development Company in Dubai.
Most wearables are designed to be worn on the body or linked to clothing, however there are some devices that may be used without the wearer’s even touching them. It is still possible to follow a person’s whereabouts with a cell phone, smart tag, or computer. Some wearables use optical sensors to measure heart rate or glucose levels, while others rely on distant smart sensors and accelerometers to monitor movement and speed. All of these wearable technologies share the ability to monitor information in real time.
Wearable Apps for IoT Healthcare
The primary application of the health wearable device app is remote patient monitoring, treatment, and rehabilitation. The patient’s health data is gathered by the sensors and, potentially, partially processed by the device before being uploaded to the cloud for analysis. The device might also get information that helps users decide what to do next. It also has several medical applications, including:
Health Treatment and Rehabilitation Wearable System
Internet of Things rehabilitation devices aid in the upkeep and improvement of a patient’s physical or mental capabilities.
Healthcare Monitoring Wearable Systems
Health-monitoring wearable apps are classified into 4 types based on the type of sensors used.
- Bio-potential sensors: electroencephalography (EEG), electrocardiography (ECG), electromyography (EMG), photoplethysmography (PPG), etc.
- Motion sensors: accelerometer and gyroscope.
- Environmental sensors: ultrasound, pressure, temperature, etc.
- Biochemical sensors: transdermal glucose.
Activity Recognition and sports wearable
Here, the wearables are worn during sports activities to record different metrics of the user/athlete’s training to improve their performance. Also, applications of this cluster consider gathering data regarding recognizing the daily activities of humans and animals.
There are two categories in this.
Wearable apps for daily physical activity tracking
The recognition of daily physical activities is typically focused on tracking routines and body movements related to skeletal muscles, such as moving forward, walking backward, jogging, sleeping, running, going up or down the stairs, bending the waist, the frontal elevation of arms, bending knees, and jumping front or back. It also includes recognition of rest postures, such as sitting, sitting and relaxing, standing, and laying down, or the honor of going from one pose to another, such as going from a standing posture to a sitting one.
Wearable apps for specific sports activities
The potential benefits of wearable apps for athletes, teams, and fans are vast. Regarding sports and fitness, the Internet of Things (IoT) creates an environment where athletes can obtain better training or access data that helps them stay healthier while also allowing coaches to assess ailments or uncover metrics on player performance. It also contributes to a better viewing experience for the audience.
IoT Wearables for tracking and Geofencing
The primary function of this category of wearable apps is online tracking of people and animals. Locating a person or animal that is outfitted with a wearable device is useful in a wide variety of contexts. Some examples of such uses include tracking pets or people, studying a bird’s flight path, locating a resident in a care facility, gauging the flow of visitors at an exhibition, and so on.
Wearable for Emergency Alert
Wearables like those that feature Emergency alert apps are integral to creating a risk-free setting for their users. For instance, a fatigue monitoring system can warn employers and careful drivers who have fallen asleep at the wheel.
The wearable IoT sensors intended for safety mostly focus on three main applications: 1) fall detection and prevention, 2) drowsiness fatigue detection 3) environmental condition monitoring.
The coming together of IoT and Wearable apps
The incorporation of IoT has given wearable technology a greater impact. Wearable Internet of Things technology is one example of a technical advancement that suits the modern digital era. The advanced functionality of today’s wearable devices is all thanks to the IoT. The Internet of Things provides a means of measuring wearable technologies.
Wearable IoT apps with Google Home/Alexa Skills
By using wearable gadgets that connect wirelessly to smart environments, consumers can save considerable time. Virtual assistants like Google Home and Amazon Alexa make it simple to connect wearable apps. Apps like “Smart Door” are great examples.
The future of wearable technology
The use of wearable technology is on the rise and is expected to alter the future drastically. There is much more to the end of technology than the widely accepted fitness trackers, smart smartphones, intelligent clothes, and virtual reality and augmented reality headsets.
The following are some examples of items and ideas from the future that are expected to impact the development of wearable technology significantly:
Bloomberg and The Information reported that Apple Glasses might debut as early as 2023. These augmented reality glasses are made to beam data from the wearer’s mobile device directly onto their eyes. These glasses will pair with an iPhone and superimpose the user’s notifications, apps, and games across their field of view.
One disadvantage of wearing electronic devices is that they must be removed at regular intervals to be charged. Energy harvesting is being studied because it can extend battery life using renewable energy sources like the sun, human movement, or even body heat. In energy harvesting, piezoelectric ceramic converts the vibrations generated by the human body during motion into usable electricity.
Smart contact lenses.
Smart contact lenses that can transmit real-time data to the human eye are on the horizon and look like something out of a science fiction film. Tech heavyweights like Google, Mojo Vision, Samsung, and Sony are developing these soft smart contact lenses to deliver real-time, hands-free information and vision correction via a wireless connection to a user’s smartphone or another external device.
AI for the human brain.
There are currently developed non-invasive sensors integrated with AI to aid with cognitive tasks. Facebook is working on a brain-computer interface to eliminate users’ need to type in status updates physically. Neuralink, a startup founded by Elon Musk, is also developing a similar interface for persons with TBI.