5G and IoT Training Course

This instructor-led, live training in India (online or onsite) is designed for intermediate-level telecom professionals, AI engineers, and IoT specialists who wish to explore how 5G networks accelerate Edge AI applications.

By the end of this training, participants will be able to:

• Understand the fundamentals of 5G technology and its impact on Edge AI.
• Deploy AI models optimized for low-latency applications in 5G environments.
• Implement real-time decision-making systems using Edge AI and 5G connectivity.
• Optimize AI workloads for efficient performance on edge devices.

This instructor-led live training in India (online or onsite) is aimed at business managers who wish to learn only the critical information needed to make important decisions about the adoption of 5G. This course is not a technical course but rather a course on the strategic thinking needed to prepare for the arrival of 5G. The technical coverage and industry coverage will be adapted to the audience.

By the end of this training, participants will be able to:

• Identify the opportunities that 5G brings to the organization.
• Identify the risks that 5G poses to business and industry.
• Understand and distinguish the different technologies and standards underlying 5G.
• Understand the role that 5G will play in the further development of AI and IoT.
• Head up 5G initiatives that lead to improvements in customer service and operational efficiency.
• Initiate a strategy for adopting 5G products and services within the organization as well as across external partner organizations.

This instructor-led live training, accessible via India (online or onsite), is targeted at intermediate-level professionals who aim to understand and evaluate the behavior, scope, and implementation of 5G networks in technical settings.

Upon completing this training, participants will be equipped to:

• Examine how 5G networks behave within clustered settings.
• Gain insight into the specific radio frequency (RF) environment associated with 5G technology.
• Review practical 5G implementation examples from various international markets.
• Evaluate both the capabilities and constraints of 5G coverage.
• Technically interpret and analyze key network quality metrics for 5G.

5G represents the fifth generation of mobile network technology, facilitating faster data speeds, reduced latency, and highly reliable connectivity across a diverse spectrum of applications.

This instructor-led live training, available in both online and onsite formats, is designed for intermediate IT professionals and technical managers seeking to grasp the fundamentals, architecture, and business implications of 5G networks.

Upon completing this training, participants will be equipped with the knowledge and skills to:

• Comprehend the core concepts and evolution of 5G technology.
• Identify the primary components and architecture of 5G networks.
• Distinguish between 4G LTE and 5G regarding performance and design.
• Evaluate 5G use cases and applications across various industries.
• Assess 5G deployment strategies and regulatory considerations.

Course Format

• Interactive lectures and group discussions.
• Case studies and scenario-based exercises.
• Hands-on exploration of 5G network architecture through live demonstrations.

Course Customization Options

• Subject to request, this course can be tailored to focus on specific industry applications or regional 5G deployment contexts.

6G represents the next generation of wireless communication standards, poised to revolutionize IoT ecosystems through ultra-fast connectivity, advanced sensing, and integrated AI capabilities.

This instructor-led, live training (available online or onsite) is designed for advanced-level participants who wish to understand and leverage the emerging intersection of 6G technologies and IoT applications.

By completing this course, learners will gain the ability to:

• Explain the core technical concepts behind 6G.
• Assess how 6G will reshape IoT device communication and architecture.
• Evaluate 6G-enabled IoT use cases across industries.
• Prepare strategies for integrating 6G capabilities into existing IoT solutions.

Format of the Course

• Concept-focused lectures combined with expert discussion.
• Applied exercises designed to reinforce key engineering principles.
• Case-based exploration and scenario analysis in a guided environment.

Course Customization Options

• For tailored versions of this training aligned with your organizational technology roadmap, please contact us to arrange.

Technological advancements and the exponential growth of information are reshaping business operations across numerous sectors, including government. The rate at which governments generate data and archive it digitally is accelerating, driven by the proliferation of mobile devices and apps, smart sensors, cloud computing solutions, and public-facing portals. As digital information expands in volume and complexity, managing, processing, storing, securing, and disposing of it becomes increasingly intricate. Emerging tools for capturing, searching, discovering, and analyzing data are enabling organizations to extract valuable insights from unstructured sources. The government sector is reaching a critical juncture, recognizing information as a strategic asset. Agencies must protect, leverage, and analyze both structured and unstructured data to better serve citizens and meet mission objectives. As government leaders evolve toward data-driven organizations to successfully achieve their missions, they are establishing the framework to correlate dependencies across events, personnel, processes, and information.

