The Internet of Things is a general term used to describe billions of interconnected devices providing data and processing information. Starting with the big picture is daunting and makes deriving requirements for connectivity, communications, management, and security difficult. The IoT open access and applications philosophy requires proper authentication mechanisms in conjunction with a secure software baseline that minimizes security holes and can isolate accidental or malicious failures.
Join us as we discuss a specific "Internet of Things" deployment for a market application and identify requirements, and implementations for interconnection, security, and use cases for efficient and secure utilization within the IoT world.
The Internet of Things (IoT) involves connecting computing devices, machines, objects and people through networked sensors that can transfer data without human interaction. IoT applications include smart homes, wearables, smart cities, smart grids, industrial uses, connected cars, healthcare, retail, supply chains and smart farming. The true value of IoT lies in the data collected from connected devices, which can provide insights and optimize systems like running a hospital efficiently.
Disrupting and Enhancing Healthcare with the Internet of Thingstodbotdotcom
Talk given to graduate students of the Heath, Technology & Engineering program at USC on 6 Mar 2013. Covers some basics of Internet of Things (IoT), some example healthcare-related IoT device, and how IoT can change how we approach healthcare.
Arzoo Sattikar is a third year B.Tech student in Information Technology at College of Engineering, Pune. In her document, she defines Internet of Things as a platform for devices to communicate electronically around the world. She discusses how IoT is used across many industries like education, food, retail, logistics, and more. She also explores how IoT is heading towards connecting over 50 billion devices through IPv6 in the next 5 years and how areas like e-voting, smart grids, and agriculture will utilize IoT. Her internship will focus on incorporating cloud services and identifying influencers in social networks. She concludes that IoT is the future but implementation challenges around safety and security must be addressed.
The document discusses the internet of things (IoT). It defines IoT as embedding short-range mobile transceivers into everyday items to enable new forms of communication between people, things, and between things themselves. IoT combines sensors, connectivity, and people and processes. Sensors act as digital sensory organs that can provide location, visual, and audio data. Applications of IoT include infrastructure management, manufacturing, healthcare, transportation, and more. The advantages are data collection, monitoring, and effective resource use, while limitations include compatibility, complexity, privacy, security, and environmental impact issues.
The document provides an overview of the Internet of Things (IoT). It defines IoT as interconnected devices, objects, and people that are provided with unique identifiers and the ability to transfer data over a network. The document discusses the history of IoT, how it works by connecting sensors and devices to networks for data collection and processing, current and potential benefits, and the growing future of IoT.
The document discusses the Internet of Things (IoT). It defines IoT as a system of interconnected objects that can collect and transfer data over a wireless network without human intervention. It identifies the four main components of IoT as sensors, connectivity, data processing, and user interface. Sensors collect different types of data from the environment. The data is connected to the cloud via various connectivity methods and then processed using software which may send alerts if issues arise. The user interface allows users to monitor the system and resolve any problems. Examples of IoT applications discussed include home automation, smart cities, agriculture, supply chains, and more.
The document discusses the Internet of Things (IoT), including its definition as a network connecting devices through the internet. It provides examples of IoT applications in various areas like automobiles, homes, smart cities, farming and healthcare. The document also outlines the growth of connected devices over time, pros and cons of IoT, and its future potential to create a global nervous system. It concludes by noting both opportunities and remaining challenges to fully realizing the IoT vision.
The Internet of Things is a general term used to describe billions of interconnected devices providing data and processing information. Starting with the big picture is daunting and makes deriving requirements for connectivity, communications, management, and security difficult. The IoT open access and applications philosophy requires proper authentication mechanisms in conjunction with a secure software baseline that minimizes security holes and can isolate accidental or malicious failures.
Join us as we discuss a specific "Internet of Things" deployment for a market application and identify requirements, and implementations for interconnection, security, and use cases for efficient and secure utilization within the IoT world.
The Internet of Things (IoT) involves connecting computing devices, machines, objects and people through networked sensors that can transfer data without human interaction. IoT applications include smart homes, wearables, smart cities, smart grids, industrial uses, connected cars, healthcare, retail, supply chains and smart farming. The true value of IoT lies in the data collected from connected devices, which can provide insights and optimize systems like running a hospital efficiently.
