The evolution of the internet, from Web 1.0 to the current Web 3.0, has transformed the way we interact with the digital world. Web 1.0 was characterized by static web pages, while Web 2.0 ushered in the era of interactive platforms and social media. Today, Web 3.0 is leveraging decentralization and blockchain technologies to reshape the digital landscape. Amidst this transformation, the advent of Augmented Reality (AR) and Virtual Reality (VR) technologies has been profound. AR and VR have introduced immersive experiences, enabling new forms of digital interaction and collaboration. But this is just the beginning.
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Spatial computing, the convergence of AR and VR into a single, seamless computing experience, is poised to redefine how we perceive and engage with digital environments on a larger scale. In this article, we discuss the concept of spatial computing and how it works in the blockchain and web3 space.
Spatial computing refers to those aspects of technology that make it possible to meld the lines between physical and virtual reality. In technical terms, spatial computing combines traditional computational forms, data, and logic with 3d location to create user interfaces so immersive that digital elements look like physical ones.
A common misconception is that spatial computing is founded on the concepts of augmented reality and virtual reality. But, in truth, it is an umbrella term that integrates aspects of extended reality with web3 concepts like the metaverse.
Spatial computing is possible only when data is collected through input devices, analyzed, processed with the aid of machine learning, and reproduced as a 3d model that is overlaid over the physical world in real-time. The most common way this is achieved is through augmented reality and visual reality hardware. Spatial computing involves using software and hardware to display virtual (or digital) objects in your physical scene to make them appear real and tangible, like the way virtual reality games make it appear like you are really inside the game.
The most common use case for spatial computing is gaming and entertainment, but in recent times, VR and AR technology has become a valuable asset in manufacturing industries. But, spatial computing has also been used in education, medicine, and other industries.
The most common use case for spatial computing is gaming and entertainment but this innovation can be applied to so many other industries. Here are some of the use cases of in spatial computing in web3 and the blockchain space.
Outside of the blockchain, spatial computing has already begun to prove its usefulness in architecture, manufacturing, and design industries. A closely related industry is real estate. Spatial computing by itself makes it possible to envision a proposed building structure before it’s already been built. When integrated with web3 and blockchain technology, particularly with the concept of tokenization, new opportunities present themselves. Imagine this: an architect makes a digital rendition of a proposed building, tokenizes it, and stores it on the blockchain. Purposed buyers can take a tour of the proposed house even though it hasn’t been built. This seamless integration of spatial computing and blockchain technology makes it possible to explore the practicality of a building project as well as get feedback on the proposed market value of the project before it’s been built. This can save time and resources, amongst other things.
A very unique feature of blockchain space is the power of community. It’s easy to notice that the community of blockchain enthusiasts, particularly when linked to a specific project or network, is a close-knit one made of traders, developers, and tech enthusiasts alike.
Social networking already exists on the blockchain, but with the integration of spatial computing, interaction on these blockchain-based apps can move from the exchange of messages to a virtual collaborative environment where users can interact as though they were having a friendly conversation in person.
This use case, in particular, can apply to decentralized autonomous organizations, which are responsible for voting and deciding on relevant changes and events relating to a platform or network. Spatial computing can make it possible for DAO members to have a virtual work environment where deliberations can be made more extensively, and voting can be done more interactively.
Web3 gaming has, in its current form, touched the helm of spatial computing with the concept of the metaverse. A common trend in the web3 gaming space is the creation of virtual worlds with real-world elements like houses and the option to purchase an in-game NFT avatar. Spatial computing can improve the real-time play experience on these virtual world games.
A major barrier to the adoption of blockchain technology and cryptocurrency is the lack of knowledge. Blockchain technology is shrouded in a lot of technicalities, which makes the technology confusing and even intimidating for newbies. However, using spatial computing technology can bridge this gap in the education efforts of crypto platforms. Beyond explainer YouTube videos, it could be possible for users to watch and even try their hands at practical experiences of blockchain technology.
The convergence of the physical and digital realms is happening through spatial computing, unlocking a world of immersive and interactive experiences. Numerous Web 3 projects are already leveraging spatial computing. They include:
Decentraland is a virtual reality gaming and social media platform that offers users an opportunity to monetize their content. Built on the Ethereum blockchain, Decentraland incorporated VR through the use of VR hardware to create an interactive world rich with activities and sights. Beyond that, the platform creates immersive games or activities, such as the option to buy land and develop it while on the platform. Decentraland represents the perfect blend of blockchain technology and spatial computing. Buying property on the platform creates a record of ownership stored on the network. It is spearheaded by automated programs called smart contracts. On top of that, the platform makes it possible to interact so seamlessly that they can perform activities together.
