Tag Archives: Augmented

How Augmented Reality is Revolutionizing Engineering

Technology has always played an important role in the field of engineering, and the advancements in augmented reality (AR) is no exception. AR enables engineers to visualize and analyze complex designs or models with incredible detail and precision, facilitating their work, and resulting in significant improvements in efficiency, accuracy, and productivity. In this blog post, we will explore how AR is revolutionizing the field of engineering and how it is improving the work of engineering professionals.

SIMPLIFYING COMPLEX MODELS

AR helps engineers simplify complex models by superimposing a digital overlay onto the physical world. By doing this, engineers can analyze models in their actual size and scale, making it easier to understand and manipulate for design modifications. AR can aid engineers to identify design flaws much more rapidly with fewer errors.

ENHANCING COLLABORATION

With AR, engineering teams can collaborate more effectively, regardless of their location, utilizing a shared AR model. Multiple team members can view and interact with the same model, which provides better insights and leads to better resolutions.

IMPROVING PRECISION

AR enables engineers to identify and mitigate potential errors before production or assembly. AR headsets can overlay digital design elements in real-time to pinpoint precise positions of mechanical components. As a result, engineering firms can reduce their manufacturing time while increasing the quality of their output.

BOOSTING EFFICIENCY

AR helps reduce the time needed for design reviews by allowing engineers to identify optimization opportunities more rapidly. Furthermore, AR can simplify assembly procedures by providing detailed step-by-step guidance through the assembly process, leading to quicker and more accurate builds.

COST REDUCTION

Increased efficiency, improved collaboration, and reduced errors lead to significant cost savings. Applying AR technology to the engineering process is providing substantial cost savings across the industry.

REAL-WORLD EXAMPLES OF AR IN ENGINEERING

AR is not a futuristic concept; it is already being utilized by several leading engineering companies worldwide:

  • Boeing: Boeing employs AR glasses for its technicians to aid in assembling complex aircraft. The glasses display instructions and diagrams directly in the technician’s field of view, boosting accuracy and efficiency.
  • Volkswagen: Volkswagen has implemented AR technology to assist its assembly line workers. AR headsets provide step-by-step instructions and can highlight specific components and tools needed during the assembly process.
  • Siemens: Siemens provides an AR-based maintenance solution for its industrial customers through their “Siemens Industrial Augmented Reality” platform. This technology assists field service technicians in diagnosing and repairing machinery by offering real-time data and guidance.
  • Lockheed Martin: Lockheed Martin, a global aerospace and defense company, uses AR to improve the assembly of satellite components. Technicians wearing AR glasses can access digital assembly instructions, reducing errors and accelerating the assembly process.
  • Porsche: Porsche employs AR glasses to assist service technicians at their dealerships. These glasses furnish service manuals, schematics, and technical information, allowing technicians to work hands-free.
  • Jaguar Land Rover: Jaguar Land Rover utilizes AR in the design and prototyping of vehicles. Engineers can view and manipulate 3D models in a real-world context, easing the evaluation of designs and collaboration on alterations.
  • General Electric (GE): GE utilizes AR for equipment maintenance and repair. Technicians can use AR apps on tablets or smart glasses to access digital twins of industrial machines, aiding in diagnostics and maintenance procedures.
  • Caterpillar: Caterpillar employs AR technology for training technicians and service personnel. It offers an interactive training module via the “Cat® AR” app for the maintenance and repair of heavy machinery.
  • BMW: BMW leverages AR glasses in its production process. These glasses assist workers in assembling and verifying the correct installation of complex components, such as wiring harnesses, by displaying visual instructions and highlighting potential issues.
  • Procter & Gamble: This multinational consumer goods corporation uses AR for quality control in its manufacturing processes. It deploys AR systems capable of scanning products for defects, providing real-time feedback to workers.
  • ABB: ABB, a global leader in robotics and automation technology, integrates AR into its service and support offerings. AR glasses enable remote experts to aid on-site technicians during maintenance and troubleshooting tasks.
  • DHL Supply Chain: DHL has implemented AR smart glasses in its warehouses to improve order picking and inventory management. Warehouse workers receive real-time picking instructions and can scan barcodes with the glasses for accuracy.

As highlighted above, AR is being applied in various ways across the manufacturing industry to enhance productivity, reduce errors, improve training, and streamline operations. AR continues to play a crucial role in transforming manufacturing processes and boosting overall efficiency.