Disrupting and Enhancing Healthcare with the Internet of Thingstodbotdotcom
Talk given to graduate students of the Heath, Technology & Engineering program at USC on 6 Mar 2013. Covers some basics of Internet of Things (IoT), some example healthcare-related IoT device, and how IoT can change how we approach healthcare.
Arzoo Sattikar is a third year B.Tech student in Information Technology at College of Engineering, Pune. In her document, she defines Internet of Things as a platform for devices to communicate electronically around the world. She discusses how IoT is used across many industries like education, food, retail, logistics, and more. She also explores how IoT is heading towards connecting over 50 billion devices through IPv6 in the next 5 years and how areas like e-voting, smart grids, and agriculture will utilize IoT. Her internship will focus on incorporating cloud services and identifying influencers in social networks. She concludes that IoT is the future but implementation challenges around safety and security must be addressed.
The document discusses the internet of things (IoT). It defines IoT as embedding short-range mobile transceivers into everyday items to enable new forms of communication between people, things, and between things themselves. IoT combines sensors, connectivity, and people and processes. Sensors act as digital sensory organs that can provide location, visual, and audio data. Applications of IoT include infrastructure management, manufacturing, healthcare, transportation, and more. The advantages are data collection, monitoring, and effective resource use, while limitations include compatibility, complexity, privacy, security, and environmental impact issues.
The document provides an overview of the Internet of Things (IoT). It defines IoT as interconnected devices, objects, and people that are provided with unique identifiers and the ability to transfer data over a network. The document discusses the history of IoT, how it works by connecting sensors and devices to networks for data collection and processing, current and potential benefits, and the growing future of IoT.
The document discusses the Internet of Things (IoT). It defines IoT as a system of interconnected objects that can collect and transfer data over a wireless network without human intervention. It identifies the four main components of IoT as sensors, connectivity, data processing, and user interface. Sensors collect different types of data from the environment. The data is connected to the cloud via various connectivity methods and then processed using software which may send alerts if issues arise. The user interface allows users to monitor the system and resolve any problems. Examples of IoT applications discussed include home automation, smart cities, agriculture, supply chains, and more.
The document discusses the Internet of Things (IoT), including its definition as a network connecting devices through the internet. It provides examples of IoT applications in various areas like automobiles, homes, smart cities, farming and healthcare. The document also outlines the growth of connected devices over time, pros and cons of IoT, and its future potential to create a global nervous system. It concludes by noting both opportunities and remaining challenges to fully realizing the IoT vision.
Droidcon: Nick Hunn: Evolving past the fingertip- 29/10/2010Skills Matter
New wireless standards are about to produce a generation of connected devices that we wear, carry with us, or have around the home, which can talk directly to the handset and to an Android application.
The document provides a beginner's guide to the Internet of Things (IoT). It defines IoT as web-enabled devices that collect and share data using embedded sensors and communication hardware. It then describes how IoT works in 4 steps: 1) devices communicate with each other and act on shared data, 2) humans can interact with devices but they operate autonomously, 3) devices generate vast amounts of Internet traffic including usable data, 4) the technology enables real-time monitoring for safety and infrastructure monitoring. The document predicts that 50-100 billion devices will connect in the next 5 years, creating $10 trillion in business opportunities and revolutionizing industries from consumer products to manufacturing.
This document discusses key concepts related to the Internet of Things (IoT), including radio frequency identification (RFID) tags, sensors, and how smartphones and mobile apps will enable IoT devices to work together. It describes how RFID tags use radio waves to transmit data without direct line of sight, and the differences between passive and active tags. It also explains how sensors will detect changes in environments and trigger automated responses. Finally, it outlines efforts by the AllSeen Alliance to develop open standards and frameworks, like AllJoyn, to ensure interoperability between IoT devices from different manufacturers.
From The Guardian to Cisco, big business to small, it seems that everybody is talking about the Internet of Things — but what exactly is IoT and why does it matter?
