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eyeora XR believe this will be the case 100%. XR glasses will be the next computing platform as it will not only do the same a mobile phone can do now, it will improve on it and the UX (user experience). The convenience always replaces the less convenient option, it’s just the way we adapt (evolve) to do more with our time, with less effort. We are already seeing many variations of XR hardware coming to market, some will focus on high level immersive gaming UX and others a more social or professional application eg replace the physical workstation with a virtual multi-screen interface, that can be with you anywhere via these XR glasses. What will be required to make this XR hardware adoption easily managed by you the consumer? Platforms like eyeora XR that allow anyone (no coding) in minutes to easily customise 3D spaces and create mixed format XR content or experiences that is compatible to traditional devices as well as XR devices, with monetisation control and cross platform media distribution of video, images, audio, games, holograms etc… from one simple action. Bridging payment systems to benefit consumers and reward content creators of all kinds…. This is what eyeora XR offer today and what’s to come tomorrow in early 2025 will simply amaze you on the unlimited potential an XR strategy we offer could mean to your success in more ways than one. So pls Stay tuned or reach out to me. Congrats Meta with the new XR glasses and continued XR pioneering! The future will be better, if you prepare for it now.

Mind Data will get commercialized. Need to build Sovereign Data Exchange as early as possible. Data Tech is moving faster than Reg Tech. Monopoly cannot become the normal standard. Cannot lose this war against unregulated and Monopoly based AI Data Usage and centralised monetization.

CMOS Image Sensor Chips Market Exploring the Evolving Landscape & Unveiling the Power by 2024-2033 https://lnkd.in/durJyUQF Introduction: The CMOS image sensor chips market stands as a beacon of innovation and evolution within the realm of digital imaging technology. These chips, heralded for their efficiency and versatility, play a pivotal role in capturing the visual essence of our world across a multitude of devices, from smartphones to surveillance systems. This overview delves into the dynamic landscape of the CMOS image sensor chips market, shedding light on its growth trajectory, key drivers, challenges, and future prospects. Market Dynamics: The CMOS image sensor chips market is propelled by a confluence of factors, including the ubiquitous demand for high-resolution imaging solutions in consumer electronics, automotive applications, and beyond. The relentless pursuit of enhanced performance, coupled with the imperative for power efficiency, underscores the market's evolution. Moreover, the advent of novel applications such as artificial intelligence (AI) and augmented reality (AR) augurs new vistas of opportunity, driving innovation and market expansion. Key Drivers: Consumer Electronics Revolution: The proliferation of smartphones, tablets, and digital cameras underscores the insatiable appetite for superior imaging capabilities, catapulting CMOS image sensor chips into the spotlight. Automotive Innovation: The automotive industry's embrace of advanced driver-assistance systems (ADAS), coupled with the advent of autonomous vehicles, fuels demand for CMOS image sensor chips tailored to the rigors of vehicular applications. Security and Surveillance Imperatives: In an era marked by heightened security concerns, CMOS image sensor chips serve as the linchpin of surveillance systems, empowering real-time monitoring and threat detection. Healthcare Advancements: From diagnostic imaging to minimally invasive surgeries, CMOS image sensor chips underpin the evolution of medical technology, offering unprecedented clarity and precision. Challenges: Amidst the fervent pace of innovation, the CMOS image sensor chips market grapples with formidable challenges. Technical hurdles, ranging from noise reduction to dynamic range optimization, necessitate continual R&D investment. Furthermore, supply chain disruptions and regulatory complexities pose formidable barriers to market growth, compelling stakeholders to navigate a landscape fraught with uncertainty.   Receive the FREE Sample Report of CMOS Image Sensor Chips Market Research Insights @ https://lnkd.in/daRH7GbT   Market Segmentations: Global CMOS Image Sensor Chip Market: By Company • AMS • ASE • GalaxyCore • SmartSens Global CMOS Image Sensor Chip Market: By Type • Front-illuminated • Backside-illuminated Global CMOS

Will glasses be our main computing platform in the near future? I must tell tha pervasive tech would affect our cognitive processes, our ability to focus, and our human-to-human connections..🕶️😎