TOP AR TOOLS THAT ARE MAKING WAVES IN THE ENGINEERING WORLD:

The choice of software depends on the specific needs and goals of the engineering project. Here are a few examples:

  1. AutoCAD AR: AutoCAD, a renowned software for 2D and 3D design, now boasts AR functionality. This allows engineers to visualize their CAD designs in real-world settings, thereby simplifying assessments of how a design will fit into a physical space.
  2. Trimble Connect: This collaboration platform offers AR capabilities, enabling engineers and construction professionals to overlay 3D models onto real-world job sites, which enhances project planning and management.
  3. Microsoft HoloLens and Microsoft Mixed Reality: Microsoft’s HoloLens and Mixed Reality platforms provide AR tools for engineers. They allow for viewing and interacting with 3D models, schematics, and data in a mixed reality environment.
  4. PTC Vuforia: PTC’s Vuforia platform offers AR solutions for industrial applications. It allows engineers to create interactive and immersive AR experiences for tasks like maintenance and training.
  5. Magic Leap: This company provides spatial computing technology for various applications, including engineering. Engineers can use Magic Leap’s AR headset to interact with 3D models and data in a spatial context.
  6. EON Reality: EON Reality provides AR and VR solutions for engineering training and education, allowing for the creation of immersive training simulations for various industrial processes.
  7. SolidWorks XR: SolidWorks, a popular 3D CAD software, offers an extended reality (XR) feature that enables engineers to view and interact with their 3D designs in augmented and virtual reality environments.
  8. Scope AR WorkLink: This platform provides AR solutions for industrial maintenance and repair. It allows engineers to access step-by-step AR instructions while performing complex maintenance tasks.
  9. TeamViewer Frontline: This platform, designed for frontline workers, including engineers, offers various AR applications for tasks such as assembly, quality control, and remote assistance. It also allows them to access hands-free information and guidance through smart glasses.
  10. Fologram: Tailored for architecture, construction, and engineering, Fologram allows engineers to view complex 3D models on job sites and collaborate with colleagues in real time.

These AR software solutions are transforming the way engineers work by enhancing collaboration, improving training and maintenance processes, and providing new ways to visualize and interact with complex data and designs.

TAKEAWAYS

It’s clear that augmented reality has emerged as a powerful tool for the engineering industry. It can simplify tasks, enhance collaboration, improve accuracy, save time and money, and positively impact product quality. By using AR, engineering firms can now optimize their delivery times while simultaneously improving product performance and quality. Engineering professionals that leverage this technology can expect to see significant benefits in their work, ultimately resulting in increased productivity and innovation. It’s no surprise that the engineering industry is now adopting this incredible technology at an ever rapid rate. Augmented reality is more than a trend; it’s a game-changing technology that is here to stay.

In our next blog, we will explore how augmented reality is beneficial to robotics development.

How Business Owners Can Leverage the Metaverse to Turn a Profit

As many have heard, Facebook’s highly publicized rebranding as Meta in 2021 signaled their long-term expansion from social media into VR, the metaverse, and more. In the process, they launched the metaverse into a household name technology. The $500 million virtual real estate boom which proceeded only further hammered the point home—as far as Meta is concerned, the metaverse is the future. With VR and AR technologies developing at an astounding rate, businesses are entering the metaverse intent on generating revenue while the technology remains in its nascent stage.

The metaverse is here to stay—the question for business owners is: how can one take advantage of it? There is a long list of apps that use AR features to enhance the shopping experience. Sephora’s Virtual Artist app enables users to view how makeup will look before trying it on. The Ikea Place application enables users to view how furniture will look in their house before they place them.

The big question is: should you as a business owner delve into the metaverse? And if so, how can you leverage a metaverse presence to generate commerce? In this week’s blog, we present a few ideas to consider when making your decision.

REAL ESTATE

The first step to a metaverse presence is the acquisition of a virtual space for the business. Luckily, metaverse real estate has proven to be an extraordinarily profitable investment in and of itself. Armando Aguilar told Coindesk recently that the price of his three-bedroom, two-bathroom home outside New York City has appreciated two and a half times, while his metaverse property surged by 1,400% during that same time.

When purchasing real estate within the metaverse, consider which platform you’d like to see your company grow in. There’s a long list of options, from Sandbox to Decentraland, each with their own pros and cons.

