# Lanxin VB1-I

> Source: https://aiwiki.ai/wiki/lanxin_robotics_vb1_i
> Updated: 2026-06-27
> Categories: Humanoid Robots, Robotics
> From AI Wiki (https://aiwiki.ai), a free encyclopedia of artificial intelligence. Quote with attribution.

The **Lanxin VB1-I** is a wheeled [humanoid robot](/wiki/humanoid_robot) and mobile manipulator developed by [Lanxin Robotics](/wiki/lanxin_robotics) (Hangzhou Lanxin Technology Co., Ltd.), a Chinese 3D vision company headquartered in Hangzhou, Zhejiang Province. It is a research and development variant of Lanxin's VersaBot platform, priced at approximately $120,000 USD, that pairs a human-scale upper body with five-finger dexterous hands on a dual-wheel differential base for [embodied AI](/wiki/embodied_ai) experimentation, logistics trials, and factory simulations.[3][12] The VB1-I sits in the middle of Lanxin's humanoid lineup, between the original [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1) and the more capable [VB2](/wiki/lanxin_robotics_vb2).

| | |
|---|---|
| **Developer** | [Lanxin Robotics](/wiki/lanxin_robotics) (Hangzhou Lanxin Technology Co., Ltd.) |
| **Type** | [Humanoid robot](/wiki/humanoid_robot) (research platform) |
| **Also known as** | VB1-I |
| **Country of origin** | China |
| **Height** | 1.65 m (5 ft 5 in) |
| **Dimensions** | 700 x 610 x 1,650 mm |
| **Weight** | 65 kg (143 lb) |
| **Degrees of freedom** | 42 (total); 6 per arm; 7 per hand |
| **Arm payload** | 2 kg (per hand) |
| **Max speed** | 1.5 m/s (5.4 km/h, 3.4 mph) |
| **Battery life** | 2 to 3 hours |
| **Navigation** | 3D Laser SLAM |
| **Driving mode** | Dual-wheel differential |
| **Price** | Approximately $120,000 USD |
| **Status** | In production |
| **Website** | [lanxinrobotics.com](https://www.lanxinrobotics.com/) |

The VB1-I is designed for [embodied AI](/wiki/embodied_ai) experimentation, logistics trials, and factory simulations, occupying a middle position in Lanxin's humanoid robot lineup between the original [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1) and the more advanced [VB2](/wiki/lanxin_robotics_vb2).

The VB1-I builds on the vision-first philosophy that Lanxin established with its VersaBot VB-1, the robot the company introduced at the 2024 World Robot Conference as the world's first "pure vision" humanoid robot. While the original VB-1 relied exclusively on [RGB-D cameras](/wiki/depth_sensor) and rejected [LiDAR](/wiki/lidar) entirely, the VB1-I adopts a hybrid sensing approach that combines panoramic RGB-D depth vision with 3D Laser SLAM navigation for improved localization accuracy. This shift reflects Lanxin's pragmatic engineering philosophy: deploying the most effective sensor combination for each product's target environment rather than adhering rigidly to a single sensing paradigm.[1][2]

The VB1-I is priced at approximately $120,000 USD and targets research laboratories, AI development teams, and industrial automation integrators who need a human-scale robotic platform for prototyping and experimentation.[3]

## What is the Lanxin VB1-I?

The Lanxin VB1-I is a full-scale, wheeled humanoid robot built as a research and development platform rather than a mass-deployment industrial worker. The "I" designation marks it as the industrial and research-oriented refinement of Lanxin's VersaBot concept: it keeps the human-scale upper body, but is repositioned for experimentation, logistics trials, factory simulation, and [embodied AI](/wiki/embodied_ai) research in laboratories and controlled industrial spaces.[3][12]

According to Lanxin's official product page, the VB1-I measures 700 x 610 x 1,650 mm, moves on a dual-wheel differential drive at up to 1.5 m/s, carries 2 kg per hand across arms with 6 joints each, and navigates using 3D Laser SLAM paired with a Panoramic RGB-D Depth Vision System. Its modular design allows future upgrades, making it suitable for long-term research projects where the platform evolves alongside the algorithms being developed on it.[12]