I completely agree with his perspective! The next wave of technology will likely involve visual enhancements, such as glasses or devices that integrate directly with the eye's retina. Imagine a future where everything you see is analysed by an AI assistant with an intelligence level far surpassing current models like ChatGPT. This assistant could provide real-time audio guidance to help you solve various problems simply by observing your surroundings. For instance, if you're struggling with plumbing issues, the AI could instruct you on how to repair your pipes, suggest where to purchase replacement parts, and recommend the necessary tools. Or, if your car is malfunctioning, it could quickly assess the problem, provide potential causes, and even compile a list of nearby mechanics while contacting them to explain the issue on your behalf. Honestly, we are very close to this reality. Should we embrace these advancements, or be cautious about their implications? In truth, it may not matter much, as we (the older generation) are merely transitional figures between the old and new worlds. Future generations will be born into this technology and will likely find it inseparable from their lives, just as today’s children are deeply connected to their smartphones. It’s fascinating to think about how quickly this technology could evolve!

Mark Zuckerberg predicts a tectonic shift—smart glasses will supplant phones as our primary computing platform by 2030. This assertion is not mere speculation; it is a vision of where immersive technology, AI, and user interaction are rapidly converging. Feasibility studies support the trajectory: Mobile devices transformed computing by placing powerful technology in our pockets, enhancing connectivity and accessibility. Now, the horizon expands toward augmented reality—merging digital overlays with our physical environment, offering unprecedented ways to interact with the world. But consider the implications: As smart glasses become mainstream, they won’t just be tools—they’ll reshape how we perceive information, navigate spaces, and communicate. Privacy, security, and societal norms will be forced to adapt to a new medium of constant, hands-free access. The very paradigm of interaction shifts from touch to a seamless, always-on experience. Yet, we must tread cautiously. How will such pervasive tech affect our cognitive processes, our ability to focus, and our human-to-human connections? The balance between enhancing human potential and preserving our autonomy will be paramount as we move into this augmented reality future. Smart glasses are more than devices—they are portals into the next wave of human experience. The future of computing is not just on the horizon; it is poised to sit on the bridge of your nose. #SmartGlasses #AugmentedReality #AI #Innovation #FutureOfTechnology #DigitalTransformation

Technology is changing rapidly and with that the way we work.

The evolution from 5G to 6G marks a leap toward faster speeds, lower latency, and smarter networks. While 5G has started to reshape industries, 6G will take it further, enabling new applications and transforming how we interact with technology. Here's a breakdown of the key technical aspects of 6G. 1. Ultra-High Speeds: 1 Tbps and Beyond One of the most defining features of 6G will be terabit-per-second (Tbps) speeds. While 5G delivers speeds up to 10-20 Gbps, 6G is expected to exceed 1 Tbps. This leap will be made possible by the use of terahertz (THz) frequencies, offering massive bandwidth but requiring dense, small-cell networks to overcome the shorter signal range of higher frequencies. Key Challenge: The higher frequency attenuation in terahertz bands means that new nano-antennas and metamaterials are needed to enhance signal propagation. Advanced Modulation: Efficient data coding schemes will also be crucial to achieve these extreme speeds. 2. Sub-Millisecond Latency 6G will target latency below 0.1 milliseconds, far surpassing 5G’s 1 ms goal. This ultra-low latency will be crucial for use cases like autonomous vehicles, remote surgeries, and real-time AR/VR. Edge Computing: Processing data closer to its source (edge computing) will be critical for reducing latency. AI Optimization: Artificial Intelligence (AI) will help predict network demands, ensuring real-time, low-latency connectivity. 3. AI-Powered Self-Organizing Networks AI will play a pivotal role in 6G networks, driving automation and self-optimization. Self-Organizing Networks (SONs): These networks will self-optimize, self-heal, and self-manage, automatically adjusting to changing network conditions. Dynamic Spectrum Allocation: AI will ensure efficient spectrum management, enabling the network to handle data traffic more effectively. 4. Holographic and 3D Communication 6G will enable holographic communication and immersive 3D experiences, transforming how we interact with digital content. Data Requirements: Real-time holographic communication will demand massive bandwidth and ultra-low latency, achievable through terahertz frequencies. New Display Technologies: Technologies like light-field displays will be needed to render these 3D experiences effectively. To be continued in next post..