When choosing a platform, consider which platform will provide the most short-term gains for your customers. Where do you anticipate long-term value? Investing wisely will lead to revenue as the price of virtual property rises.

For a list of the top metaverse platforms, check out XR Today’s list of the top metaverse platforms to watch in 2022.

EXPAND YOUR PHYSICAL PRESENCE

The metaverse presents an opportunity for companies to translate their brand into a virtual experience. Similar to the early aughts of the internet, companies which fail to capitalize on the new channel may lose money to companies that adopted the metaverse faster.

The metaverse differs from the internet in that it enables businesses to replicate three dimensional, physical spaces. This is a huge leap as we are physical beings and crave physical experiences.

While nothing can replace the physical retail experience, a great deal of commerce is generated by monetizing convenience. Delivery services like Amazon and Seamless generate billions of dollars in revenue by offering a variety of products to their customers through their digital presence, cutting out the need to stray from the home.

The metaverse capitalizes on our desire for physical experiences while enabling us to access them from the comfort of our couch. Rather than recreate their websites, businesses need to think about how they can create a physical experience for their customers.

Five years down the line, businesses will likely require a team of consultants and developers to build the metaverse experience. Check out the video below showing how Walmart created a physical shopping experience in the metaverse.

NFTs AND THE METAVERSE

Commerce in the metaverse will incorporate cryptocurrency and NFTs. NFTs, or nonfungible tokens, are unique digital files which function as certificates of ownership verified by the blockchain. They can be associated with any number of things—from sneakers, to songs and works of art. Although the market shows volatility similar to cryptocurrency, NFT value can appreciate by quite a bit.

NFTs represent a new buying channel that’s crucial to the metaverse. Creating exclusive experiences in the metaverse will draw your customers in.

Offering exclusive NFTs is a way to both create value and boost engagement with your customers. Adidas recently took advantage of this, generating over $23 million in ethereum in their first NFT drop.

Consider incorporating NFT’s alongside physical product drops. For example, offer an NFT to customers who enter the metaverse to make early pre-orders of future releases.

The metaverse is an opportunity to drive engagement and create value by offering personalized, exclusive experiences to your customers. NFTs are the perfect method to achieve this.

CONCLUSION

The metaverse poses a business opportunity for enterprises unafraid of innovation. What kind of experience can you deliver to your customers in the metaverse that you cannot in any other realm? Businesses which manage to answer that question will be rewarded with long-term profit.

Learn How Google Bests ARKit with Android’s ARCore

Previously, we covered the strengths of ARKit 4 in our blog Learn How Apple Tightened Their Grip on the AR Market with the Release of ARKit 4. This week, we will explore all that Android’s ARCore has to offer.

All signs point toward continued growth in the Augmented Reality space. As the latest generations of devices are equipped with enhanced hardware and camera features, applications employing AR have seen increasing adoption. While ARCore represents a breakthrough for the Android platform, it is not Google’s first endeavor into building an AR platform.

HISTORY OF GOOGLE AR

In summer 2014, Google launched their first AR platform Project Tango.

Project Tango received consistent updates, but never achieved mass adoption. Tango’s functionality was limited to three devices which could run it, including the Lenovo Phab 2 Pro which ultimately suffered from numerous issues. While it was ahead of its time, it didn’t receive the level of hype ARKit did. In March 2018, Google announced that it will no longer support Project Tango and that the tech titan will be continuing AR Development with ARCore.

ARCORE

ARCore uses three main technologies to integrate virtual content with the world through the camera:

  • Motion tracking
  • Environmental understanding
  • Light estimation

It tracks the position of the device as it moves and gradually builds its own understanding of the real world. As of now, ARCore is available for development on the following devices:

ARCORE VS. ARKIT

ARCore and ARKit have quite a bit in common. They are both compatible with Unity. They both feature a similar level of capability for sensing changes in lighting and accessing motion sensors. When it comes to mapping, ARCore is ahead of ARKit. ARCore has access to a larger dataset which boosts both the speed and quality of mapping achieved through the collection of 3D environmental information. ARKit cannot store as much local condition data and information. ARCore can also support cross-platform development—meaning you can build ARCore applications for iOS devices, while ARKit is exclusively compatible with iOS devices.

