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Automotive

LiDAR Technology in Autonomous Vehicles

Introduction:

LiDAR, an acronym for “light detection and ranging” or “laser imaging, detection, and ranging” is a sensor used for determining ranges by targeting an object or a surface with a laser and measuring the time for the reflected light to return to the receiver. With the functionality of scanning its environment, it is also sometimes called 3D laser scanning. Particularly, LiDAR image registration (LIR) is a critical task that focuses on techniques of aligning or registering lidar point cloud data with corresponding images. It involves two types of data that have different properties and may be acquired from different sensors at different times or under different conditions. With an accurate alignment of LiDAR point clouds and captured 2D images, the registration method results in the most informative understanding of the environment with fine details.

How does LiDAR work?

The working methodology of LiDAR includes sending a pulse of light and waiting for the return. It measures the total time period i.e. how long it takes to return the pulse. This finally assists in figuring out the distance between objects.

LiDAR Sensor Representation for Autonomous Vehicle

Fig. 1. Working of LiDAR

Application Areas of LiDAR
The fusion of LiDAR point clouds and camera images is a popular example of Multi-Remote Sensing Image Registration (MRSIR). As of today, LiDAR is of various types and forms such as static and mobile LiDARs. According to the geographical use, LiDAR is of terrestrial, aerial, and marine kinds.
The application of LiDAR is very broad. It has uses in surveying, archaeology, geology, forestry, and other fields such as:

  • Autonomous driving: LIR is used to align sensor data to create a more accurate and complete representation of the environment.
  • Robotics: Align sensor data to create more accurate maps and enable more precise localization.
  • 3D mapping: Align data from multiple sensors to create detailed 3D models of the environment.
  • Augmented Reality (AR): Synchronizing virtual elements to correspond with the physical environment.

Utilization of LiDAR in Self-Driving Vehicles

3D Point Cloud and Calculation of Distance
In the realm of road safety, numerous automobile manufacturers are either using or exploring the installation of LiDAR technology in their vehicles.

LiDAR Technology in Self-Driving Vehicles

Fig. 1. LiDAR Technology in Self-Driving Vehicles [Source: https://velodynelidar.com/what-is-lidar/#:~:text=A%20typical%20lidar%20sensor%20emits,calculate%20the%20distance%20it%20traveled]

By iterating this process multiple times within seconds, a detailed, live 3D representation of the environment is generated, referred to as a point cloud.

Advantages of Mounting Lidar Above Autonomous Vehicles
Within an autonomous vehicle, the LiDAR sensor captures extensive data through rapid analysis of numerous laser pulses. This information, forming a ‘3D point cloud‘ from laser reflections, undergoes processing by an integrated computer to generate a dynamic three-dimensional representation of the surroundings. Training the onboard AI model with meticulously annotated point cloud datasets becomes pivotal to ensuring the precise creation of this 3D environment by LiDAR. The annotated data empowers autonomous vehicles to detect, identify, and categorize objects, enhancing their ability to accurately discern traffic lanes, road signs, and moving entities, and evaluate real-time traffic scenarios through image and video annotations.
Beyond research, active exploration delves into the use of LiDAR technology within autonomous vehicles. Automakers have begun integrating LiDAR into advanced driver assistance systems (ADAS), enabling a comprehensive grasp of dynamic traffic conditions. The journey toward autonomous driving safety relies on these systems, which swiftly make precise decisions through meticulous analysis of vast data points, ensuring security through rapid computations.

Cutting-edge approaches
However, there still are challenges in developing a fully automated vehicle with a guarantee of 100% accuracy in critical tasks such as object detection and navigation. To overcome this challenge, many researchers and automobile companies have been trying to improve this technology. The cutting-edge approaches include broadly categorized architecture of methodologies involving four distinct pipelines: information-based pipeline, feature-based pipeline, ego-motion-based pipeline, and deep learning-based pipeline. There has been more accuracy and improvement in the sector of deep learning-based pipelines. LiDAR technology not only enhances convenience but also plays a pivotal role in reducing severe collisions. The latest advancements in this domain include the innovation of LiDAR sensors and the shift from traditional mechanical methods to cutting-edge FMCW and flash technologies.