CMOS Image Sensor Chips Market Exploring the Evolving Landscape & Unveiling the Power by 2024-2033 https://lnkd.in/durJyUQF Introduction: The CMOS image sensor chips market stands as a beacon of innovation and evolution within the realm of digital imaging technology. These chips, heralded for their efficiency and versatility, play a pivotal role in capturing the visual essence of our world across a multitude of devices, from smartphones to surveillance systems. This overview delves into the dynamic landscape of the CMOS image sensor chips market, shedding light on its growth trajectory, key drivers, challenges, and future prospects. Market Dynamics: The CMOS image sensor chips market is propelled by a confluence of factors, including the ubiquitous demand for high-resolution imaging solutions in consumer electronics, automotive applications, and beyond. The relentless pursuit of enhanced performance, coupled with the imperative for power efficiency, underscores the market's evolution. Moreover, the advent of novel applications such as artificial intelligence (AI) and augmented reality (AR) augurs new vistas of opportunity, driving innovation and market expansion. Key Drivers: Consumer Electronics Revolution: The proliferation of smartphones, tablets, and digital cameras underscores the insatiable appetite for superior imaging capabilities, catapulting CMOS image sensor chips into the spotlight. Automotive Innovation: The automotive industry's embrace of advanced driver-assistance systems (ADAS), coupled with the advent of autonomous vehicles, fuels demand for CMOS image sensor chips tailored to the rigors of vehicular applications. Security and Surveillance Imperatives: In an era marked by heightened security concerns, CMOS image sensor chips serve as the linchpin of surveillance systems, empowering real-time monitoring and threat detection. Healthcare Advancements: From diagnostic imaging to minimally invasive surgeries, CMOS image sensor chips underpin the evolution of medical technology, offering unprecedented clarity and precision. Challenges: Amidst the fervent pace of innovation, the CMOS image sensor chips market grapples with formidable challenges. Technical hurdles, ranging from noise reduction to dynamic range optimization, necessitate continual R&D investment. Furthermore, supply chain disruptions and regulatory complexities pose formidable barriers to market growth, compelling stakeholders to navigate a landscape fraught with uncertainty.   Receive the FREE Sample Report of CMOS Image Sensor Chips Market Research Insights @ https://lnkd.in/daRH7GbT   Market Segmentations: Global CMOS Image Sensor Chip Market: By Company • AMS • ASE • GalaxyCore • SmartSens Global CMOS Image Sensor Chip Market: By Type • Front-illuminated • Backside-illuminated Global CMOS

💡What is spatial computing, and how will mixed reality blur the lines between the physical and the digital realms? Definition of Spatial Computing: Spatial computing merges the digital and physical worlds by overlaying our environment with virtual and augmented reality. Devices like Microsoft’s HoloLens and Apple’s Vision Pro headsets facilitate this integration, making digital objects appear three-dimensional and blending them seamlessly with the real world. Evolution of Computing: Cathy Hackl describes spatial computing as the next evolution of computing, following mainframes, desktops, personal computers, and mobile devices. This shift extends computing beyond screens to understand and interact with the physical world. Applications in Various Fields: • Gaming: Companies like Marvel provide mixed-reality experiences that immerse users in their superhero universe. • Workplace: NASA used spatial computing to assemble parts of the Orion spacecraft, significantly reducing labor costs and hours by 90%. • Medical Field: Apple’s Vision Pro headset enables trainee clinicians to interact with a life-like heart simulation, enhancing medical training. Components of Spatial Computing: Four key components are necessary for spatial computing to thrive: • Hardware: Mixed-reality headsets and wearable AI devices. • Software: Computer vision and large AI models to understand the physical world. • Data: New data types, like 3D voxels, replacing 2D pixels. • Connectivity: Advanced connectivity beyond 5G, potentially requiring 6G. Challenges and Considerations: • Virtual Air Rights: As computing expands into the physical world, questions about who owns the virtual space around us arise, including rights to place ads or audio in this space. • Talent and Generational Shifts: Companies need to adapt to the preferences of Generation Alpha, who move fluidly between virtual and physical realms and have grown up as digital natives. Engaging with this generation involves understanding their digital habits and entrepreneurial spirit. Future Implications: Spatial computing promises to revolutionize interactions with technology, enhance workforce capabilities, and require new talent management strategies. Business leaders are advised to immerse themselves in digital experiences to better understand and engage with the emerging generation. #technology #innovation #future #digitaltransformation #spatialcomputing