Over is a blockchain-based platform that fills the gap for accurate 3d mapping by encouraging community participation and enabling real-time updates using augmented reality. With the rise of the technological age, traditional mapping methods have become almost extinct, and now mapping is dependent on 3d mapping techniques. The most common method for this mapping method is the deployment of sophisticated graphic processing units. Still, the costly and tech-heavy nature of these methods makes them inaccessible. Over arises to fill that gap with its visual position system with over 20 cm accuracy. Beyond the technological features, Over provides a mapper tool that encourages everyday users to participate in the mapping process in exchange for a reward.
With a market cap of over $500,000, Matryx is a decentralized platform that is tailored to solving scientific challenges using blockchain and VR technology. The project offers VR an opportunity for pharmaceutical professionals to design and simulate STEM innovations to almost perfect levels of accuracy. These innovations are treated as proposals or bounties) that can be accepted by supervising bodies like a private university company. Once accepted, a partnership is formed, and both parties can collaborate on research for that innovation with the hope of completing it. Maytryx provides a networking environment for manufacturers or research buffs to hear from different professionals in building the perfect innovation.
The metaverse is a concept that describes the evolution of the internet to a point where interacting with digital elements is as good as interacting with physical elements. The term is most commonly used to refer to web3 games, but it’s not just about games; it includes any application on the web that applies blockchain and spatial computing technology for a super immersive experience.
Now, people wonder what’s the difference between spatial computing and the metaverse. On the surface, they seem similar. Both concepts have the same end result to make it practical for human beings to interact with digital elements as though they really exist.
A better way to look at it is to understand that spatial computing is just one piece of the entire puzzle that is the metaverse. The metaverse is an all-encompassing term that covers game technology and essentially describes the next version of the web that is immersive instead of interactive. It’s like the future of the internet, shifting from regular web use to a full-on immersive experience.
Spatial computing, Web3, and blockchain technology are three emerging technologies that have the potential to revolutionize the way we interact with the digital world. By combining the immersive experiences of spatial computing with the decentralized and secure nature of Web3 and blockchain, we can create new and innovative applications that will transform the way we live, work, and play.
The evolution of the internet, from Web 1.0 to the current Web 3.0, has transformed the way we interact with the digital world. Web 1.0 was characterized by static web pages, while Web 2.0 ushered in the era of interactive platforms and social media. Today, Web 3.0 is leveraging decentralization and blockchain technologies to reshape the digital landscape. Amidst this transformation, the advent of Augmented Reality (AR) and Virtual Reality (VR) technologies has been profound. AR and VR have introduced immersive experiences, enabling new forms of digital interaction and collaboration. But this is just the beginning.
.
Spatial computing, the convergence of AR and VR into a single, seamless computing experience, is poised to redefine how we perceive and engage with digital environments on a larger scale. In this article, we discuss the concept of spatial computing and how it works in the blockchain and web3 space.
Spatial computing refers to those aspects of technology that make it possible to meld the lines between physical and virtual reality. In technical terms, spatial computing combines traditional computational forms, data, and logic with 3d location to create user interfaces so immersive that digital elements look like physical ones.
A common misconception is that spatial computing is founded on the concepts of augmented reality and virtual reality. But, in truth, it is an umbrella term that integrates aspects of extended reality with web3 concepts like the metaverse.
Spatial computing is possible only when data is collected through input devices, analyzed, processed with the aid of machine learning, and reproduced as a 3d model that is overlaid over the physical world in real-time. The most common way this is achieved is through augmented reality and visual reality hardware. Spatial computing involves using software and hardware to display virtual (or digital) objects in your physical scene to make them appear real and tangible, like the way virtual reality games make it appear like you are really inside the game.
The most common use case for spatial computing is gaming and entertainment, but in recent times, VR and AR technology has become a valuable asset in manufacturing industries. But, spatial computing has also been used in education, medicine, and other industries.
The most common use case for spatial computing is gaming and entertainment but this innovation can be applied to so many other industries. Here are some of the use cases of in spatial computing in web3 and the blockchain space.
Outside of the blockchain, spatial computing has already begun to prove its usefulness in architecture, manufacturing, and design industries. A closely related industry is real estate. Spatial computing by itself makes it possible to envision a proposed building structure before it’s already been built. When integrated with web3 and blockchain technology, particularly with the concept of tokenization, new opportunities present themselves. Imagine this: an architect makes a digital rendition of a proposed building, tokenizes it, and stores it on the blockchain. Purposed buyers can take a tour of the proposed house even though it hasn’t been built. This seamless integration of spatial computing and blockchain technology makes it possible to explore the practicality of a building project as well as get feedback on the proposed market value of the project before it’s been built. This can save time and resources, amongst other things.