Patenting Trends for LiDAR Technology in Autonomous Vehicles

The field of autonomous vehicle technology has witnessed a notable rise in patent submissions, especially concerning sensor technology, mapping techniques, decision-making algorithms, and communication systems. Pioneering the advancements are entities such as Google, Tesla, and Uber, whereas longstanding automotive giants like Ford, General Motors, and BMW have also been actively filing patents. In the United States, a significant emphasis lies on artificial intelligence (AI) and augmented reality within the market, with car manufacturers and developers collaborating to introduce self-driving vehicles to the public. Autonomous cars are predicted to change the driving experience and introduce a whole new set of problems.
Despite Sartre’s initial patent submission in the autonomous vehicle domain, it was perceived primarily as a patent related to an AI system designed for highway navigation or restricted roadways. There was a scarcity of US patent filings for self-driving cars before 2006, largely influenced by a trend that emerged in the late 1990s and persists today: a limited number of patents granted by the US Patent Office.

Challenges in Patenting Technology for Autonomous Vehicles
The challenges in patenting technology for self-driving vehicles emerge when these vehicles are involved in incidents or insurance-related events. Owners typically confront three choices:

  1. Assuming liability for any harm or property damage caused by their vehicle.
  2. Taking steps toward legal recourse against the involved driver.
  3. Exploring compensation from their insurance company to address losses resulting from the other driver’s negligence.
    However, legislative uncertainty still clouds the landscape concerning autonomous vehicles and traffic incidents.

Analysis of Patent Applications filed under Lidar in Autonomous Vehicles
Over the past few years, there has been a rapid growth in filing Patent Applications regarding the use of LiDAR in Autonomous Vehicles. As of today, it is marked that there are ~81,697 patents recorded around the globe. It has been observed that Ford Global Tech LLC with ~3,426 patents is a dominant player in the market. Similarly, LG Electronics and Waymo LLC stand in second and third position in the chart.

Analysis of Patent Applications filed under Lidar in Autonomous Vehicles

[Source: https://www.lens.org/lens/search/patent/list?q=LiDAR%20%20%2B%20Autonomous%20vehicle]
The following visual representations show the charts representing Legal Status and Patent Documents Over Time.

Legal Status and Patent Documents Over Time.
Patent Documents Over Time

[Source: https://www.lens.org/lens/search/patent/list?q=LiDAR%20%20%2B%20Autonomous%20vehicle]

Through an examination of patent filings across different geographic regions, it is evident that the United States, constituting approximately 78% of the overall patents submitted, holds the foremost position in this chart.

patent filings across different geographic regions

[Source: https://www.lens.org/lens/search/patent/list?q=LiDAR%20%20%2B%20Autonomous%20vehicle]

Conclusion

In conclusion, LiDAR technology used in self-driving vehicles has a huge scope in improving road safety. With the cutting-edge FMCW and flash technologies, the application of LiDAR in autonomous vehicles shows great improvements in terms of accuracy and comfort providing features like object detection and incredible navigation. Automobile companies such as Tesla and Toyota have already practiced the technology in their vehicles and companies having such huge turnovers are seeking forward to utilize the full potential of the technology. Technology holds the future of global advancement in technology.

Categories
Computer Science Electronics

Augmented Reality (AR) vs. Virtual Reality (VR): The Future of Tech

Augmented Reality (AR)

Augmented Reality (AR) has developed as a transformational and compelling technology that blurs the boundaries between the digital and physical worlds in a world where technology is continually developing. The term “augmented reality” describes the creative blending of digital components with our physical surroundings to produce an immersive and interactive experience that improves our perception of reality. AR enhances our everyday experiences by superimposing computer-generated images, visuals, or information onto the real world we view and interact with, in contrast to Virtual Reality (VR), which immerses users in wholly computer-generated settings. Through the employment of advanced technology like computer vision, sensors, and potent processing powers, this fusion of digital and physical aspects is made possible.