Taking a deep dive, we explore the many faces of IoT in Healthcare. Technology research and advisory company, Gartner, currently place the Internet of Things at the peak of inflated expectations and there are certainly challenges. But IoT also holds real promise for healthcare and it is already making an impact today.
We demonstrate why the Internet of Things has a far reaching impact across all determinants of health and how it could lead to a broader model of healthcare. We look at some of the technologies that are available to buy or that are already in development today, whilst also exploring some of the very real challenges that integrating such technologies into healthcare presents. Finally, we offer some ideas about how you can get involved, whether you are a healthcare professional or not.
The document discusses how the Internet of Things (IoT) can transform healthcare. IoT uses sensors, connectivity, and data analysis to generate insights from real-time patient and medical equipment data. This allows for remote monitoring of patients, automation of healthcare processes, and more accurate decision making. Implementing IoT in healthcare can improve patient experiences and outcomes, reduce costs, and address challenges like physician burnout.
topics discussed:
internet of things the future.
is IOT a fad?
future opportunities for internet of things
market size of internet of things.
current market.
obstacles in internet of things
The document discusses the topic of the Internet of Things (IoT). It defines IoT as connecting devices to the internet to allow them to interact, collaborate and share data. It provides examples of IoT applications in various domains like smart homes, healthcare, smart cities, agriculture and industrial automation. The document also outlines some of the benefits of IoT for businesses, the large scope and growth potential of IoT, and some challenges and criticisms regarding privacy, security and lack of standards.
In this slide, i have show you basic definition of Internet of things as well as applications of internet of things which are currently trending like Iot in field of Healthcare and wearables and waste management and many more and challenges that a IOT project or product faces in implementation and different protocols which are generally used in field of Internet of things.
The document outlines a lecture on the Internet of Things (IoT). It defines IoT as a system of connected devices that can collect and share data without human intervention. Examples include smart refrigerators and air conditioners. The reasons for IoT include human desires for comfort, convenience, and remote control capabilities. IoT devices use sensors to collect real-time data and have unique IDs to enable communication. While challenges exist, IoT has many applications like environmental monitoring and can transform businesses and lives.
The document discusses the evolution of digital transformation and the impact of technologies like the Internet of Things (IoT). It explains that networks form the foundation of the digitized world and connect millions of devices. The IoT allows smart devices and sensors to collect and exchange data without human intervention. This creates opportunities but also challenges around managing large amounts of "Big Data" securely across networks and clouds.
The Internet of Things allows physical objects embedded with software and sensors to connect to the internet and exchange data. This enables objects to be remotely monitored and controlled through existing network infrastructure, improving efficiency. Internet of Things devices do not directly connect to the traditional internet, but instead use dedicated networks to share information with specific applications. The future of IoT is promising as more everyday objects are networked together.
This document discusses the Internet of Things (IoT). It defines IoT as a system of interconnected computing devices, machines, objects, animals, and people that are provided with unique identifiers and the ability to transfer data over a network. It notes that IoT affects different industries in various ways, such as helping manufacturing organizations track tools and machines. The document also outlines some challenges of IoT, such as managing the lifecycle of collected data and addressing security vulnerabilities. Finally, it explains that IoT works by assigning static IP addresses to connected objects and machines to enable them to share data over the Internet.
Internet of things: our savior or destroyer?Liam Weld
The document discusses the potential impacts of the Internet of Things (IoT). It notes that by 2020, 50 billion devices will be connected to the internet and $1.9 trillion in value will be added globally. However, it also raises concerns that connecting everyday devices to the internet introduces security risks, as devices could potentially be hacked and used to endanger lives. While IoT provides benefits by increasing knowledge and improving industries like healthcare, energy, and entertainment, security must be addressed seriously to prevent potential hacking of devices like cars or medical implants. The document argues that IoT should be embraced if these risks can be properly managed.
In this presentation, Tejaswi talks about the importance of establishing standards before achieving ground breaking innovation using Internet of Things.
The document discusses several ways that the Internet of Things (IOT) can impact different areas:
1) IOT will help improve access to and quality of healthcare and education by utilizing connected smart devices to improve patient care and reduce strain on healthcare systems.
2) IOT allows for enhanced data collection from a variety of sensors that provide a more accurate picture of everything compared to traditional passive data collection methods.