High-impact government solutions are emerging from the integration of the most disruptive technologies:

• Mobile devices and applications
• Cloud services
• Social business technologies and networking
• Big Data and analytics

Big Data serves as a key intelligent industry solution, empowering governments to make superior decisions by acting upon patterns revealed through the analysis of vast volumes of data—whether related or unrelated, structured or unstructured.

However, achieving these outcomes requires far more than merely accumulating large amounts of data. "Making sense of these volumes of Big Data requires cutting-edge tools and technologies that can analyze and extract useful knowledge from vast and diverse streams of information," Tom Kalil and Fen Zhao of the White House Office of Science and Technology Policy noted in a post on the OSTP Blog.

The White House took a significant step toward assisting agencies in identifying these technologies by establishing the National Big Data Research and Development Initiative in 2012. This initiative allocated over $200 million to maximize the potential of the Big Data explosion and the tools necessary to analyze it.

The challenges posed by Big Data are nearly as formidable as its promise is encouraging. Efficiently storing data is one such challenge. With budgets often tight, agencies must minimize the cost per megabyte of storage while ensuring data remains easily accessible so users can retrieve it as needed. Backing up massive data volumes further complicates this task.

Effectively analyzing data presents another major challenge. Many agencies utilize commercial tools to sift through vast amounts of data, identifying trends that enhance operational efficiency. (A recent MeriTalk study revealed that federal IT executives believe Big Data could help agencies save over $500 billion while also fulfilling mission objectives.)

Custom-developed Big Data tools are also enabling agencies to meet their analytical needs. For instance, the Oak Ridge National Laboratory’s Computational Data Analytics Group has made its Piranha data analytics system available to other agencies. This system has assisted medical researchers in identifying links that alert doctors to aortic aneurysms before they occur. It is also employed for routine tasks, such as filtering resumes to match job candidates with hiring managers.

This instructor-led, live training in India (online or onsite) is designed for intermediate-level IT professionals and business managers who wish to understand the potential of IoT and edge computing for enabling efficiency, real-time processing, and innovation in various industries.

By the end of this training, participants will be able to:

• Understand the principles of IoT and edge computing and their role in digital transformation.
• Identify use cases for IoT and edge computing in manufacturing, logistics, and energy sectors.
• Differentiate between edge and cloud computing architectures and deployment scenarios.
• Implement edge computing solutions for predictive maintenance and real-time decision-making.

This instructor-led, live training in India (online or onsite) is tailored for intermediate-level developers, system architects, and industry professionals who wish to leverage Edge AI to enhance IoT applications with intelligent data processing and analytics capabilities.

By the conclusion of this training, participants will be equipped to:

• Understand the fundamentals of Edge AI and its application in IoT.
• Set up and configure Edge AI environments for IoT devices.
• Develop and deploy AI models on edge devices for IoT applications.
• Implement real-time data processing and decision-making in IoT systems.
• Integrate Edge AI with various IoT protocols and platforms.
• Address ethical considerations and best practices in Edge AI for IoT.

This instructor-led live training in India (online or onsite) is designed for product managers and developers aiming to decentralise data management to achieve faster performance, leveraging smart devices located on the source network.

Upon completing this training, participants will be capable of:

• Gaining a clear understanding of the core concepts and benefits of Edge Computing.
• Identifying appropriate use cases and examples where Edge Computing can be effectively applied.
• Designing and implementing Edge Computing solutions to accelerate data processing and lower operational costs.

Embedded systems are specialized computing solutions engineered to execute specific tasks within broader frameworks. IoT (Internet of Things) refers to a network of physical devices equipped with sensors and software, enabling them to connect and exchange data over the internet.

This instructor-led, live training (available online or onsite) is designed for beginner-level technical professionals looking to comprehend and implement embedded systems and IoT concepts using C and microcontroller architectures.

