Articles by FiRa Consortium
Indoor positioning is, in many ways, an inside version of the satellite-navigation apps we rely on for outdoor navigation, but with an added twist – it can also be used to help locate people and things. Let’s say you’re at home and misplaced your car keys, or you’re in a grocery store and can’t find your favorite brand of coffee. Or maybe you’re working in a factory and need a particular tool from a storage bin, or you’re a site manager dealing with an emergency and need to make sure everyone’s exited the building. Indoor positioning helps in all these situations, because it can locate items and guide you to where they are. The importance of “where” Knowing where an asset is located in real time is useful in many ways. In industrial settings, it improves item utilization rates and saves time spent searching for things. It opens the door for a new level of “just in time” efficiency on factory floors, and for inventory management in warehouses and retail environments. Safety is another benefit of accurate location, because knowing where people, automatic guided vehicles, and robots are in real time can help prevent accidents and keep people out of harm’s way. Accurate location in real time also enables contextual decision-making, so your smart house adjusts your stereo automatically as you move from to room or lets you control objects by simply pointing at them. Lets you control objects by simply pointing at them Security authorisations based on location is another possibility. Precise real-time location is something that can be hard to fake, so it can be used to restrict access to an area or used to add protections based on where an asset sits, where a piece of data resides, or the origination point of a communication. Getting the technology right Developing an effective technology for indoor positioning requires several things. To begin with, location readings needs to be very precise, with accuracy down to as small an area as possible. The technology has to be secure, because location often needs to be kept private. The technology has to be reliable, even in harsh environments, and easily scalable, too, so it can address the thousands of people and assets in large venues. It has to be low power and affordable, so it can be embedded in everything from high-end, complex devices like smartphones to low-end, simple devices like asset tags. And, of course, the technology has to have latency low enough that it can track movement in real time. Various wireless technologies, including Bluetooth and Wi-Fi, are already used for indoor positioning, but they don’t deliver on the full set of requirements, especially in terms of accuracy. A different kind of wireless, called Ultra-Wideband (UWB) checks all the boxes. It has the potential to change the way we do all kinds of everyday tasks. What is UWB? UWB is based on the IEEE standard 802.15.4a/z, which has been optimized for micro-location and secure communication. UWB is highly accurate. It can pinpoint people and things to within just a few centimeters, making it 100 times more accurate than the current implementations of Bluetooth Low Energy (BLE) and Wi-Fi. UWB is reliable because it has high immunity to various types of interference, including multipath, which is when a wave from a transmitter traveling to a receiver by two or more paths causes interference. UWB also offers very low latency, with update rates of up to 1000 times per second and readings that are as much as 50 times faster than satellite navigation. UWB is also implemented using mainstream technology, so it’s both affordable and optimized for low power. Lastly, UWB leverages distance-bounding techniques defined by the IEEE to provide a level of security that makes it extremely difficult to hack. Ultra-Wideband (UWB) checks all the boxes How is all this possible? Physics! UWB out-performs other location technology because, unlike Bluetooth and Wi-Fi, which transmit narrowband signals and use Received Signal Strength Indicator (RSSI) to determine location, UWB transmits wideband signals (500 MHz) and uses Time-of-Flight to determine location. Already in 40+ verticals UWB is already bringing value to products and services in more than forty verticals covering the consumer, automotive, industrial, and commercial market segments. For example, it brings operational visibility to manufacturing and logistics, helps businesses protect workers, and reduces safety-management costs. UWB also lets robots and drones self-navigate, and enables secure, hands-free access to cars, front doors, and other secure locations. It even helps with contact tracing and social distancing in the fight against COVID-19. Now in smartphones Recent adoption in smartphones means UWB is ready to grow quickly. Developers are using UWB as part of new services, with an eye toward making various everyday activities more convenient and safer. With UWB as part of smartphone apps, purchases will be more secure, accessing your car will be possible without a key fob, and misplaced items won’t stay hidden for long. Retail outlets will use location for targeted marketing, and finding things on store shelves will be easier than ever. Home automation will become seamless, and friends and family will be easy to find even if they’re in a crowd. The question of interoperability Having UWB in smartphones is an important first step Having UWB in smartphones is an important first step toward making UWB an everyday part of life, but interoperability is another key factor, since smartphones have to interact with a wide range of other devices and services. That’s where the FiRa Consortium comes in. Launched just over a year ago, the FiRa Consortium is a member-driven organization of market leaders from the consumer, mobile, industrial, enterprise, and semiconductor industries. FiRa members work collectively to define the future standards that will make interoperability across UWB products a reality. With FiRa making it possible for developers to use UWB in all kinds of new ways, the future of indoor location is really only limited by the developer’s imagination.
