Length: 2 Days
The Internet of Things Training
Most observers in the technological sciences regard IoT (Internet of Things) as one of the most important advances of this century.
Besides touching every aspect of life, IoT also brings people, processes and devices closer to each other. Yet, people not thinking “technology” every day may not see the bigger picture of what’s taking place.
Bill Gates, for example, insisted that the mindset of the government and people has not adjusted to view the future so far, even though technology is exploding in this decade.
In reality, IoT has become a critical part of an enterprise’s digital strategy and every business is keen on leveraging it. The IoT universe churns data and numbers to provide optimal service and value.
IoT’s association with other technologies, pushes its importance even higher. AI and IoT, for instance, not helps in medication adherence, patient monitoring, quality control and biometric security, but also play an important part in making the city efficient.
Taking a deeper look at the IoT, all this is made possible by the interplay between connected components, such as microcontrollers, sensors and actuators, which convert electrical impulses into pressure, motion, temperature or other mechanical parameters.
The IoT ecosystem and resultant systems are complex. IoT systems combine individual devices, databases and gateways linking multiple networks with each other. They are connected to the Internet, usually over a wireless interface, and send data or receive commands.
It’s generally believed that future IoT technology trends will help facilities get maximum efficiency and productivity out of their equipment and manufacturing components. This will translate into immense economic value for industries that adopt IoT.
The evolution of IoT will bring further improvements in mass personalization, virtual prototyping, cybersecurity, vehicle-to-everything (V2X) connectivity, and healthcare.
Edge computing is also expected to play a major role in IoT evolution. Simply put, edge computing allows connected devices to share, calculate, analyze and keep data locally. Edge computing is a kind of hybrid approach to data processing that’s reshaping the future of IoT.
Considering how IoT is spreading into different areas of our lives, we must make sure all connected systems function flawlessly. The need for security will make hybrid data storage especially relevant for sensitive and vital systems like autonomous vehicles and industrial equipment networks where lags can lead to injuries.
The Internet of Things Training Course by Tonex
The Internet of Things (IoT) touches all our lives and will continue to do so in a way that will make today seem a century ago tomorrow.
The Internet of Things Training Course, IoT Training covers what the IoT is about, technology trends, deployments and convergence. Learn how to work with building connected devices, sensors, automation, network interconnection, system security, cybersecurity, data analytics and more.
IoT Training Course attendees will learn about the dynamics of the IoT markets, technology, trends, planning, design and the convergence of platforms and services with a special focus on the product design, architecture and implementation.
This is a fundamental IoT course covering the technologies behind the Internet of Things and connected devices.
What is the Internet of Things (IoT)?
- Concepts and definitions of The Internet of Things (IoT)
- History of IoT
- IoT standards
- Functionalists and structure
- IoT enabling technologies
- IoT architecture
- Major components of IoT
- Hardware, sensors, systems-on-a-chip, firmware, device drivers, application software, connectivity, cloud and security
- Role of wired and wireless communication
- IoT communication and networking protocols
- IoT services and applications
- Big data and analytics
- Cloud computing and the Internet of Things
- Semantic Web 3.0 Standard for M2M and IoT
- IoT Platforms
- Challenges of adapting the concepts
Overview of IoT Connectivity Methods and Technologies
- Wireless 101
- RF 101
- ZigBee PRO, ZigBee 3.0 and ZigBee IP
- Bluetooth and BLE (BT5.0)
- Home Automation (HA) Profile
- Smart Energy (SE) Profile
- Health Care
- IEEE 802.15.4, IEEE 802.15.4e, 802.11ah
- 802.11ah, Wi-Fi HaLow
- Relay Access Point (AP)
- Grouping of stations
- Target Wake Time (TWT)
- Speed Frame Exchange
- GSM, CDMA, GPRS,3G, LTE, small cells, SATCOM
- LTE and 5G
- Sensors and sensor networks
- Serial communication
- Power consumption and optimization
- MIPI, M-PHY, UniPro, SPMI, BIF, SuperSpeed USB Inter-Chip (SSIC), Mobile PCIe (M-PCIe) and SPI
- Wired connectivity
- Real-time systems and embedded software
- Big data
- Cloud computing and storage
- Augmented Reality
Evaluation of IoT
- Mobile integration
- Data visualization
- Convergence with social networks
- Value chain and business models
- User centric cloud based services
- Analytical hierarchy process for technology selection
- End-to-end security
- Integration with IT systems
- Cost/benefit constraints
- End-to-end compatibility
- Application architecture
- Lifecycle solution management
- Real-time response and delay
- IoT and blockchain
- IoT modeling and simulation
- Programming the Internet of Things (IOT)
- IoT wireless & cloud computing
- Industrial IoT on cloud platforms
- Architecting smart IoT devices
- Internet of Things and embedded systems
- IoT and embedded hardware
- IoT python programming for the raspberry pi platform
- Emerging IoT and big data technologies
Other Related Courses
The Internet of Things will fuel technology innovation by creating the means for machines to communicate many different types of information with one another. With all objects in the world connected, lives will be transformed. But the success of IoT depends strongly on standardization, which provides interoperability, compatibility, reliability and effective operations on a global scale.
Recognizing the value of IoT to industry and the benefits this technology innovation brings to the public, the IEEE Standards Association (IEEE-SA) has a number of standards, projects and events that are directly related to creating the environment needed for a vibrant IoT.
Learn how 802.11ah PHY and MAC are optimized for extended range, power efficiency and scalable operation. The new 11ah design enhances link-budget and coverage compared to 2.4GHz technologies. 802.11ah can also support channels with 4, 8, and 16 MHz bandwidth for higher-data rate applications.