Upon completion of this training, participants will be able to:

• Gain insight into the architecture and components of embedded systems.
• Write and compile C code to facilitate interaction with embedded hardware.
• Utilize microcontroller peripherals such as timers and ADCs.
• Understand the role of embedded systems within IoT architectures.

Format of the Course

• Interactive lectures and discussions.
• Extensive exercises and practice sessions.
• Hands-on implementation in a live-lab environment.

Course Customization Options

• To request a customized training for this course, please contact us to arrange.

This instructor-led, live training in India (online or onsite) is designed for intermediate-level professionals who wish to apply Federated Learning to optimize IoT and edge computing solutions.

Upon completion of this training, participants will be able to:

• Grasp the core principles and advantages of Federated Learning in IoT and edge computing.
• Deploy Federated Learning models on IoT devices for decentralized AI processing.
• Minimize latency and enhance real-time decision-making capabilities in edge computing environments.
• Tackle challenges associated with data privacy and network limitations in IoT systems.

The Internet of Things (IoT) constitutes a network infrastructure that wirelessly links physical objects with software applications, enabling them to communicate and exchange data through network communications, cloud computing, and data capture. C is a versatile programming language widely recommended for IoT development due to its widespread adoption and advantages in low-level programming.

In this instructor-led live training, participants will acquire the skills to develop IoT solutions using C.

Upon completing this training, participants will be able to:

• Install and configure NetBeans to program IoT systems using C
• Grasp the fundamental principles of IoT architecture
• Recognize the benefits of employing C in IoT system programming
• Build, test, deploy, and troubleshoot IoT systems using C

Audience

• Developers
• Engineers

Format of the course

• A blend of lectures, discussions, exercises, and extensive hands-on practice

Note

• To request customized training for this course, please contact us to make arrangements.

The Internet of Things (IoT) refers to a network infrastructure that wirelessly connects physical devices with software applications, enabling them to communicate and exchange data through network communication, cloud computing, and data capture. Java, a general-purpose programming language renowned for its "write once, run anywhere" capability, is highly recommended for IoT development due to its portability and efficiency.

In this instructor-led live training, participants will acquire the skills needed to program IoT solutions using Java.

Upon completion of this training, participants will be able to:

• Install and configure tools and frameworks, such as the Eclipse Open IoT Stack, for developing IoT systems with Java
• Grasp the fundamentals of IoT architecture
• Utilize the Eclipse Open IoT Stack for Java to connect and manage devices within an IoT solution
• Build, test, and deploy an IoT system using Java

Audience

• Developers
• Engineers

Course Format

• A blend of lectures, discussions, exercises, and extensive hands-on practice

Note

• To request customized training for this course, please contact us to arrange.

Connected devices are disrupting businesses across the board, with power utilities being no exception. Power utility companies are currently grappling with four major challenges brought about by the rise of IoT.

1. Vendors are increasingly connecting machines, controllers, HMIs, and SCADA systems to the cloud, promising enhanced analytics and insights for predictive and preventative maintenance. However, stringent quarantine policies for critical assets prevent power companies from leveraging these new IoT features offered by machine and controller vendors.
2. With the rapidly decreasing cost of solar and wind power microgrids, utility companies are anticipating a decline in revenue from power generation. To compensate for this loss, companies must aggressively pursue new revenue streams such as energy management for homes as a service, energy storage as a service, and grid services for EV charging or P2P energy trading (between homes, between homes and microgrids, between microgrids, between microgrids and batteries, between homes and batteries, etc.). All of this requires facilitation through smart metering, smart grids, and secure transactions enabled by Distributed Ledger Technology (DLT) like IOTA. Additionally, utilities are exploring offering various smart city services to municipal authorities.
3. For critical infrastructure like dams, ICOLD (International Committee of Large Dams) mandates real-time Structural Health Monitoring (SHM) to provide advance warning of potential collapses or dangers associated with dams, rocks, or tunnels, allowing for the evacuation of affected populations.
4. Another emerging revenue area is EV charging in parking facilities. This module explores how IoT can facilitate smart charging and smart parking solutions.