## Who makes the Lanxin VB1-I?

### Lanxin Robotics

The VB1-I is made by [Lanxin Robotics](/wiki/lanxin_robotics), formally Hangzhou Lanxin Technology Co., Ltd., which describes its mission as "empower robots with the intelligence to see and serve the human society."[9] Lanxin Robotics was founded in 2016 by Dr. Gao Yong, who holds a doctorate in pattern recognition and [artificial intelligence](/wiki/artificial_intelligence) from the Chinese Academy of Sciences. Prior to founding the company, Dr. Gao worked at Ricoh Japan and the Microsoft Asia Engineering Institute on [computer vision](/wiki/computer_vision) products. The company's core founding team includes researchers from the Chinese Academy of Sciences, Fudan University, and Zhejiang University, with approximately half of all staff dedicated to research and development.[4][5]

Headquartered at China Artificial Intelligence Town in Hangzhou, Lanxin was the first company in China to develop 3D visual perception technology specifically for [mobile robots](/wiki/autonomous_mobile_robot) and to achieve large-scale commercial deployment of that technology. The company operates under an organizational framework it describes as "one body and two wings": the main body is mobile robot systems (MRS), while the two wings are the MRDVS sensor division (3D visual sensor development) and the VMR robot division (visual perception mobile robots, including humanoid robots).[6][7]

By 2024, Lanxin had accumulated 156 national patents, including 41 invention patents, and reported a compound annual revenue growth rate exceeding 80% from 2019 to 2024. The company was listed among Hangzhou's quasi-unicorn companies in 2022 and was recognized as a national-level specialized and new "little giant" enterprise by the Chinese government in 2024.[4][8]

Notable clients for Lanxin's mobile robot and logistics solutions include Huawei, ZTE, BYD, Midea, Toshiba, Foxconn, Toyota, LG, Sharp, Mitsubishi, and COMAC, with deployments spanning the 3C electronics, semiconductor, photovoltaic, battery, automotive, and packaging industries.[1][9]

### Funding and IPO Plans

Lanxin Robotics has completed multiple rounds of financing since its founding. According to Crunchbase, the company raised a total of $15.83 million in disclosed funding as of its Series C round. Key investors include Tencent, Kunpeng Capital, Lanchi Ventures, Advantech Capital, Envision Capital, and Blue Horizon Capital.[10][11]

On May 7, 2025, Lanxin officially announced the completion of its C+ round of financing, led by Kunpeng Fund, with the total amount reported to be in the hundreds of millions of yuan. The company stated that the new capital would fund three priorities: deepening the research and development of 3D vision sensors, advancing the AI technology behind humanoid robots, and upgrading the global supply chain and service system. Lanxin operates two intelligent manufacturing bases, one in Huzhou, Zhejiang Province, and another in Gui'an New District, Guizhou Province.[6][10]

Lanxin has placed an initial public offering (IPO) on its agenda and is expected to pursue listing as what it has described as the "first stock of 3D visual perception robots" in China.[6]

### Development Context

The VB1-I emerged from Lanxin's strategy of iterating on humanoid robot platforms in response to deployment experience and customer feedback. The original [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1) was unveiled at the 2024 World Robot Conference in Beijing on August 23, 2024, where it was introduced as a wheeled-base humanoid with a pure vision navigation system and no LiDAR sensors. The VB-1 was designed for manufacturing logistics, material handling, and smart factory applications, relying on a humanoid upper body with gripper hands mounted on a wheeled mobile base.[1][2]

The VB1-I represents a refinement of this concept, repositioned specifically for research and development use cases. While the VB-1 was optimized for immediate industrial deployment, the VB1-I was designed with modularity and experimentation in mind, allowing researchers to test different control algorithms, manipulation strategies, and [AI](/wiki/artificial_intelligence) models on a human-scale platform.[3][12]

## Design and Architecture

### Physical Configuration

The VB1-I stands 1,650 mm (approximately 5 feet 5 inches) tall with overall dimensions of 700 x 610 x 1,650 mm. The robot weighs 65 kg (143 lb) and features a ground clearance of 30 mm and a rotation diameter of 580 mm. Its frame is constructed from aluminum alloy combined with composite materials, balancing structural rigidity with weight reduction.[3][12]

