by China has taken a significant stride in the global race toward next-generation computing with the launch of three new spatial computing chips. These advanced processors, developed by GravityXR Electronics and Technology Co. Ltd., were officially presented at the Spatial Computing Summit 2025, hosted in Ningbo, Zhejiang Province. Their release signals a major milestone in China’s ambition to elevate its presence in extended reality (XR), mixed reality (MR), and AI-driven intelligent hardware.
Spatial computing has emerged as one of the most important technological transformations of the decade. Unlike conventional computers that operate through flat displays, spatial computing enables systems to understand the physical world in three dimensions. This includes recognizing depth, tracking motion, analyzing spatial environments, and blending digital elements seamlessly into real-world settings. The technology underpins XR headsets, interactive robots, smart cars, virtual assistants, and a rapidly expanding range of AI-powered devices.
At the summit, Cui Ping, director of the Yongjiang Laboratory, emphasized that the heart of spatial computing lies in teaching digital systems how to genuinely “understand space.” According to her, this breakthrough relies on three critical capabilities: environmental perception, virtual-real integration, and natural interaction. Together, these functions allow data to break free from the confines of screens and instead become part of the user’s physical environment.
Cui described this next phase of computing as a world where digital information becomes as present and accessible as “air,” effortlessly blending into everyday life. Instead of tapping through apps on a phone or navigating interfaces on a computer, users will interact with digital content naturally, through gestures, movement, voice, or simply through the environment around them. This shift represents a fundamental change in how humans interact with technology.
GravityXR Unveils Three Chips Designed for a Spatial Computing Future
A major highlight of the event was GravityXR’s announcement of three purpose-built spatial computing processors: G-X100, G-VX100, and G-EB100. Each chip tackles a specific challenge in enabling real-time 3D interaction and expanding the capabilities of next-generation smart devices.
1. G-X100: High-Performance Chip for Immersive Mixed Reality
The G-X100 stands as GravityXR’s flagship product and is engineered specifically for mixed reality headsets and high-end XR platforms. One of its most notable achievements is its ultra-low latency response. Latency, the small delay between user action and device reaction, has long been a barrier for comfortable immersive experiences. Even slight lag can cause motion sickness or discomfort, limiting how long users can remain in VR and MR environments.
By dramatically reducing latency, the G-X100 allows MR systems to respond almost instantly to user movement, significantly enhancing comfort and realism. This improvement opens the door for wider adoption of MR in both consumer and professional settings. Industries such as industrial design, remote training, education, surgical simulation, architecture, and manufacturing all depend on responsive, real-time 3D visualization. A chip that minimizes delay can greatly improve the accuracy and usability of MR tools in these fields.
GravityXR highlighted that the G-X100 will support MR headsets that not only perform better but are also more comfortable for long-term wear. As global tech companies compete to define the future of headset computing, China’s introduction of the G-X100 positions it strongly within the fast-growing XR hardware landscape.
2. G-VX100: Ultra-Compact Chip Built for AI Glasses and Lightweight Wearables
The second product, G-VX100, distinguishes itself through its incredibly compact size. It is designed to be small enough to fit directly into the frame of standard eyewear, making it a key component for AI-powered smart glasses, slim AR wearables, and other lightweight devices.
Developing chips for glasses is a complicated task. They must deliver meaningful computational power while remaining energy-efficient, heat-controlled, and physically small. The G-VX100 successfully balances these requirements, offering robust performance in a tiny package.
With this chip, manufacturers can design glasses that look similar to everyday eyewear while offering advanced digital capabilities. This can include real-time language translation, turn-by-turn navigation projected in front of the user’s eyes, context-aware notifications, hands-free digital assistants, or environment-aware overlays for shopping, travel, and accessibility.
As the global tech industry moves toward practical AR glasses—devices that are lightweight enough to wear daily without discomfort—the G-VX100 gives China a competitive edge in producing wearable spatial computing hardware. GravityXR believes the chip will play a central role in the next trend of “invisible technology,” where advanced computing tools seamlessly integrate into a user’s routine without adding bulk or inconvenience.
3. G-EB100: Advanced Rendering Chip for XR Displays and Robotics
The third chip, G-EB100, focuses on graphics, display rendering, and visual processing, offering notable improvements in image clarity, animation smoothness, and overall visual quality for MR devices. Since immersive experiences rely heavily on high-fidelity visuals, the G-EB100 helps deliver clearer images, richer textures, and more realistic lighting effects.
However, the chip’s role extends far beyond XR headsets. GravityXR emphasized its potential in robotics, especially where expressive digital faces or realistic on-device interactions are required. With the G-EB100, robots can display more natural facial expressions, detailed animations, and responsive eye movements—features that are increasingly important in human-robot interaction.
This enhances the emotional and communication skills of robots used in education, hospitality, healthcare, customer service, and home assistance. As robots become more common in public spaces and workplaces, expressive capabilities are critical for building trust and improving user comfort. The G-EB100, therefore, plays a key part in shaping more intuitive and human-friendly robotic systems.
A Major Turning Point for China’s Spatial Computing Development
The Spatial Computing Summit 2025 was hosted by the China Mobile Communications Association, with participation from Yongjiang Laboratory and GravityXR. The event drew leading researchers, engineers, and industry experts who all expressed strong confidence in China’s progress in spatial computing technologies.
China has already made major investments in critical areas such as industrial metaverse development, XR infrastructure, smart robotics, and AI-enhanced digital environments. The introduction of these chips shows that China is moving firmly toward deeper innovation, not just in consumer electronics but also in advanced industrial applications.
Experts at the summit predicted rapid growth in China’s spatial computing sector over the coming years. As chips, sensors, optical modules, operating systems, and AI algorithms continue to improve, spatial computing is expected to become a core pillar of future digital ecosystems—impacting education, manufacturing, mobility, entertainment, retail, and more.
Toward a New Era of Intelligent and Immersive Technology
The unveiling of the G-X100, G-VX100, and G-EB100 chips is more than a technical accomplishment—it represents a clear shift toward a future where digital information exists naturally within our physical surroundings. These chips will support lighter AI glasses, smarter robots, and more comfortable MR headsets, helping shape the next generation of immersive technology.
As spatial computing continues to evolve, China’s innovations put the country at the forefront of global efforts to redefine how humans interact with digital information. With these new chips, China is stepping firmly into the future of computing—one where virtual content and physical environments blend seamlessly into an intelligent, interactive world.
