SVIC Blog

The Transformative Impact of 5G on IoT

Written by Silicon Valley Innovation Center | Aug 21, 2024 10:27:08 PM

Have you ever wondered how you can operate your electronic appliances such as turn on AC using a mobile app from anywhere, track your fitness on your mobile through a smartwatch, or receive alerts on your phone about a fire or water leak in your home or factory? These everyday conveniences are made possible by a technology called the Internet of Things (IoT). From enhancing home automation to revolutionizing industrial operations, IoT is at the forefront of building smarter environments.

In this blog, we will explore the incredible potential of IoT and how it is transforming various aspects of the IT industry.

The Evolution of Connectivity

The Internet of Things (IoT) connects everyday objects to the internet, allowing them to send and receive data. This concept began in the 1980s with an internet-connected Coke machine at Carnegie Mellon University. In 1999, Kevin Ashton coined the term "IoT," envisioning a world where not only computers but also everyday items could connect to the internet. This network includes everything from smart thermostats and security systems to industrial machinery and smart city infrastructure, making our lives more convenient, efficient, and safer.

The journey of connectivity began with Ethernet, providing reliable wired connections for local networks. Early IoT devices were connected using Ethernet cables. These devices collected and transmitted data within localized networks. They offered reliable and secure data transfer but lacked mobility.

Wi-Fi and Bluetooth revolutionized wireless communication. Wi-Fi enabled high-speed internet access without cables, facilitating wireless sensors and smart home devices. Bluetooth allowed short-distance data sharing, ideal for wearables and personal gadgets. Cellular networks evolved from 2G to 4G LTE, offering faster data speeds and supporting mobile IoT applications across diverse sectors.

Specialized networks like Low Power Wide Area Networks (LPWAN) support long-range communication and low power consumption, ideal to cover large and remote areas. 

Mesh networks enable devices to communicate directly with each other in a localized area, enhancing reliability and redundancy, which is crucial for smart homes and industrial IoT settings. 

Satellite IoT connectivity complements terrestrial networks by providing coverage in remote areas and enhancing navigation systems.

Now, the advent of 5G, the fifth generation of mobile networks, is set to transform IoT. With significantly faster speeds, lower latency, greater capacity, and enhanced connectivity, 5G is set to revolutionize how devices communicate, making them smarter and more responsive. This next-generation network promises to unlock new possibilities for IoT applications in every walk of life.

5G Subscriptions Forecast (Ericsson Mobility Report)

According to the November 2023 Ericsson Mobility Report, North America is leading in 5G adoption, with an expected penetration rate of 61% by the end of 2023, projected to rise to 92% by 2029. 

  • The Gulf Cooperation Council (GCC) is also poised for high adoption, matching North America's 92% penetration by 2029.

  • India shows impressive growth, from 130 million 5G subscriptions in 2023 to an estimated 860 million by 2029, representing 68% of the region's mobile subscriptions.
  • Western Europe is set to follow closely with an 85% penetration rate by 2029.

In comparison, regions like India are catching up rapidly but still lag behind North America and the GCC in terms of penetration rates​.

Benefits of 5G in IoTs

Enhanced Connectivity and Speed

The arrival of 5G’s high-speed connectivity significantly enhances the functionality of IoT devices. With much faster speeds and reduced latency, IoT devices can interact in real time. Enhanced connectivity also means more reliable and stable connections, even in challenging environments. This will benefit critical industries, where IoT devices monitor and control critical processes, ensuring minimal downtime and maximizing productivity.

Examples

The deployment of a standalone 5G network by Thai mobile operator True and Huawei at Siriraj Hospital in Bangkok has revolutionized healthcare delivery. High-speed 5G connectivity, combined with artificial intelligence, accelerates medical processes like emergency responses and pathological analyses. 5G-enabled IoT devices enhance the capabilities of ambulances equipped with HD cameras and augmented reality (AR) glasses, providing timely emergency care with real-time data transmission.

The collaboration between Audi of America and Verizon to integrate 5G into Audi's vehicle lineup marks a significant advancement in automotive connectivity. This integration brings enhanced speed, ultra-low latency for real-time data transmission, and improved safety features like collision avoidance and autonomous driving. Passengers benefit from high-speed internet access for streaming and advanced navigation with real-time traffic updates. Vehicle-to-Everything (V2X) communications improve traffic flow and reduce congestion. Over-the-air updates ensure the latest features and security patches for vehicle software.

Reduced Latency

One of the most significant advantages of 5G technology is its ability to drastically reduce latency. Latency refers to the time delay between sending and receiving data. With 5G, this delay can be reduced to as low as one millisecond, compared to 4G's 50 milliseconds. This reduced latency is crucial for applications requiring real-time data transmission. It allows for immediate data processing and response, enhancing the functionality and reliability of these systems.

Example

Swoop Aero, an Australian drone logistics company, has transformed medical supply delivery using 5G technology. Supported by the Australian Government’s 5G Innovation Initiative, their AI-powered drones leverage high-speed, low-latency 5G for precise, real-time deliveries. Ultra-reliable low latency communications (URLLC) enable coordinated drone operations, reducing delivery times from hours to minutes, such as cutting pathology sample delivery between Moreton Bay islands from six hours to just 50 minutes. This innovation enhances operational efficiency and ensures timely medical assistance, showcasing the transformative potential of 5G-enabled IoT devices in healthcare.