For the security market, the ‘fine ranging’ capabilities of ultra-wideband (UWB) technology opens up a range of new uses based on the ability to determine the relative position and distance of two UWB-equipped devices with pinpoint accuracy – within centimeters. UWB is more accurate and secure, even in challenging environments full of interference, compared to narrow band wireless technologies. UWB technology transmits a large amount of data over short distances using a small amount of energy. It will be used in seamless access control, location-based services, and device-to-device services across industries including smart homes, cities, retail services, and healthcare. Increasing the accuracy of ranging measurements UWB technology will support any application that benefits from knowing the precise location of a connected deviceUltra-wideband is a mature radio technology that transmits information spread over a large bandwidth, as described by the IEEE 802.154 standard. A new, enhanced amendment to the standard – IEEE 802.15.4z – focuses on improvements to existing modulations to increase the integrity and accuracy of ranging measurements. Moving forward, UWB technology will support any application that benefits from knowing the precise location or presence of a connected device or object. This reflects a move from data communication to secure sensing. New capabilities of UWB are largely unfamiliar to the market, but a new Consortium – the FiRa Consortium – has a mission to educate the market, provide use cases, and promote UWB technology. Delivering interoperability across devices “With a consortium, we can better deliver interoperability across devices, software, and chipsets,” says Ramesh Songukrishnasamy, Director and Treasurer of the FiRa Consortium, and SVP & CTO of HID Global. “This creates a frictionless experience for the user, which is vitally important with a new technology. People are more likely to adopt emerging technology when it runs smoothly without interruptions or errors.” The FiRa consortium is ensuring new use cases for fine ranging capabilities can thrive" An industry consortium can create a UWB ecosystem of interoperable technologies instead of individual companies launching products that consumers struggle to make work together, says Songukrishnasamy. “Simply, the FiRa consortium is ensuring new use cases for fine ranging capabilities can thrive.” Founding members of the FiRa consortium ASSA ABLOY and HID Global, pioneers in secure access and identity solutions, are founding members of the consortium. Their technology manages access to physical and digital places, things, and identities. Another founding consortium member, NXP Semiconductors, is a pioneer in secure connectivity solutions for embedded applications. Other founding members are Samsung, which creates top-of-the-line TVs, smartphones, wearables, and other connected devices; and the Bosch Group, a global supplier of technology and services that is at the forefront of IoT innovations. Sony Imaging Products & Solutions Inc., LitePoint and the Telecommunications Technology Association (TTA) are the first companies to join the newly formed organization. Immune to radio frequency interference UWB is also immune to radio frequency interference, so it functions in high traffic settingsUWB introduces higher levels of accuracy in positioning capabilities and increased security for ranging data exchange compared to existing technologies. Fine ranging with UWB technology can localize devices and objects to 10 centimeters of accuracy with or without line of sight. UWB is also immune to radio frequency interference, so it functions in high traffic settings. These capabilities will enable a variety of use cases like secure, hands-free access control in hospitals, location-based services for ride sharing, and targeted marketing for retailers. FiRa will demonstrate UWB technology at upcoming trade shows. The FiRa Consortium aims to build on IEEE’s work with an interoperable high rate physical layer (HRP) standard, including defining an application layer that discovers UWB devices and services and configures them in an interoperable manner. The consortium also plans to develop service-specific protocols for multiple verticals and define necessary parameters for applications including physical access control, location-based services and device-to-device services. Promoting the adoption of UWB solutions As a consortium, FiRa is not just setting standards but actively championing use cases for UWB technology. Creating the consortium addresses the need to develop interoperability and implementation standards; brings key players together to create a rich UWB ecosystem; allows for the sharing of intellectual property; and promotes the adoption of UWB solutions. The FiRa Consortium is committed to educating and promoting new use cases" “Since UWB is a mature technology with new potential uses, there is a general lack of awareness of potential applications that take advantage of the technology,” says Songukrishnasamy. “The FiRa Consortium is committed to educating and promoting new use cases.” The FiRa name comes from Fine Ranging to highlight UWB technology’s use cases and distinction from older UWB technologies and solutions. Enhanced security in challenging environments Fine ranging powered by UWB can outperform other technologies in terms of accuracy, power consumption, robustness in wireless connectivity, and security, especially in challenging, high density environments. UWB previously served as a technology for high data rate communication and as such was in direct competition with Wi-Fi. Since then, UWB has undergone several transformations: UWB has evolved from an OFDM-based data communication to an impulse radio technology specified in IEEE 802.15.4a (2ns pulses with Time of Flight); and A security extension being specified in IEEE 802.15.4z (at PHY/MAC level) makes it a unique secure fine ranging technology. Moving from data communication to secure ranging allows ‘spatial context capability’ to be utilized by a variety of applications: seamless access control, location-based services, and device-to-device (peer-to-peer) services. Information is available at firaconsortium.org.