The robot features a humanoid upper body with a head, torso, and dual articulated arms. The upper body provides the human-scale form factor needed for research into human-robot interaction, object manipulation in environments designed for people, and whole-body coordination studies. The operating height range spans 0.2 to 2 meters, giving the VB1-I flexibility to reach both floor-level and elevated surfaces.[12]

### Mobility Platform

The VB1-I uses a dual-wheel differential driving mode for locomotion, as specified on Lanxin's official product page. This differentiates it from the VB-1 (which also uses a wheeled base but with different chassis geometry) and the [VB2](/wiki/lanxin_robotics_vb2) (which uses a four-wheel omnidirectional driving system). The dual-wheel differential configuration provides reliable, cost-effective mobility suited to structured indoor environments such as laboratories, test facilities, and factory floors. The maximum travel speed is 1.5 m/s (5.4 km/h).[12]

Some third-party robotics databases have described the VB1-I as featuring bipedal locomotion. However, the manufacturer's official specifications list a dual-wheel differential driving mode, consistent with Lanxin's broader product strategy of using wheeled bases to prioritize stability and reliability in controlled environments.[3][12]

### Navigation and Sensing

A notable departure from the original VersaBot VB-1 is the VB1-I's adoption of 3D Laser SLAM (Simultaneous Localization and Mapping) for its primary navigation system. The VB-1 was marketed as the world's first "pure vision" humanoid robot, using only RGB-D cameras and no LiDAR. The VB1-I instead uses 3D Laser SLAM for precise localization and mapping, acknowledging that laser-based methods can offer superior accuracy and repeatability in structured research environments where these qualities matter more than the cost savings of vision-only navigation.[12]

The robot also integrates a Panoramic RGB-D Depth Vision System, which provides rich three-dimensional environmental perception for obstacle detection, object recognition, and scene understanding. This combination of laser-based SLAM for navigation with vision-based sensing for perception creates a multi-modal sensor architecture that gives researchers flexibility in how they approach different experimental scenarios.[12]

Lanxin's proprietary LX-MRDVS (Lanxin Mobile Robot Deep Vision System) technology underpins much of the VB1-I's visual processing capability. The MRDVS sensor lineup is organized into four product series:[4][13]

| Series | Function | Key Specification |
|---|---|---|
| S-Series | Obstacle detection (dToF cameras) | 45 m long-range mapping and SLAM |
| M-Series | High-precision docking (iToF cameras) | 0.3 to 5 m range; wide FOV (H-108, V-82 degrees) |
| V-Series | Visual SLAM navigation | Proprietary top-view technology |
| V2 Pro | Integrated spatial intelligence (LiDAR + RGB + IMU) | 3 cm precision real-time localization for AGVs |

### Manipulation System

The VB1-I is equipped with two articulated arms, each featuring 6 joints (degrees of freedom). The arms can carry a gripping load of 2 kg per hand, which is suitable for handling lightweight objects commonly encountered in research scenarios such as grasping household items, sorting components, and performing pick-and-place tasks.[12]

The total system provides 42 degrees of freedom, distributed across the arms, hands, torso, head, and mobility platform. Each hand has 7 degrees of freedom and features five-finger dexterous hand designs. The five-finger configuration allows for more naturalistic grasping patterns compared to the gripper-style hands used on the original VB-1, supporting research into dexterous manipulation, [grasping algorithms](/wiki/robot_grasping), and human-like object interaction.[3]

The robot uses high-torque electric servo motors paired with [harmonic drive](/wiki/harmonic_drive) reducers (also called strain wave gears) throughout its actuator system. Harmonic drives are widely used in precision robotics because they offer high gear ratios in compact form factors, near-zero backlash, and smooth torque transmission. These properties are particularly important in a research platform where repeatable, precise motion is valued over raw payload capacity.[3]

### Computing and Software

The VB1-I runs on a Linux-based operating system, providing researchers with the flexibility to deploy custom software stacks, [ROS](/wiki/robot_operating_system) (Robot Operating System) packages, and [machine learning](/wiki/machine_learning) frameworks. Connectivity options include Ethernet and WiFi, allowing the robot to be integrated into laboratory networks, cloud computing environments, and multi-robot coordination setups.[3]