3) Areas of waste and inefficiency can be identified through IOT data leading to more effective resource management.
The document discusses the Internet of Things (IoT). It defines IoT as the network of physical objects embedded with electronics, software, and sensors that allows them to connect, exchange data and be controlled remotely. It describes how IoT works and provides examples of applications such as smart homes, infrastructure management, healthcare, transportation and agriculture. The document also outlines some challenges to IoT implementation including data security, ownership and technical difficulties in sensing environments and ensuring connectivity. It predicts that IoT will become integrated into everyday life as technologies become more invisible and interconnected, and will transform sectors like healthcare, home automation, and more.
Future of Digital Healthcare on Cloud .pdfayushiqss
Healthcare has been an integral part of the discussion and a transformative force towards innovation. With increasing advancements and awareness, people are becoming more conscious about their choices, what they eat, and where and how to get the best treatment facilities. This brings the need to provide the best healthcare services, disease detection, and the right treatment, with the best tools and hospital staff. The internet has played a significant role in serving such kinds of top-notch consumer needs. One of these internets of things is Cloud Technology. Let’s look at cloud computing in healthcare, models of cloud computing and how it has transformed the digital healthcare sector.
Wireless sensor technology is now used widely to collect data from remote locations on variables like temperature, sound and pressure. Wireless sensors transmit this data via software which can then analyze the information. Some key uses of wireless technology include cellular networks for mobile phones, cloud services which store data remotely, and wireless control systems which can manage organizations from a distance at lower costs than traditional staffing methods. Wireless leak detection systems are also useful applications, as they can automatically detect and shut off water when leaks develop in home piping systems.
Droidcon: Nick Hunn: Evolving past the fingertip- 29/10/2010Skills Matter
New wireless standards are about to produce a generation of connected devices that we wear, carry with us, or have around the home, which can talk directly to the handset and to an Android application.
The document provides a beginner's guide to the Internet of Things (IoT). It defines IoT as web-enabled devices that collect and share data using embedded sensors and communication hardware. It then describes how IoT works in 4 steps: 1) devices communicate with each other and act on shared data, 2) humans can interact with devices but they operate autonomously, 3) devices generate vast amounts of Internet traffic including usable data, 4) the technology enables real-time monitoring for safety and infrastructure monitoring. The document predicts that 50-100 billion devices will connect in the next 5 years, creating $10 trillion in business opportunities and revolutionizing industries from consumer products to manufacturing.
This document discusses key concepts related to the Internet of Things (IoT), including radio frequency identification (RFID) tags, sensors, and how smartphones and mobile apps will enable IoT devices to work together. It describes how RFID tags use radio waves to transmit data without direct line of sight, and the differences between passive and active tags. It also explains how sensors will detect changes in environments and trigger automated responses. Finally, it outlines efforts by the AllSeen Alliance to develop open standards and frameworks, like AllJoyn, to ensure interoperability between IoT devices from different manufacturers.
From The Guardian to Cisco, big business to small, it seems that everybody is talking about the Internet of Things — but what exactly is IoT and why does it matter?
Taking a deep dive, we explore the many faces of IoT in Healthcare. Technology research and advisory company, Gartner, currently place the Internet of Things at the peak of inflated expectations and there are certainly challenges. But IoT also holds real promise for healthcare and it is already making an impact today.
We demonstrate why the Internet of Things has a far reaching impact across all determinants of health and how it could lead to a broader model of healthcare. We look at some of the technologies that are available to buy or that are already in development today, whilst also exploring some of the very real challenges that integrating such technologies into healthcare presents. Finally, we offer some ideas about how you can get involved, whether you are a healthcare professional or not.