Applications of Augmented Reality

AR keeps redefining how we interact with our environment and obtain information in this quickly developing industry. We can use it to interact with difficult concepts, learn about items before making a purchase, and even help with medical operations. With its impact on society, culture, and daily life projected to increase rapidly in the future years, augmented reality’s potential seems limitless.

The way we see and interact with the world will surely change as augmented reality (AR) technology develops and becomes more widely available, stimulating new spheres of creativity and improving our comprehension of the places we live in. Technology’s fascinating new frontier, augmented reality, has the potential to transform many facets of our lives and influence how people interact with computers in the future.

Applications of Augmented Reality

A wide range of useful and cutting-edge applications for augmented reality (AR) effortlessly incorporate virtual components into the actual environment. With Pokémon GO, players may hunt virtual creatures in their actual surroundings, AR delivers engaging experiences in the entertainment and gaming industries. With the help of AR, education may make hard subjects more approachable for pupils by offering dynamic and entertaining learning content, such as anatomy representations or historical reenactments. By enabling customers to visually try on clothes or picture furniture in their homes before making a purchase, augmented reality (AR) in retail improves the buying experience.

Additionally, as it can superimpose maps and current information on the user’s field of view, augmented reality (AR) has useful uses in navigation and wayfinding. AR streamlines operations and lowers errors in the industrial sector by providing personnel with step-by-step visual guidance during maintenance and repair tasks. Medical personnel’s accuracy and safety are improved through AR-assisted procedures and medical visualization. AR continues to spur innovation across industries due to its adaptability and promise to improve many parts of our lives, creating new opportunities for user experiences, productivity, and communication.

Virtual Reality (VR)

Innovative technology known as virtual reality (VR) immerses viewers in computer-generated settings for a realistic and engaging experience. The use of customized headsets or head-mounted displays (HMDs) transports people to interesting and surprisingly lifelike virtual worlds. Advanced tracking technologies are used in VR to precisely replicate the user’s movements and gestures so they can interact with the virtual environment. This technology has a wide range of uses, including immersive gaming, simulated training scenarios for many industries, educational simulations, and therapeutic uses. VR technology has the potential to alter entertainment, education, training, and many other industries as it develops and becomes more widely available. It does this by opening up a whole new world of experiences that push the limits of conventional computer and human connection.

Applications of Virtual Reality

VR takes people to dynamic, lifelike landscapes using cutting-edge headsets and motion-tracking technologies, sparking their imaginations and offering chances for exploration, education, and enjoyment. VR has a wide range of applications, from gaming and education to medicine and architecture, among others. VR hardware’s potential to change industries and improve human experiences is limitless as it develops and becomes more widely available. Virtual Reality is at the vanguard of a revolutionary era in computing and human-computer interaction thanks to its capacity to open up new vistas of possibilities and transform how people interact with technology.

Applications of Virtual Reality

Virtual reality (VR) offers a wide range of uses in a variety of sectors and professions. In the world of video games, virtual reality offers gamers completely immersive experiences that immerse them in fanciful settings where they can interact with fictional characters and environments. By allowing for interactive and engaging simulations, virtual reality (VR) in education and training revolutionizes learning by allowing students to engage in historical events, scientific ideas, and professional settings.

Healthcare uses VR for patient therapy, medical teaching, and pain management, while professionals in architecture and design use it to show off 3D models and provide virtual tours of structures. The entertainment sector is also enriched by VR thanks to the additional storytelling opportunities and virtual concerts it provides. Social VR platforms enable meaningful connections by bringing people together in common virtual worlds. Other applications include virtual tourism, real estate, engineering simulations, military training, retail experiences, and artistic creations. As VR technology continues to evolve, its impact will expand, transforming industries and redefining the way we experience and interact with the world.