A very unique feature of blockchain space is the power of community. It’s easy to notice that the community of blockchain enthusiasts, particularly when linked to a specific project or network, is a close-knit one made of traders, developers, and tech enthusiasts alike.
Social networking already exists on the blockchain, but with the integration of spatial computing, interaction on these blockchain-based apps can move from the exchange of messages to a virtual collaborative environment where users can interact as though they were having a friendly conversation in person.
This use case, in particular, can apply to decentralized autonomous organizations, which are responsible for voting and deciding on relevant changes and events relating to a platform or network. Spatial computing can make it possible for DAO members to have a virtual work environment where deliberations can be made more extensively, and voting can be done more interactively.
Web3 gaming has, in its current form, touched the helm of spatial computing with the concept of the metaverse. A common trend in the web3 gaming space is the creation of virtual worlds with real-world elements like houses and the option to purchase an in-game NFT avatar. Spatial computing can improve the real-time play experience on these virtual world games.
A major barrier to the adoption of blockchain technology and cryptocurrency is the lack of knowledge. Blockchain technology is shrouded in a lot of technicalities, which makes the technology confusing and even intimidating for newbies. However, using spatial computing technology can bridge this gap in the education efforts of crypto platforms. Beyond explainer YouTube videos, it could be possible for users to watch and even try their hands at practical experiences of blockchain technology.
The convergence of the physical and digital realms is happening through spatial computing, unlocking a world of immersive and interactive experiences. Numerous Web 3 projects are already leveraging spatial computing. They include:
Decentraland is a virtual reality gaming and social media platform that offers users an opportunity to monetize their content. Built on the Ethereum blockchain, Decentraland incorporated VR through the use of VR hardware to create an interactive world rich with activities and sights. Beyond that, the platform creates immersive games or activities, such as the option to buy land and develop it while on the platform. Decentraland represents the perfect blend of blockchain technology and spatial computing. Buying property on the platform creates a record of ownership stored on the network. It is spearheaded by automated programs called smart contracts. On top of that, the platform makes it possible to interact so seamlessly that they can perform activities together.
Over is a blockchain-based platform that fills the gap for accurate 3d mapping by encouraging community participation and enabling real-time updates using augmented reality. With the rise of the technological age, traditional mapping methods have become almost extinct, and now mapping is dependent on 3d mapping techniques. The most common method for this mapping method is the deployment of sophisticated graphic processing units. Still, the costly and tech-heavy nature of these methods makes them inaccessible. Over arises to fill that gap with its visual position system with over 20 cm accuracy. Beyond the technological features, Over provides a mapper tool that encourages everyday users to participate in the mapping process in exchange for a reward.
With a market cap of over $500,000, Matryx is a decentralized platform that is tailored to solving scientific challenges using blockchain and VR technology. The project offers VR an opportunity for pharmaceutical professionals to design and simulate STEM innovations to almost perfect levels of accuracy. These innovations are treated as proposals or bounties) that can be accepted by supervising bodies like a private university company. Once accepted, a partnership is formed, and both parties can collaborate on research for that innovation with the hope of completing it. Maytryx provides a networking environment for manufacturers or research buffs to hear from different professionals in building the perfect innovation.
The metaverse is a concept that describes the evolution of the internet to a point where interacting with digital elements is as good as interacting with physical elements. The term is most commonly used to refer to web3 games, but it’s not just about games; it includes any application on the web that applies blockchain and spatial computing technology for a super immersive experience.
Now, people wonder what’s the difference between spatial computing and the metaverse. On the surface, they seem similar. Both concepts have the same end result to make it practical for human beings to interact with digital elements as though they really exist.
A better way to look at it is to understand that spatial computing is just one piece of the entire puzzle that is the metaverse. The metaverse is an all-encompassing term that covers game technology and essentially describes the next version of the web that is immersive instead of interactive. It’s like the future of the internet, shifting from regular web use to a full-on immersive experience.
Spatial computing, Web3, and blockchain technology are three emerging technologies that have the potential to revolutionize the way we interact with the digital world. By combining the immersive experiences of spatial computing with the decentralized and secure nature of Web3 and blockchain, we can create new and innovative applications that will transform the way we live, work, and play.