The main cons of ARCore in relation to ARKit mainly have to do with their adoption. In 2019, ARKit was on 650 million devices while there were only 400 million ARCore-enabled devices. ARKit yields 4,000+ results on GitHub while ARCore only contains 1,400+. Ultimately, iOS devices are superior to software-driven Android devices—particularly given the TrueDepth Camera—meaning that AR applications will run better on iOS devices regardless of what platform they are on.

OVERALL

It is safe to say that ARCore is the more robust platform for AR development; however, ARKit is the most popular and most widely usable AR platform. We recommend spending time determining the exact level of usability you need, as well as the demographics of your target audience.

For supplementary reading, check out this great rundown of the best ARCore apps of 2021 from Tom’s Guide.

Learn How Apple Tightened Their Hold on the AR Market with the Release of ARKit 4

Since the explosive launch of Pokemon Go, AR technologies have vastly improved. Our review of the iPhone 12 concluded that as Apple continues to optimize its hardware, AR will become more prominent in both applications and marketing.

At the 2020 WWDC in June, Apple announced ARKit 4, their latest iteration of the famed augmented reality platform. ARKit 4 features some vast improvements that help Apple tighten their hold on the AR market.

LOCATION ANCHORS

ARKit 4 introduces location anchors, which allow developers to set virtual content in specific geographic coordinates (latitude, longitude, and altitude). When rebuilding the data backend for Apple Maps, Apple collected camera and 3D LiDAR data from city streets across the globe. ARKit downloads the virtual map surrounding your device from the cloud and matches it with the device’s feed to determine your location. The kicker is: all processing happens using machine learning within the device, so your camera feed stays put.

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Devices with an A12 chip or later, can run Geo-tracking; however, location anchors require Apple to have mapped the area previously. As of now, they are supported in over 50 cities in the U.S. As the availability of compatible devices increases and Apple continues to expand its mapping project, location anchors will find increased usage.

DEPTH API

ARKit’s new Depth API harnesses the LiDAR scanner available on iPad Pro and iPhone 12 devices to introduce advanced scene understanding and enhanced pixel depth information in AR applications. When combined with 3D mesh data derived from Scene Geometry, which creates a 3D matrix of readings of the environment, the Depth API vastly improves virtual object occlusion features. The result is the instant placement of digital objects and seamless blending with their physical surroundings.

FACE TRACKING

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Face tracking has found an exceptional application in Memojis, which enables fun AR experiences for devices with a TrueDepth camera. ARKit 4 expands support to devices without a camera that has at least an A12. TrueDepth cameras can now leverage ARKit 4 to track up to three faces at once, providing many fun potential applications for Memojis.

VIDEO MATERIALS WITH REALITYKIT

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ARKit 4 also brings with it RealityKit, which adds support for applying video textures and materials to AR experiences. For example, developers will be able to place a virtual television on a wall, complete with realistic attributes, including light emission, texture roughness, and even audio. Consequentially, AR developers can develop even more immersive and realistic experiences for their users.

CONCLUSION

iOS and Android are competing for supremacy when it comes to AR development. While the two companies’ goals and research overlap, Apple has a major leg up on Google in its massive base of high-end devices and its ability to imbue them with the necessary structure sensors like TrueDepth and LiDAR.

ARKit has been the biggest AR development platform since it hit the market in 2017. ARKit 4 provides the technical capabilities tools for innovators and creative thinkers to build a new world of virtual integration.

How App Developers Can Leverage the iPhone 12 to Maximize Their Apps

On October 23rd, four brand new iPhone 12 models were released to retailers. As the manufacturer of the most popular smartphone model in the world, whenever Apple delivers a new device its front-page news. Mobile app developers looking to capitalize on new devices must stay abreast of the latest technologies, how they empower applications, and what they signal about where the future of app development is headed.

With that in mind, here is everything app developers need to know about the latest iPhone models.

BIG DEVELOPMENTS FOR AUGMENTED REALITY

LiDAR is a method for measuring distances (ranging) by illuminating the target with laser light and measuring the reflection with a sensor
LiDAR is a method for measuring distances (ranging) by illuminating the target with laser light and measuring the reflection with a sensor

On a camera level, the iPhone 12 includes significant advancements. It is the first phone to record and edit Dolby Vision with HDR. What’s more, Apple has enhanced the iPhone’s LiDAR sensor capabilities with a third telephoto lens.

The opportunities for app developers are significant. For AR developers, this is a breakthrough—enhanced LiDAR on the iPhone 12 means a broad market will have access to enhanced depth perception, enabling smoother AR object placement. The LIDAR sensor produces a 6x increase in autofocus speed in low light settings.