Lanxin's self-developed core controller serves as the central "brain" of the VB1-I. This controller has been iteratively optimized using operational data collected from Lanxin's fleet of industrial mobile robots deployed across hundreds of customer sites. The company argues that this data-driven optimization approach produces more reliable and stable operations, with superior business logic and task execution algorithms compared to controllers that have not benefited from large-scale deployment experience.[1][2]

### Multimodal AI Interaction

The VB1-I integrates what Lanxin calls a Multimodal AI Interaction Hub, a feature shared with the VB2. This system is designed to enable more natural communication between the robot and human operators or research subjects, supporting use cases in [human-robot interaction](/wiki/human_robot_interaction) research, natural language command interpretation, and multi-modal sensory integration studies.[12]

## Technical Specifications

The following table compiles verified specifications from Lanxin's official product page and third-party robotics databases.[3][12]

| Category | Parameter | Value |
|---|---|---|
| Physical | Height | 1,650 mm (5 ft 5 in) |
| Physical | Dimensions (L x W x H) | 700 x 610 x 1,650 mm |
| Physical | Weight | 65 kg (143 lb) |
| Physical | Material | Aluminum alloy + composite |
| Physical | Ground clearance | 30 mm |
| Physical | Rotation diameter | 580 mm |
| Mobility | Driving mode | Dual-wheel differential motor |
| Mobility | Maximum speed | 0 to 1.5 m/s (5.4 km/h) |
| Mobility | Operating height range | 0.2 to 2.0 m |
| Manipulation | Arm joints | 6 per arm |
| Manipulation | Gripping load | 2 kg (per hand) |
| Manipulation | Fingers per hand | 5 |
| Manipulation | DOF per hand | 7 |
| Manipulation | Total degrees of freedom | 42 |
| Sensing | Navigation | 3D Laser SLAM |
| Sensing | Vision system | Panoramic RGB-D Depth Vision System |
| Actuators | Motor type | High-torque electric servo motors |
| Actuators | Gear technology | Harmonic reducers |
| Power | Battery life | 2 to 3 hours |
| Environment | Working temperature | 0 to 40 degrees Celsius |
| Environment | Working humidity | 10 to 90% RH (no condensation) |
| Computing | Operating system | Linux |
| Connectivity | Interfaces | Ethernet, WiFi |
| Safety | Safe with humans | Yes |

## How does the VB1-I differ from the VersaBot VB-1 and VB2?

The VB1-I sits between the original VersaBot VB-1 and the VB2 in Lanxin's humanoid robot product line. Each model targets a different combination of use case, mobility, and capability level.

| Feature | [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1) | VB1-I | [VB2](/wiki/lanxin_robotics_vb2) |
|---|---|---|---|
| Unveiled | August 2024 | 2024/2025 | 2025 |
| Mobility | Wheeled base | Dual-wheel differential | Four-wheel omnidirectional |
| Height | 1.6 m | 1.65 m | 1.7 m |
| Weight | Not disclosed | 65 kg | Not disclosed |
| Navigation | 3D Pure Vision (no LiDAR) | 3D Laser SLAM | 3D Laser SLAM |
| Arm joints | Not disclosed | 6 per arm | 7 per arm |
| Payload (per hand) | 2 kg | 2 kg | 5 kg |
| Fingers per hand | Gripper | 5 (dexterous) | 5 (dexterous) |
| Total DOF | Not disclosed | 42 | 47 |
| Battery life | Not disclosed | 2 to 3 hours | 4 to 6 hours |
| Maximum speed | Not disclosed | 1.5 m/s | 1.2 m/s |
| Operating height | 0.72 to 1.2 m | 0.2 to 2.0 m | 0.4 to 2.0 m |
| Price | Not disclosed | ~$120,000 | ~$150,000 |
| Primary focus | Industrial manufacturing | Research and embodied AI | Industrial and embodied AI |
| AI features | Core controller | Multimodal AI Interaction Hub | Multimodal AI Interaction Hub |