The document discusses how the Internet of Things (IoT) can transform healthcare. IoT uses sensors, connectivity, and data analysis to generate insights from real-time patient and medical equipment data. This allows for remote monitoring of patients, automation of healthcare processes, and more accurate decision making. Implementing IoT in healthcare can improve patient experiences and outcomes, reduce costs, and address challenges like physician burnout.
topics discussed:
internet of things the future.
is IOT a fad?
future opportunities for internet of things
market size of internet of things.
current market.
obstacles in internet of things
The document discusses the topic of the Internet of Things (IoT). It defines IoT as connecting devices to the internet to allow them to interact, collaborate and share data. It provides examples of IoT applications in various domains like smart homes, healthcare, smart cities, agriculture and industrial automation. The document also outlines some of the benefits of IoT for businesses, the large scope and growth potential of IoT, and some challenges and criticisms regarding privacy, security and lack of standards.
In this slide, i have show you basic definition of Internet of things as well as applications of internet of things which are currently trending like Iot in field of Healthcare and wearables and waste management and many more and challenges that a IOT project or product faces in implementation and different protocols which are generally used in field of Internet of things.
The document outlines a lecture on the Internet of Things (IoT). It defines IoT as a system of connected devices that can collect and share data without human intervention. Examples include smart refrigerators and air conditioners. The reasons for IoT include human desires for comfort, convenience, and remote control capabilities. IoT devices use sensors to collect real-time data and have unique IDs to enable communication. While challenges exist, IoT has many applications like environmental monitoring and can transform businesses and lives.
The document discusses the evolution of digital transformation and the impact of technologies like the Internet of Things (IoT). It explains that networks form the foundation of the digitized world and connect millions of devices. The IoT allows smart devices and sensors to collect and exchange data without human intervention. This creates opportunities but also challenges around managing large amounts of "Big Data" securely across networks and clouds.
The Internet of Things allows physical objects embedded with software and sensors to connect to the internet and exchange data. This enables objects to be remotely monitored and controlled through existing network infrastructure, improving efficiency. Internet of Things devices do not directly connect to the traditional internet, but instead use dedicated networks to share information with specific applications. The future of IoT is promising as more everyday objects are networked together.
This document discusses the Internet of Things (IoT). It defines IoT as a system of interconnected computing devices, machines, objects, animals, and people that are provided with unique identifiers and the ability to transfer data over a network. It notes that IoT affects different industries in various ways, such as helping manufacturing organizations track tools and machines. The document also outlines some challenges of IoT, such as managing the lifecycle of collected data and addressing security vulnerabilities. Finally, it explains that IoT works by assigning static IP addresses to connected objects and machines to enable them to share data over the Internet.
Internet of things: our savior or destroyer?Liam Weld
The document discusses the potential impacts of the Internet of Things (IoT). It notes that by 2020, 50 billion devices will be connected to the internet and $1.9 trillion in value will be added globally. However, it also raises concerns that connecting everyday devices to the internet introduces security risks, as devices could potentially be hacked and used to endanger lives. While IoT provides benefits by increasing knowledge and improving industries like healthcare, energy, and entertainment, security must be addressed seriously to prevent potential hacking of devices like cars or medical implants. The document argues that IoT should be embraced if these risks can be properly managed.
In this presentation, Tejaswi talks about the importance of establishing standards before achieving ground breaking innovation using Internet of Things.
The document discusses several ways that the Internet of Things (IOT) can impact different areas:
1) IOT will help improve access to and quality of healthcare and education by utilizing connected smart devices to improve patient care and reduce strain on healthcare systems.
2) IOT allows for enhanced data collection from a variety of sensors that provide a more accurate picture of everything compared to traditional passive data collection methods.
3) Areas of waste and inefficiency can be identified through IOT data leading to more effective resource management.
The document discusses the Internet of Things (IoT). It defines IoT as the network of physical objects embedded with electronics, software, and sensors that allows them to connect, exchange data and be controlled remotely. It describes how IoT works and provides examples of applications such as smart homes, infrastructure management, healthcare, transportation and agriculture. The document also outlines some challenges to IoT implementation including data security, ownership and technical difficulties in sensing environments and ensuring connectivity. It predicts that IoT will become integrated into everyday life as technologies become more invisible and interconnected, and will transform sectors like healthcare, home automation, and more.