The potential use cases are vast. An enterprise-level application could leverage the enhanced camera to show the inner workings of a complex machine and provide solutions. Dimly lit rooms can now house AR objects, such as Christmas decorations. The iPhone 12 provides a platform for AR developers to count on a growing market of app users to do much more with less light, and scan rooms with more detail.

The iPhone 12’s enhanced LiDAR Scanner will enable iOS app developers to employ Apple’s ARKit 4 to attain enhanced depth information through a brand-new Depth API. ARKit 4 also introduces location anchors, which enable developers to place AR experiences at a specific point in the world in their iPhone and iPad apps.

With iPhone 12, Apple sends a clear message to app developers: AR is on the rise.

ALL IPHONE 12 MODELS SUPPORT 5G

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The entire iPhone 12 family of devices supports 5G with both sub-6GHz and mmWave networks. When iPhone 12 devices leverage 5G with the Apple A14 bionic chip, it enables them to integrate with IoT devices, and perform on ML algorithms at a much higher level.

5G poses an endless array of possibilities for app developers—from enhanced UX, more accurate GPS, improved video apps, and more. 5G will reduce dependency on hardware as app data is stored in the cloud with faster transfer speeds. In addition, it will enable even more potential innovation for AR applications.

5G represents a new frontier for app developers, IoT, and much more. Major carriers have been rolling out 5G networks over the past few years, but access points remain primarily in major cities. Regardless, 5G will gradually become the norm over the course of the next few years and this will expand the playing field for app developers.

WHAT DOES IT MEAN?

Beyond the bells and whistles, the iPhone 12 sends a very clear message about what app developers can anticipate will have the biggest impact on the future of app development: AR and 5G. Applications employing these technologies will have massive potential to evolve as the iPhone 12 and its successors become the norm and older devices are phased out.

How to Leverage AR to Boost Sales and Enhance the Retail Experience

The global market for VR and AR in retail will reach $1.6 billion by 2025 according to research conducted by Goldman Sachs. Even after years of growing popularity, effectively employed Augmented Reality experiences feel to the end-user about as explicitly futuristic as any experience created by popular technology.

We have covered the many applications for AR as an indoor positioning mechanism on the Mystic MediaTM blog, but when it comes to retail, applications for AR are providing real revenue boosts and increased conversion rates.

Augmented Reality (AR) History

Ivan Sutherland 1

While working as an associate professor at Harvard University, computer scientist Ivan Sutherland, aka the “Father of Computer Graphics”, created an AR head-mounted display system which constituted the first AR technology in 1968. In the proceeding decades, AR visual displays gained traction in universities, companies, and national agencies as a way to superimpose vital information on physical environments, showing great promise for applications for aviation, military, and industrial purposes.

Fast forward to 2016, the sensational launch of Pokemon GO changed the game for AR. Within one month, Pokemon GO reached 45 million users, showing there is mainstream demand for original and compelling AR experiences.

Cross-Promotions

Several big brands took advantage of Pokemon GO’s success through cross-promotions. McDonald’s paid for Niantic to turn 3,000 Japan locations into gyms and PokeStops, a partnership that has recently ended. Starbucks took advantage of Pokemon GO’s success as well by enabling certain locations to function as PokeStops and gyms, and offering a special Pokemon GO Frappucino.

One of the ways retailers can enter into the AR game without investing heavily in technology is to cross-promote with an existing application.

In 2018, Walmart launched a partnership with Jurassic World’s AR game: Jurassic World Alive. The game is similar to Pokemon GO, using a newly accessible Google Maps API to let players search for virtual dinosaurs and items on a map, as well as battle other players. Players can enter select Walmart locations to access exclusive items.

Digital-Physical Hybrid Experiences

The visual augmentation produced by AR transforms physical spaces by leveraging the power of computer-generated graphics, an aesthetic punch-up proven to increase foot traffic. While some retailers are capitalizing on these hybrid experiences through cross-promotions, others are creating their own hybrid experiential marketing events.

Foot Locker developed an AR app that used geolocation to create a scavenger hunt in Los Angeles, leading customers to the location where they could purchase a pair of LeBron 16 King Court Purple shoes. Within two hours of launching the app, the shoes sold out.

