Unlock the potential of WI-FI with Virtual Antenna® technology

Discover seamless integration solutions for Wi-Fi technology with our comprehensive design guide.

Whether implementing Wi-Fi independently or alongside other wireless technologies like BLE, Cellular IoT, and GNSS, this guide equips you with strategies for low power consumption, robust connections, easy integration, and controlled coexistence. Maximize efficiency and reliability in your IoT projects.

Get Your Guide Today

CES 2024 Preview: US Consumer Label, Disaster Relief, AI for IoT Security

06 Dec 2023 Events

Join us at the forefront of innovation as the IMC IoT M2M Council presents a virtual roundtable event, “CES 2024 Preview: US Consumer Label, Disaster Relief, AI for IoT Security” focused on pivotal topics shaping IoT today. Mark your calendars for December 6th and 7th where industry leaders and analysts explore critical themes including the US Consumer Labelling, IoT for Disaster Relief, and the integration of AI for IoT Security.

Don’t miss out on insights from Bruno Cunha, Ignion’s Head of Sales EMEA, as he takes the stage on December 7th at 4:00 pm (CET) in a spotlight presentation about “Trends in Asset-Tracking Using Wi-Fi.” Delve deeper into how Wi-Fi is being used to complement GNSS to make asset tracking more reliable and robust.

Save your spot

Connectivity and smart meters: Laying a secure foundation

Neil Bosworth
27 Nov 2023 Blog

Smart meters: fundamental to smart cities

The world is becoming more connected every day. Smart meters enabled by Internet of Things (IoT) technologies are fundamental to municipal smart grid systems.

Governments and utilities worldwide are collaborating with IoT device manufacturers to modernize energy systems. However, this digitization comes with significant security challenges, making IoT smart meter safety a paramount concern. Implementing cybersecurity measures safeguards the grid from disruption by bad actors.

Connected smart metering devices and sensors collect and send data to utility companies (e.g., water, heat, gas and electricity). This data optimizes distribution and reduces costs. In addition, it empowers consumers to make informed decisions about energy consumption.

Other benefits of smart metering include load balancing and usage forecast enhancements. It improves customer engagement through accurate, up-to-date billing. Smart meters even support remote monitoring and automatic issue resolution, reducing the need for technician visits. Despite these benefits, there are critical connectivity, design and security considerations.

IoT firmware control for secure connectivity

IoT device security hinges on controlling IoT firmware, a vital software embedded in devices. This firmware allows devices to operate effectively and communicate with other systems.

IoT device manufacturers may lack detailed knowledge of the firmware inside their modules. The module manufacturer holds this crucial information. It’s important to work with a trusted module vendor that understands the importance of reliable connectivity and security.

Connectivity and security: safeguarding device network connections

Choosing the right connectivity standards is crucial for securing smart meter solutions. Smart meter deployments can be deployed in the field for a decade or longer. Power-saving connectivity options like cellular LPWA technologies (e.g., LTE-M and NB-IoT) are ideal for these devices.

When a device connects to the internet, it becomes susceptible to cyberthreats. IoT device manufacturers must consider these vulnerabilities when protecting their device network connections.

Reliable connectivity is the foundation for smart metering

Reliable connectivity is the heart of every smart meter’s functionality. These devices have transitioned from mere meter readers to gathering a wealth of data beyond traditional readings. They are essential components of advanced metering infrastructure (AMI), making large-scale deployments essential for utilities.

With significant investments at stake, emphasizing cost-efficiency and reliability is more critical than ever. A smart meter is powerless without dependable, secure communication. Therefore, a robust antenna and a trusted module provider are fundamental.

Wireless communication technology ensures that the devices seamlessly operate. Let’s delve deeper into the functionality and challenges smart meters face in today’s complex landscape.

Smart meters: a look beyond the surface

Modern smart meters are becoming more complex. They resemble smartphones in some respects but at a fraction of the cost and with longer lifespans. They run applications, including third-party software. Smart meters also require firmware and security updates and must address the challenges posed by multiple wireless connectivity standards.

However, unlike smartphones, these meters are fixed installations. They are often located in obscure or challenging environments (e.g., basements, cupboards and outdoors).

Even in such conditions, these devices must perform reliably and manage multiple communication standards simultaneously. They play a crucial role in balancing the grid and managing meter readings. Smart meters are essential components of a robust energy infrastructure. However, this expanded role presents several challenges:

  • Integration of new devices: Utilities must continuously integrate new smart devices and smart home technologies into their infrastructure.
  • Separation of communication and metering: A clear demarcation between metering hardware and communication components must be established to enhance flexibility and scalability.
  • Backhaul connectivity: Long-term backhaul connectivity methods that often leverage multiple RF technologies must be developed.

Various techniques (e.g., low-power protocols, private networks and cellular communication) address these challenges. Still, cellular technology is a front-runner for comprehensive and long-term IoT deployments.

Elevating smart metering with cellular technology

Cellular technology’s advantages make it an attractive option for smart metering:

  • Global standards and spectrum: Cellular technology operates on globally agreed-upon standards and licensed frequencies defined by 3GPP. These standards ensure a consistent roadmap for future development.
  • Globally deployed networks: These networks are supported by continuous investments from hundreds of established mobile network operators.
  • Private cellular networks: These offer the ultimate privacy and control for utilities and maintain the benefits of globally defined standards.
  • Infinitely scalable infrastructure: Cellular LPWA networks are designed to serve millions of endpoints.
  • Easier deployments: Compared to short-range or mesh networks, cellular is a ready-to-use infrastructure requiring no additional network equipment.
  • Inherent security: Cellular technology offers robust security with a trusted network identity and encryption.