Future of Digital Healthcare on Cloud .pdfayushiqss
Healthcare has been an integral part of the discussion and a transformative force towards innovation. With increasing advancements and awareness, people are becoming more conscious about their choices, what they eat, and where and how to get the best treatment facilities. This brings the need to provide the best healthcare services, disease detection, and the right treatment, with the best tools and hospital staff. The internet has played a significant role in serving such kinds of top-notch consumer needs. One of these internets of things is Cloud Technology. Let’s look at cloud computing in healthcare, models of cloud computing and how it has transformed the digital healthcare sector.
Wireless sensor technology is now used widely to collect data from remote locations on variables like temperature, sound and pressure. Wireless sensors transmit this data via software which can then analyze the information. Some key uses of wireless technology include cellular networks for mobile phones, cloud services which store data remotely, and wireless control systems which can manage organizations from a distance at lower costs than traditional staffing methods. Wireless leak detection systems are also useful applications, as they can automatically detect and shut off water when leaks develop in home piping systems.
Wireless sensor technology is now used widely to collect data from remote locations on variables like temperature, sound and pressure. Wireless sensors transmit this data via software which can then analyze the information. Some key uses of wireless technology include cellular networks for mobile phones, cloud services which store data remotely, and wireless control systems which can manage organizations from a distance at lower costs than traditional staffing models. Wireless leak detection systems are also common, using sensor networks to automatically detect and shut off water if leaks develop in home piping systems.
Wireless sensor technology is now used widely to collect data from remote locations on variables like temperature, sound and pressure. Wireless sensors transmit this data via software which can then analyze the information. Some key uses of wireless technology include cellular networks for mobile phones, cloud services which store data remotely, and wireless control systems which can manage organizations from a distance at lower costs than traditional staffing models. Wireless leak detection systems are also now common, using sensor networks to automatically detect and shut off water if leaks develop in home plumbing systems.
The document discusses the emerging concept of the "Internet of Things" and the role of "sentrollers" (sensors, actuators, and controllers) within it. It notes that the number of devices connected to the internet is shifting from being primarily people-operated to including a vast number of machine-connected things. These things will largely consist of low-data sentrollers that sense and control physical environments and systems. The smart home is presented as an early application, with sentrollers around the home beginning to connect to utilities and service providers over the internet. This will allow remote monitoring and control of home functions but places importance on long battery life and low-cost connectivity of sentrollers.
The document discusses several future challenges in computer science including mobile and cloud computing, data security, networking infrastructure, big data, and healthcare applications. It notes that as digital technologies expand, computer science must address issues like updating networks for higher speeds, protecting sensitive data, analyzing vast amounts of data, and using data to improve healthcare. Potential solutions involve changes like software-defined networking, larger fiber optic cables, improved data visualization and mining tools, and clinical data sharing to aid diagnosis. Overall, properly addressing these challenges can lead to organizational improvements and benefits to society.
What is Internet of Things?
History
How IoTWorks?
Few Applications of IoT
Current Status & Future Prospect of IoT
Technological Challenges of IoT
Criticisms & Controversies of IoT
Technology in Education Technology Presentation in Blue Peach Illustrative St...MaryroseVicente6
The document discusses the importance of computers in daily life and how they have become essential tools in homes and businesses. It notes how computers have led to the digitization and electronic processing of transactions across many fields like education, health, and more. Computers are also described as important sources of knowledge since they can access the internet to find written, audio, and visual information online. The current era is characterized as the information age due to computers becoming basic elements of human life.
Computer science is faced with many challenges as the digital universe expands. From mobile and cloud computing to data security, addressing these issues can require large, structural changes, but an examination of these problems can lead to organizational solutions and improvements in the world.
This eBook covers different IoT uses, how they apply to buildings, and how to evaluate the technologies to ensure good decision making for your building.
Computer science faces many challenges as technology expands. Mobile and cloud computing, data security, and networking all require improvements to handle growing data and usage. By 2020, the digital universe could contain 40,000 exabytes of data, requiring better analysis tools and data visualization. While these issues seem daunting, addressing problems in areas like healthcare data could help improve treatment of diseases.
Computer science faces many challenges as technology expands. Mobile and cloud computing, data security, and networking all require improvements to handle growing data and usage. By 2020, the digital universe could contain 40,000 exabytes of data, requiring better analysis tools and data visualization. While these issues seem daunting, addressing problems in areas like healthcare data could help improve treatment for diseases.