AR also has proven potential to help stores create hybrid experiences through indoor navigation. Users can access an augmented view of the store through their phones, which makes in-store navigation easy. Users scan visual markers, recognized by Apple’s ARKitGoogle’s ARCore, and other AR SDKs, to establish their position, and AR indoor navigation applications can offer specific directions to their desired product.

Help Consumers Make Informed Choices

Ikea Place Screenshots

AR is commonly employed to enrich consumers’ understanding of potential purchases and prompt them to buy. For example, the “IKEA Place” app allows shoppers to see IKEA products in a superimposed graphics environment. IKEA boasts the app gives shoppers 98% accuracy in buying decisions.

Converse employs a similar application, the “Converse Sampler App”, which enables users to view what a shoe will look like on their feet through their device’s camera. The application increases customer confidence, helping them make the decision to purchase.

Treasury Wines Estates enhances the consumer experience with “Living Wine Labels”: AR labels that bring the history of the vineyard to life and provide users with supplementary information, including the history of the vineyard the wine came from and tasting notes.

Conclusion

AR enables striking visuals that captivate customers. As a burgeoning tool, AR enables companies to get creative and build innovative experiences that capture their customers’ imagination. Retailers who leverage AR will seize an advantage both in the short term and in the long term as the technology continues to grow and evolve.

The Future of Indoor GPS Part 5: Inside AR’s Potential to Dominate the Indoor Positioning Space

In the previous installment of our blog series on indoor positioning, we explored how RFID Tags are finding traction in the indoor positioning space. This week, we will examine the potential for AR Indoor Positioning to receive mass adoption.

When Pokemon Go accrued 550 million installs and made $470 million in revenues in 2016, AR became a household name technology. The release of ARKit and ARCore significantly enhanced the ability for mobile app developers to create popular AR apps. However, since Pokemon Go’s explosive release, no application has brought AR technology to the forefront of the public conversation.

When it comes to indoor positioning technology, AR has major growth potential. GPS is the most prevalent technology navigation space, but it cannot provide accurate positioning within buildings. GPS can be accurate in large buildings such as airports, but it fails to locate floor number and more specifics. Where GPS fails, AR-based indoor positioning systems can flourish.

HOW DOES IT WORK?

AR indoor navigation consists of three modules: Mapping, Positioning, and Rendering.

via Mobi Dev
via Mobi Dev

Mapping: creates a map of an indoor space to make a route.

Rendering: manages the design of the AR content as displayed to the user.

Positioning: is the most complex module. There’s no accurate way of using the technology available within the device to determine the precise location of users indoors, including the exact floor.

AR-based indoor positioning solves that problem by using Visual Markers, or AR Markers, to establish the users’ position. Visual markers are recognized by Apple’s ARKit, Google’s ARCore, and other AR SDKs.  When the user scans that marker, it can identify exactly where the user is and provide them with a navigation interface. The further the user is from the last visual marker, the less accurate their location information becomes. In order to maintain accuracy, developers recommend placing visual markers every 50 meters.

Whereas beacon-based indoor positioning technologies can become expensive quickly, running $10-20 per beacon with a working range of around 10-100 meters of accuracy, AR visual markers are the more precise and cost-effective solution with an accuracy threshold down to within millimeters.

Via View AR
Via View AR

CHALLENGES

Performance can decline when more markers have been into an AR-based VPS because all markers must be checked to find a match. If the application is set up for a small building where 10-20 markers are required, it is not an issue. If it’s a chain of supermarkets requiring thousands of visual markers across a city, it becomes more challenging.

Luckily, GPS can help determine the building where the user is located, limiting the number of visual markers the application will ping. Innovators in the AR-based indoor positioning space are using hybrid approaches like this to maximize precision and scale of AR positioning technologies.

CONCLUSION

AR-based indoor navigation has had few cases and requires further technical development before it can roll out on a large scale, but all technological evidence indicates that it will be one of the major indoor positioning technologies of the future.

This entry concludes our blog series on Indoor Positioning, we hope you enjoyed and learned from it! In case you missed it, check out our past entries:

The Future of Indoor GPS Part 1: Top Indoor Positioning Technologies

The Future of Indoor GPS Part 2: Bluetooth 5.1′s Angle of Arrival Ups the Ante for BLE Beacons

The Future of Indoor GPS Part 3: The Broadening Appeal of Ultra Wideband

The Future of Indoor GPS Part 4: Read the Room with RFID Tags