Several design trends are visible across the product line. Navigation shifted from pure vision (VB-1) to 3D Laser SLAM (VB1-I and VB2), suggesting that Lanxin found laser-based SLAM more effective for the precision requirements of humanoid robot applications. Hand design evolved from simple grippers (VB-1) to five-finger dexterous hands (VB1-I and VB2), reflecting the growing importance of manipulation research. Payload capacity and degrees of freedom increase from the VB1-I to the VB2, with the VB2 gaining an additional joint per arm (7 versus 6) and more than doubling the gripping load (5 kg versus 2 kg).[1][3][12][14]

The VB2's four-wheel omnidirectional drive provides greater maneuverability than the VB1-I's dual-wheel differential system, allowing holonomic motion (the ability to move in any direction without first rotating). The VB2 also offers significantly longer battery life at 4 to 6 hours versus 2 to 3 hours. However, the VB1-I is approximately $30,000 less expensive, making it a more accessible entry point for research teams with limited budgets.[12][14]

## What is the Lanxin VB1-I used for?

The VB1-I is designed primarily for research and development rather than continuous industrial deployment. Its target applications include:

### Embodied AI Research

The VB1-I provides a physical platform for researchers working on [embodied artificial intelligence](/wiki/embodied_ai), the study of intelligent systems that learn through physical interaction with their environment. The robot's 42 degrees of freedom, five-finger dexterous hands, and multi-modal sensor suite allow researchers to experiment with [reinforcement learning](/wiki/reinforcement_learning), [imitation learning](/wiki/imitation_learning), and other AI training paradigms in a human-scale embodiment. The Linux-based operating system supports integration with popular AI frameworks and [deep learning](/wiki/deep_learning) libraries.[3][12]

### Logistics and Factory Simulation

Research teams developing autonomous logistics solutions can use the VB1-I to prototype and test material handling workflows in laboratory settings before deploying them on production systems. The robot's 2 kg payload, variable operating height (0.2 to 2.0 m), and dual-wheel mobility allow it to simulate common factory tasks such as picking items from shelves, sorting components, and transporting lightweight parts between workstations.[3][12]

### Human-Robot Interaction Studies

The VB1-I's human-scale form factor and Multimodal AI Interaction Hub make it suitable for studying how people respond to and collaborate with robotic systems. Researchers in [cognitive science](/wiki/cognitive_science), ergonomics, and social robotics can use the platform to investigate questions about trust, collaboration patterns, and communication modalities in human-robot teams.[12]

### Algorithm Development and Benchmarking

The modular design of the VB1-I allows researchers to upgrade hardware components over time, making it suitable for long-term projects where the robot platform needs to evolve alongside the algorithms being developed on it. The standardized sensor suite and actuator system provide a consistent benchmarking environment for comparing different control strategies, [path planning](/wiki/path_planning) algorithms, and manipulation policies.[3]

## OmniHead Modular System

In addition to its humanoid robot lineup, Lanxin Robotics has developed OmniHead, which the company describes as the world's first truly modular head for humanoid robots. Rather than requiring an entire system replacement when sensory or compute capabilities need upgrading, the OmniHead design allows operators to swap out individual components as needed. Lanxin has drawn an analogy to how smartphones became versatile through modular apps, arguing that humanoid robots will similarly become more adaptable through modular hardware.[15]

The OmniHead system is compatible with Lanxin's humanoid robot platforms and represents the company's broader strategy of building an upgradeable ecosystem rather than selling fixed-configuration robots.

## Competitive Context

The VB1-I entered the humanoid robotics market during a period of intense activity, particularly among Chinese companies. China's humanoid robot market is projected to reach approximately RMB 10.5 billion (US $1.4 billion) by 2026 and RMB 75 billion (US $10.3 billion) by 2029. Chinese firms dominated global humanoid robot shipments in 2025, with companies such as [AgiBot](/wiki/agibot) (which shipped over 10,000 units by early 2026), [Unitree Robotics](/wiki/unitree), and [UBTECH](/wiki/ubtech) leading in volume.[16][17]

The research platform segment in which the VB1-I competes includes offerings from several international and Chinese manufacturers. [Fourier Intelligence](/wiki/fourier_intelligence) offers the [GR-1](/wiki/fourier_intelligence_gr_1) and [GR-2](/wiki/fourier_intelligence_gr_2) as research-oriented humanoids. [EngineAI](/wiki/engineai) produces the [SE01](/wiki/engineai_se01) and [PM01](/wiki/engineai_pm01) platforms targeted at developers and researchers. Internationally, [Agility Robotics](/wiki/agility_robotics)' [Digit](/wiki/agility_robotics_digit), [1X Technologies](/wiki/1x_technologies)' [NEO](/wiki/1x_technologies_neo), and [Unitree Robotics](/wiki/unitree)' [G1](/wiki/unitree_g1) and [H1](/wiki/unitree_h1) all serve overlapping research and early-industrial market segments.