Preparing for the future with a trusted partner

Smart meter manufacturers must anticipate evolving technologies and infrastructure complexities and challenges. With Telit Cinterion, utilities can navigate challenges and ensure that smart meters meet present and future demands.

Telit Cinterion’s modules offer comprehensive support for smart metering across various frequency bands and technologies. The company has over 23 years of knowledge and experience and is globally compatible and committed to standards. Its expertise in vertical-specific demands makes Telit Cinterion a valuable smart meter design and deployment partner.

A secure path forward: mitigating security risks in IoT-driven energy systems

Smart meters offer myriad advantages as governments and utilities pursue sustainability and smart grids. However, ensuring security for smart meters, from firmware control to connectivity standards, is crucial. These elements require selecting a trusted module supplier.

By adhering to these considerations, we can confidently embrace the future of IoT-driven energy systems. We can ensure reduced security risks and greater sustainability. Security remains a top priority for a more connected world as IoT technology expands.

Read this article on IoT for All to learn more.

the author

Neil Bosworth

Neil Bosworth is an IoT specialist at Telit Cinterion where he devices and implements the IoT vertical marketing strategy across the Telit Cinterion portfolio. He is an experienced Sales and…

see author’s profile

Getting the best cellular IoT antenna performance: Why it’s better to focus on the specific bands in your region

Jordi Miro
02 Nov 2023 Blog

Does this sound familiar?

Customer: “Our new device’s RF module can work with a wide range of global bands, and we want an antenna that matches them all.”

Antenna engineer: “Sure, but aren’t you only deploying in Europe? Let me show you something…”

When you are in the process of creating IoT devices, one crucial decision revolves around choosing the right cellular RF module and its associated antenna. The RF module handles wireless communication and operates within specific frequency bands. However, not all global cellular bands are likely to be relevant for your IoT device. Here’s why from an antenna perspective it’s better to focus on covering the bands specific to your deployment region:

  • Regulatory Compliance: Different regions have different regulations regarding the use of radio frequency bands. By focusing on the bands specific to your region, you ensure that your device complies with local regulations without excess coverage/unnecessary testing.
  • Optimized Performance: By matching the antenna design to the bands used only in your region, you can further optimize the performance of your device. Typically, limited bands mean you can build a smaller device.
  • Cost and Complexity: Integrating a chip antenna that covers all possible frequency bands can add unnecessary cost and complexity to your device. By focusing on the bands relevant to your region, you can keep your design simpler and more cost-effective.
  • Power Efficiency: Devices operating in the correct frequency band will have better power efficiency, which is critical for battery-powered IoT devices.
  • Network Availability: There’s no benefit in supporting a frequency band if the local networks don’t operate on it. Focusing on local bands ensures your device can connect optimally to available networks, delivering better performance.

Remember, while RF modules may support a wide range of frequency bands, it’s essential to focus on those relevant to your region(s) when designing your IoT device. One of the key steps is to ensure that it meets the certification targets set by various RF performance certification authorities. These targets vary by region and wireless standard. For instance, AT&T, Verizon, and T-Mobile US in North America or Vodafone in the EU have their own certification processes for cellular devices. Contact your local certification body to understand region-specific requirements. This approach ensures regulatory compliance, optimizes performance and keeps costs down.

To illustrate, let’s bring up an example powered by the Antenna Intelligence Cloud™ digital twin:

Picture a PCB board that measures 107 mm by 50 mm, coupled with an RF module capable of covering a wide range of bands worldwide from 699 MHz to 2200 MHz. Now, in this case, the goal is to match the antenna’s range to this wide spectrum. This means the antenna needs to possess multi-band capabilities and have sufficient size to encompass both the sub-GHz frequencies and the higher bands. For this project, we’ve opted for the TRIO mXTEND™ antenna (NN03-310). Let’s explore how its performance differs when it covers the entire available range (including all bands from 699 MHz to 960 MHz and 1710 MHz to 2200 MHz), as opposed to concentrating on just two of the European bands (bands 8 and 20 // 791 MHz to 960 MHz.

Figure 1 – A 107 mm by 50 mm PCB board with the TRIO mXTEND™ covering Cellular LPWA bands.

Figure 2 – S11 (dB) and Total efficiency (%) covering the whole range from 699 – 960 MHz to 1710 – 2200 MHz. Figure 3 – S11 (dB) and Total efficiency (%) covering bands 8, 20 from 791 – 960 MHz.

As can be seen in the results above, a narrower frequency range results in a better performance in the lower bands of interest having around +2 dB of improvement in the bands 20 and 8. Going beyond these results, you can consider a less complex or smaller antenna resulting in space and cost savings for the design.

In conclusion, when it comes to antenna integration, more isn’t always better. Tailoring your antenna solution to cover the bands pertinent to your region’s deployment offers regulatory compliance, efficient spectrum utilization, enhanced performance, and cost savings. It’s an important strategic choice to align your wireless communication strategy with the unique needs and regulations of your target market.

the author

Jordi Miro

Jordi Miro is Ignion’s Technical Product Marketing Manager responsible for the company’s Virtual Antenna® products. He works closely with partners and the Ignion engineering team to provide support and testing…

see author’s profile