This document discusses computer networks and communications. It begins by defining a computer network as a system that connects interconnected computers and peripheral devices to communicate and share information and resources. There are three main types of networks: local area networks (LANs) which cover a small area like a building; metropolitan area networks (MANs) which connect LANs within a larger area like a city; and wide area networks (WANs) which are the largest and connect LANs or MANs across large distances like countries or continents. The document then discusses network architectures, focusing on client/server networks where shared files and applications are stored on a server and accessed by client computers, and peer-to-peer networks where all nodes can
A computer network connects multiple computers and devices to allow sharing of resources and communication between users. There are three main types of networks - local area networks (LANs), metropolitan area networks (MANs), and wide area networks (WANs). LANs cover small physical areas like a home or office building. MANs encompass larger areas like a city. WANs have the largest geographical reach such as between countries. Common network architectures include client-server, where file storage and services are centralized on server computers, and peer-to-peer where computers directly share files and resources without a central server.
This document provides an overview of building an Internet of Things (IoT) system. It discusses connecting a device to the cloud using a message broker. It describes how the cloud can send messages back using services like AWS Simple Notification Service. It also covers storing sensor data in the cloud using databases and performing analytics on the data. The document notes that technology changes can sometimes cause issues and provides an example of when the author encountered such an issue with analytics interfaces changing.
This includes short description about modern computer network technologies like: 5G Technology, Artificial intelligence (AI), Augmented Reality and Virtual Reality, IoT, Edge/cloud computing, WIFI-6, SDN, SD-WAN, DevOps etc.
The document discusses key concepts related to the Internet of Things (IoT). It describes IoT as connecting everyday physical objects to the internet through sensors and software. This allows objects to collect and exchange data. The document outlines some challenges with IoT, such as privacy, security, standards and regulation. It emphasizes the importance of collaborative and multistakeholder approaches to address these challenges.
Fog Computing is a paradigm that extends Cloud computing and services to the edge of the network. Similar to Cloud, Fog provides data, compute, storage, and application services to end-users. The motivation of Fog computing lies in a series of real scenarios, such as Smart Grid, smart traffic lights in vehicular networks and software defined networks,
Fog computing is a term created by Cisco that refers to extending cloud computing to the edge of an enterprise's network.
Cisco introduced its fog computing vision in January 2014 as a way of bringing cloud computing capabilities to the edge of the network .
As the result, closer to the rapidly growing number of connected devices and applications that consume cloud services and generate increasingly massive amounts of data.
A concept based on the vision described by Mark Weiser nearly a decade ago:
“The most profound technologies are those that disappear. They weave themselves into the fabric of everyday life until they are indistinguishable from it”
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DECLARATION OF HELSINKI - History and principlesanaghabharat01
This SlideShare presentation provides a comprehensive overview of the Declaration of Helsinki, a foundational document outlining ethical guidelines for conducting medical research involving human subjects.
The skin is the largest organ and its health plays a vital role among the other sense organs. The skin concerns like acne breakout, psoriasis, or anything similar along the lines, finding a qualified and experienced dermatologist becomes paramount.
Travel vaccination in Manchester offers comprehensive immunization services for individuals planning international trips. Expert healthcare providers administer vaccines tailored to your destination, ensuring you stay protected against various diseases. Conveniently located clinics and flexible appointment options make it easy to get the necessary shots before your journey. Stay healthy and travel with confidence by getting vaccinated in Manchester. Visit us: www.nxhealthcare.co.uk
Osteoporosis - Definition , Evaluation and Management .pdfJim Jacob Roy
Osteoporosis is an increasing cause of morbidity among the elderly.
In this document , a brief outline of osteoporosis is given , including the risk factors of osteoporosis fractures , the indications for testing bone mineral density and the management of osteoporosis
8 Surprising Reasons To Meditate 40 Minutes A Day That Can Change Your Life.pptxHolistified Wellness
We’re talking about Vedic Meditation, a form of meditation that has been around for at least 5,000 years. Back then, the people who lived in the Indus Valley, now known as India and Pakistan, practised meditation as a fundamental part of daily life. This knowledge that has given us yoga and Ayurveda, was known as Veda, hence the name Vedic. And though there are some written records, the practice has been passed down verbally from generation to generation.