Top Market Players in AR-VR and Top patent holders

Several well-known corporations with a global presence lead the AR and VR industry, including Google, Microsoft, LG, Samsung Electronics, Sony, Apple Inc., etc. Through both organic and inorganic growth tactics, such as product launches and innovations, partnerships, contracts, expansions, and acquisitions, these businesses have enhanced their market positions. The following graph displays the businesses with the greatest number of global patents in the AR/VR industry:

Top Market Players in AR-VR and Top patent holders

Apple (Vision Pro)

A ground-breaking spatial computer that seamlessly combines digital material with the real environment while enabling users to remain present and socially engaged has been presented by Apple as Apple Vision Pro.

Vision Pro develops an unlimited canvas for apps that expands beyond the limitations of a conventional display and adds a completely three-dimensional user interface that is managed by the most instinctive and natural inputs — a user’s eyes, hands, and voice — that are currently available. Vision Pro’s vision, the first spatial operating system in the world, enables users to engage with digital information in a way that makes it seem like it is actually in their area. The ground-breaking Vision Pro design includes a dual-chip dual-display ultra-high-resolution display system with 23 million pixels spread over two monitors.

Apple (Vision Pro)

The brand-new Apple Vision Pro App Store is open to users and contains thousands of popular iPhone and iPad applications that work smoothly and automatically with the new input method for Vision Pro. Apple’s developer community may go much further and produce entirely new app experiences as well as modify existing ones for spatial computing by harnessing the potent and distinctive capabilities of Vision Pro and visionOS. The visionOS three-dimensional interface gives digital content the appearance and experience of being physically present in the user’s surroundings. It helps the user understand scale and distance by casting shadows and dynamically responding to ambient light.

Apple Vision Pro presents a whole new input system that is managed by a person’s eyes, hands, and voice to enable user navigation and interaction with spatial information. Apps may be browsed through by merely looking at them, selecting with a tap, scrolling with a wrist flick, or speaking commands.

Microsoft HoloLens

Microsoft HoloLens is a cutting-edge mixed-reality gadget created by Microsoft. HoloLens provides an immersive computing experience by combining augmented reality and virtual reality. It is worn like a headset and allows users to interact with 3D holographic pictures while remaining linked to reality. The gadget integrates gesture and voice control, allowing for hands-free and easy virtual content navigation. HoloLens uses powerful sensors and cameras for spatial mapping, ensuring that virtual items are precisely integrated into the user’s environment.

This technology is used in a variety of areas, including education, healthcare, and entertainment, and allows for visualization, training, and collaboration. Microsoft offers a holographic development platform to developers, encouraging creativity and the creation of unique apps. The second-generation HoloLens improves on its predecessor with improved ergonomics and a broader field of view. Microsoft HoloLens is a big step forward in mixed reality technology, providing users with a seamless combination of digital and physical worlds and unleashing immense possibilities for future applications.

Microsoft HoloLens
Microsoft HoloLens

Microsoft HoloLens is a cutting-edge mixed-reality device that changes the way people interact with digital material. It combines the finest of augmented and virtual reality technology to provide a one-of-a-kind and immersive computing experience. Users may see and interact with holographic pictures that are perfectly blended into their real-world surroundings by wearing the headset.

This is made feasible through a network of sensors, cameras, and processors that work together to correctly map and interpret the physical environment. The technology enables easy and natural holographic interaction. Hand gestures and voice instructions can be used to handle and control virtual objects, allowing for hands-free and immersive engagement. This breakthrough offers up a slew of new opportunities in a variety of industries, making it a potent tool for education, design, training, remote cooperation, and entertainment

Microsoft’s dedication to cultivating a dynamic ecosystem resulted in the development of the HoloLens development platform. This platform enables developers to create their own mixed-reality apps, stimulating creativity and propelling the technology’s progress in a variety of sectors. Microsoft debuted HoloLens 2, the device’s second incarnation, in 2019. This version has substantial enhancements such as a more ergonomic design, a bigger field of view, and improved hand-tracking capabilities.

HoloLens 2 expands on its predecessor’s triumphs, fixing prior shortcomings and giving an even smoother and more exciting mixed reality experience. Microsoft HoloLens continues to push the frontiers of mixed reality with its innovative technology and transformational applications, defining the future of how we perceive, interact with, and integrate digital material into our lives.