Over the last three years, IoT engineering has undergone massive changes, primarily driven by Microsoft, Google, and Amazon. These tech giants have invested billions of dollars to develop IoT platforms that are easier to manage and more secure. Furthermore, IoT edge computing has gained significant momentum in both research and deployment as the primary method for practical IoT implementation. The advent of 5G promises to transform the IoT business landscape, leading to unprecedented levels of research funding in this area. Consequently, for any practicing engineer, it is absolutely essential to understand the IoT platforms developed by major players like AWS, Google, and especially Microsoft.

However, none of these platforms offer an exhaustive or completely comprehensive solution for scalable IoT. For instance, deploying smart meters to millions of homes requires additional technologies to secure the smart meters, radio networks, IoT management technology, and many other secured services. The strategy, pricing, and security of any IoT deployment must be optimal and acceptable. Given the vast interdisciplinary knowledge required, it is almost impossible for any single company to assemble a team that can meet all these requirements.

This course is a modest attempt to educate key decision-makers, developers, and security experts on the challenges, risks, and practical methods for deploying IoT in next-generation power utility businesses.

Additionally, as deployment scales, managing IoT services for thousands of sensors and connections has emerged as a distinct engineering subject of research. This area, formerly known as managed IoT services, is experiencing rapid growth because the challenges of scalable IoT are far greater than simply building them. This includes securing over-the-top firmware/software updates, managing sensor and system calibration, auto-diagnosing connection issues, identifying the root cause of API failures, and tracking the hardware and service health of distributed systems, among others.

Course objectives

The main objective of the course is to introduce emerging technological options, platforms, and case studies of IoT implementation in Power Utility Companies, including Smart Metering, Smart Cars, SHM (structural health monitoring), Power Quality Diagnosis, and Smart Contracts. It provides a basic introduction to all elements of IoT—mechanical, electronics/sensor platforms, wireless and wireline protocols, mobile-to-electronics integration, mobile-to-enterprise integration, data analytics, and control plane applications.

1. IoT technology Stacks: Devices, Gateways, Edge, Edge Cloud, Public Cloud, IoT databases, Web & Mobile Applications for IoT, Centralized vs Decentralized IoT
2. IoT ecosystem for Business, third-party device management, risk management of the entire IoT ecosystem
3. M2M Wireless protocols for IoT: WiFi, SigFox, LORA, LPWAN, Zigbee/Zwave, Bluetooth, ANT+: When and where to use which one
4. Fundamentals of IoT Gateways: Risks, Management, and Ecosystem
5. Mobile/Desktop/Web apps for registration, data acquisition, and control – Available M2M data acquisition platforms for IoT: AWS IoT, Azure IoT, Google IoT
6. Security issues and solutions for IoT: Review of security across all technology stacks
7. Enterprise IoT platforms such as Microsoft Azure IoT suites, AWS IoT, Google IoT, Siemens MindSphere
8. Smart Metering, Open Smart Grid Protocols (OSGP), ANSI C2.18 Protocols, NIST Standard for HAN (Home Area Network), Home Plug Powerline Alliance, Security Standard for Smart Meter: IEC 62056
9. Distributed Ledger Technology (DLT) such as Blockchain, HyperLedger, and DAG (Direct Acyclic Graph) for smart contracts, P2P transactions, and smart car charging
10. IoT for critical infrastructure like DAMs, Transformers, Sub-stations, and High Tension Wires

This instructor-led, live training (online or onsite) is aimed at beginner-level and intermediate-level telecom engineers and field professionals who wish to use structured deployment methodologies and industry best practices to successfully install, supervise, integrate, and manage multi-vendor wireless networks from 2G to 5G across operator and enterprise environments.

By the end of this training, participants will be able to:

• Install and configure multi-vendor BTS systems (Huawei, ZTE, Ericsson) from 2G to 5G.
• Supervise site deployment activities and coordinate RF, transmission, power, civil, and core network teams during integration.
• Prepare telecom sites for ATP (Acceptance Test Procedure) and manage operator handover processes.
• Monitor wireless KPIs and manage cluster-based and region-based network operations within commercial and technical reporting structures.