Unitree's launch of its R1 humanoid in mid-2025 at a price of just $5,900 significantly disrupted pricing expectations across the industry, though the R1 targets a different capability tier than the VB1-I. The VB1-I's $120,000 price point positions it in the mid-range of the research humanoid market, below premium platforms from companies like [Apptronik](/wiki/apptronik) ([Apollo](/wiki/apptronik_apollo)) and [Figure AI](/wiki/figure_ai) ([Figure 02](/wiki/figure_02)) but above the growing number of sub-$50,000 educational and entry-level platforms.[16][17]

Lanxin differentiates the VB1-I primarily through its heritage in industrial 3D vision technology. While most humanoid robot manufacturers began as robotics companies that later added vision systems, Lanxin started as a 3D visual perception company that expanded into robotics. This background gives Lanxin deep expertise in the sensor, algorithm, and software layers of the perception stack, which the company leverages across its entire product portfolio from standalone MRDVS sensors to integrated humanoid platforms.[4][6]

### Wheeled vs. Legged Humanoid Approaches

The VB1-I's use of a wheeled mobility platform places it in the "wheeled humanoid" category alongside robots such as the [Enchanted Tools Mirokai](/wiki/enchanted_tools_mirokai), [Pudu D9](/wiki/pudu_robotics_d9), and UniX AI Panther. This design approach trades the terrain versatility of bipedal locomotion for the stability, energy efficiency, and reliability that wheels provide in structured indoor settings. Wheeled humanoid robots have found growing adoption in retail assistance, customer service, indoor logistics, and research applications where navigating stairs or rough terrain is not required.[16][17]

The broader Chinese humanoid robot market includes both wheeled and bipedal platforms, with different companies choosing different approaches based on their target applications. Companies like AgiBot, Unitree, and UBTECH have focused primarily on bipedal designs, while Lanxin has consistently used wheeled bases across its VB-1, VB1-I, and VB2 platforms, reflecting its roots in industrial mobile robotics where wheels have proven more practical.[1][14]

## Explain Like I'm 5

The Lanxin VB1-I is a robot that is about as tall as a grown-up. It has a head, a body, and two arms with hands that have five fingers, just like people. But instead of legs and feet, it rolls around on wheels, which keeps it from tipping over. It uses cameras and a spinning laser to "see" where it is going and to pick up small objects. Scientists buy this robot, which is pretty expensive, so they can teach it new tricks and study how robots and people can work together.

## See Also

- [Lanxin Robotics](/wiki/lanxin_robotics)
- [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1)
- [VB2](/wiki/lanxin_robotics_vb2)
- [Humanoid robot](/wiki/humanoid_robot)
- [Humanoid robots](/wiki/humanoid_robots)
- [Embodied AI](/wiki/embodied_ai)
- [Autonomous mobile robot](/wiki/autonomous_mobile_robot)
- [Computer vision](/wiki/computer_vision)
- [LiDAR](/wiki/lidar)
- [Harmonic drive](/wiki/harmonic_drive)
- [Robot Operating System](/wiki/robot_operating_system)