Mercurius is named after the roman god mercurius, the god of trade and science. The planet mercurius is named after the same god. Mercurius is sometimes called hydrargyrum, means ‘watery silver’. Its shine and colour are very similar to silver, but mercury is a fluid at room temperatures. The name quick silver is a translation of hydrargyrum, where the word quick describes its tendency to scatter away in all directions.
The droplets have a tendency to conglomerate to one big mass, but on being shaken they fall apart into countless little droplets again. It is used to ignite explosives, like mercury fulminate, the explosive character is one of its general themes.
Promoting Wellbeing - Applied Social Psychology - Psychology SuperNotesPsychoTech Services
A proprietary approach developed by bringing together the best of learning theories from Psychology, design principles from the world of visualization, and pedagogical methods from over a decade of training experience, that enables you to: Learn better, faster!
These lecture slides, by Dr Sidra Arshad, offer a simplified look into the mechanisms involved in the regulation of respiration:
Learning objectives:
1. Describe the organisation of respiratory center
2. Describe the nervous control of inspiration and respiratory rhythm
3. Describe the functions of the dorsal and respiratory groups of neurons
4. Describe the influences of the Pneumotaxic and Apneustic centers
5. Explain the role of Hering-Breur inflation reflex in regulation of inspiration
6. Explain the role of central chemoreceptors in regulation of respiration
7. Explain the role of peripheral chemoreceptors in regulation of respiration
8. Explain the regulation of respiration during exercise
9. Integrate the respiratory regulatory mechanisms
10. Describe the Cheyne-Stokes breathing
Study Resources:
1. Chapter 42, Guyton and Hall Textbook of Medical Physiology, 14th edition
2. Chapter 36, Ganong’s Review of Medical Physiology, 26th edition
3. Chapter 13, Human Physiology by Lauralee Sherwood, 9th edition
7. Well, first of all, a number
of things changed…
• The way that we connect changed (cellular &
wireless technology).
• The speed at which we connect improved (the
speed at which data transfers exploded).
• The size of the hardware that we use to
connect shrank (PC devices became smaller).
• ‘Cloud Computing’ began to advance rapidly
(making small devices even more powerful).
8. The way that we used to connect was
restrictive & awkward…
Cables, cables and more cables! LQQK! No more cables!
9. When we connect today, the speed that
data transfers has increased dramatically!
Before 2000 … From 2000 to 2010 + …
10. When you need information, it is available on
your device faster than ever before!
11. The size of the devices that we connect
with has decreased dramatically!
1993 Hardware vs 2008 Hardware…
12. Finally… ‘Cloud Computing’, an extension of classic
client/server networking, makes these smaller, faster,
wireless devices that we use even more powerful!
13. With Cloud Computing, or even
classic client/server computing, …
• We can connect very small computer devices, wirelessly, to
much larger computers (servers) on the network.
• These small wireless devices now transfer information so
quickly from the larger computer, that it’s the same as if we
were logged on directly to the larger computer!
• Our smaller computers act almost only as a ‘looking glass’
into the larger computer (server).
• This means, there is virtually no limit to what can be
performed with the smaller computer device anymore!
14. As all of these things began to change, the
internet became a lot more useful and fun for
people…
And older concepts, like Healthcare Technology,
made more sense to implement!
15. The types of mobile healthcare devices
that we can connect are astounding!
16. Wireless Tablets Wireless Laptops
Wireless Smartphones Wireless body sensors
17. We can even use wireless sensors to monitor the
patient’s vital signs remotely!
Click Here To learn More About Wireless Body Networking!
18. Then, if we wanted to communicate live with the
patient, we could establish a telemedicine video link!
19. Most practitioners use a variety of
information to render a medical
diagnosis…
• Lab results (like blood work & biopsies)
• Vital signs
• Information gathered verbally
• Visual inspection
20. With today’s Mobile
Healthcare
Technology, all of
that information
can be made
available to the
practitioner
without the need to
actually physically
see the patient!