Massive IoT Deployment

The deployment of 5G technology is transforming massive IoT implementations. With 5G, businesses can connect an unprecedented number of devices. This allows for extensive data collection and communication.

  • In smart cities, thousands of sensors and devices work together. They monitor and manage infrastructure, traffic, and public services. This coordination improves efficiency and safety.
  • In industrial settings, 5G supports large-scale automation. It connects many machines and systems, enhancing productivity and efficiency.

5G can handle high device density and provide consistent connectivity. This ensures that massive IoT networks operate smoothly. It enables real-time monitoring, control, and optimization across various sectors.

Example

  • Barcelona has implemented a massive IoT deployment, leveraging 5G technology to enhance its smart city infrastructure. This initiative, led by NEC and local partners, has integrated thousands of IoT devices across the city to monitor and manage various urban functions. These devices include sensors for environmental monitoring, smart lighting systems, and traffic management solutions. 

The 5G network supports real-time data collection and communication, enabling city officials to make informed decisions promptly. For example:

  • The smart lighting system adjusts brightness based on pedestrian and vehicle traffic, reducing energy consumption and improving public safety. 
  • Similarly, the traffic management system utilizes data from connected sensors to optimize traffic flow and reduce congestion. 

This extensive use of 5G-enabled IoT devices has significantly improved the efficiency and sustainability of urban operations in Barcelona, showcasing the transformative potential of 5G in massive IoT deployments.

Enhanced Reliability and Network Slicing

Network slicing is a transformative technology enabled by 5G, allowing multiple virtual networks to be created within a single physical network infrastructure. Each virtual network, or "slice," is customized to meet the specific needs of different applications or services, ensuring optimal performance and resource allocation. This capability is crucial in environments that require high reliability and low latency, such as smart factories. With 5G network slicing, factories can allocate dedicated slices for critical operations like real-time communication between sensors and robots, thereby enhancing efficiency and reliability.

Example

A successful implementation of 5G network slicing has been tested at Comau’s headquarters in Turin, Italy, in collaboration with TIM and Ericsson. This smart factory setup leverages 5G network slicing to facilitate seamless real-time communication between embedded sensors, robots, and control systems. 

Sensors continuously collect and transmit operational data. This data is processed in real-time to predict maintenance needs and prevent equipment failures. As a result, downtime is significantly reduced. The ultra-reliable low latency communications (URLLC) provided by 5G ensure precise and synchronized movements of robots, which greatly enhances operational efficiency.

The project also integrated advanced robotics and AI-driven processes. This showcases the potential for highly automated and intelligent manufacturing environments. 

Challenges and Considerations

Integration Complexity

Integrating 5G with IoT presents significant challenges, primarily due to the complexity of network slicing and the need for seamless coordination across various network components. 

Network slicing is a key feature of 5G. It allows multiple virtual networks to run on a single physical network. However, implementing it is complex and requires advanced management to ensure performance and security.

IoT devices have diverse requirements. Some need high-speed data, while others need ultra-low latency. Each application needs a tailored network slice to function properly.

Managing these different slices adds layers of complexity to deploying and maintaining 5G networks. This can slow down the integration process, making it a challenging task. 

From a regulatory perspective, network slicing also faces hurdles. In the US, the FCC’s cautious approach to network slicing in its proposed net neutrality rules reflects concerns about fair access and the potential for service prioritization, which could further complicate the deployment and integration of 5G-enabled IoT systems.

Infrastructure Investment

The deployment of 5G technology necessitates substantial investment in infrastructure, including the installation of new antennas, base stations, and fiber optic connections. This investment is crucial to support the higher speeds, lower latency, and increased connectivity demanded by IoT applications. Upgrading existing infrastructure or building new facilities involves significant capital expenditure, posing a challenge for telecom operators and stakeholders.

To address these infrastructure challenges, companies are actively seeking investment opportunities and forming strategic partnerships. For instance:

Security & Privacy

As 5G technology enables a vast and intricate network of connected devices, maintaining the security and privacy of data becomes paramount. The expansion of IoT devices increases potential vulnerabilities, necessitating robust security measures to protect against cyberattacks. The massive data flow generated by these devices includes sensitive information that requires stringent privacy protections to prevent unauthorized access and breaches.

Future Outlook

The future of 5G in IoT is set to evolve the connectivity landscape, with 5G subscriptions projected to reach nearly 5.6 billion by 2029, making it the dominant mobile access technology globally. This growth is driven by the deployment of the 5G mid-band spectrum, which balances coverage and capacity, enhancing user experiences across various applications. Emerging trends such as edge computing will enable faster data processing and real-time analytics essential for autonomous vehicles and smart cities. Additionally, the integration of AI and machine learning will foster advanced IoT solutions, driving automation and operational efficiency in diverse sectors.

Innovations in network technologies, including the deployment of 5G standalone architecture, will further enhance the capabilities of 5G networks, allowing for greater flexibility, reliability, and security. The use of network slicing will enable dedicated network segments tailored to specific applications, optimizing performance and security. Integrating 5G with blockchain technology will enhance data security within IoT networks. As these technologies evolve, the IoT landscape will be reshaped, offering unprecedented opportunities for innovation and growth, ultimately transforming industries and improving global quality of life.

Conclusion

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