## References

1. "Exciting News! Lanxin unveiled VersaBot (VB-1) at the 2024 World Robot Conference." Lanxin Robotics News, August 2024. [https://www.lanxinrobotics.com/news/Exciting%20News!%20Lanxin%20unveiled%20VersaBot%20(VB-1)%20at%20the%202024%20World%20Robot%20Conference](https://www.lanxinrobotics.com/news/Exciting%20News!%20Lanxin%20unveiled%20VersaBot%20(VB-1)%20at%20the%202024%20World%20Robot%20Conference)
2. "蓝芯科技荣膺'十大人形机器人创新企业'，VersaBot(威宝)做有'眼睛'的人形机器人." Lanxin Technology official news. [https://www.lanxincn.com/news_cont_546.html](https://www.lanxincn.com/news_cont_546.html)
3. "VB1-I Humanoid Robot by Lanxin Robotics." HumanoidSpecs.com. [https://humanoidspecs.com/robots/lanxin-robotics-vb1-i](https://humanoidspecs.com/robots/lanxin-robotics-vb1-i)
4. "杭州准独角兽，做出首个纯视觉类人形机器人" (Hangzhou quasi-unicorn produces the first pure-vision humanoid robot). Sina Finance, November 1, 2024. [https://finance.sina.com.cn/wm/2024-11-01/doc-incupefn3483097.shtml](https://finance.sina.com.cn/wm/2024-11-01/doc-incupefn3483097.shtml)
5. "Yong Gao." The Org, Lanxin Technology. [https://theorg.com/org/lanxin-technology/org-chart/yong-gao](https://theorg.com/org/lanxin-technology/org-chart/yong-gao)
6. "Lanxin Robotics Completes C+ Round of Financing of Hundreds of Millions of Yuan." China Mobile Robot Alliance (CMRA), May 2025. [https://cnmra.com/lanxin-robotics-completes-c-round-of-financing-of-hundreds-of-millions-of-yuan/](https://cnmra.com/lanxin-robotics-completes-c-round-of-financing-of-hundreds-of-millions-of-yuan/)
7. "蓝芯科技荣膺'十大人形机器人创新企业'" (Lanxin Robotics wins 'Top 10 Humanoid Robot Innovation Enterprise'). ChinaAGV.com, January 2025. [https://m.chinaagv.com/news/detail/202501/32288.html](https://m.chinaagv.com/news/detail/202501/32288.html)
8. "2024年中国人形机器人产业供应链十大创新代表性企业." Sina Finance, December 24, 2024. [https://finance.sina.com.cn/roll/2024-12-24/doc-ineaqhum1529951.shtml](https://finance.sina.com.cn/roll/2024-12-24/doc-ineaqhum1529951.shtml)
9. "About Us" and Lanxin Robotics official website. [https://www.lanxinrobotics.com/about/](https://www.lanxinrobotics.com/about/)
10. "Lanxin Robotics." Crunchbase Company Profile. [https://www.crunchbase.com/organization/lanxim-technology](https://www.crunchbase.com/organization/lanxim-technology)
11. "Vision System Developer Lanxin Technology Finishes B Round of Financing Worth Over 100 Million Yuan." Pandaily. [https://pandaily.com/vision-system-developer-lanxin-technology-finishes-b-round-of-financing-worth-over-100-million-yuan/](https://pandaily.com/vision-system-developer-lanxin-technology-finishes-b-round-of-financing-worth-over-100-million-yuan/)
12. "VB1-I." Lanxin Robotics official product page. [https://www.lanxinrobotics.com/humanoid-robots/vb1-i/](https://www.lanxinrobotics.com/humanoid-robots/vb1-i/)
13. MRDVS official website. [https://mrdvs.com/](https://mrdvs.com/)
14. "VB2." Lanxin Robotics official product page. [https://www.lanxinrobotics.com/humanoid-robots/vb2-2/](https://www.lanxinrobotics.com/humanoid-robots/vb2-2/)
15. "OMNIHEAD: The Modular Future of Humanoid Robotics." HouseBots. [https://www.housebots.com/news/omnihead-the-modular-future-of-humanoid-robotics](https://www.housebots.com/news/omnihead-the-modular-future-of-humanoid-robotics)
16. "Chinese Firms Dominated Global Humanoid Robot Shipments in 2025." Bloomberg, January 8, 2026. [https://www.bloomberg.com/news/articles/2026-01-08/chinese-firms-dominated-global-humanoid-robot-shipments-in-2025](https://www.bloomberg.com/news/articles/2026-01-08/chinese-firms-dominated-global-humanoid-robot-shipments-in-2025)
17. "Why China's humanoid robot industry is winning the early market." TechCrunch, February 28, 2026. [https://techcrunch.com/2026/02/28/why-chinas-humanoid-robot-industry-is-winning-the-early-market/](https://techcrunch.com/2026/02/28/why-chinas-humanoid-robot-industry-is-winning-the-early-market/)

