Robot dossier
Husky A300
Release
Oct 15, 2024
Price
Price TBA
Connectivity
6
Status
Available
Height
372 mm chassis height
Weight
78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configuration
Battery
Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycle
Speed
2.0 m/s
Payload
Up to 101.5 kg allowable payload on relatively flat terrain in the 40 Ah configuration; Clearpath markets a 100 kg max payload
Clearpath Robotics' Husky A300 is the next-generation version of the company's rugged Husky unmanned ground vehicle for robotics research, rapid prototyping, and light industrial deployments. The current platform pairs a weather-resistant IP54 chassis with four in-wheel brushless motors, ROS 2 Jazzy support, payload power breakouts, and configurable battery packs for long outdoor test days. Clearpath positions it as a build-and-expand research base: users can add cameras, LiDAR, GPS, manipulators, custom payloads, or the Husky AMP package with OutdoorNav autonomy software for field missions. It is a research and industrial platform rather than a consumer home assistant, but its open ROS stack, heavy payload capacity, outdoor autonomy path, and mobile-manipulation package ecosystem make it useful context for tracking capable mobile robots.
Listed price
Price TBA
Clearpath's official product page uses quote/contact-sales flows and does not publish a manufacturer MSRP.
Release window
Oct 15, 2024
Current status
Available
Clearpath Robotics
Last verified
Jun 23, 2026
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Technical overview
A fast read on the mechanical profile, sensing package, and platform integrations behind Husky A300.
Height
372 mm chassis height
Weight
78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configuration
Dimensions
990 x 698 x 372 mm
Battery Life
Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycle
Charging Time
Standard charger: 4-12 h in North America or 5-15 h in Europe depending on battery configuration; faster optional chargers are available
Max Speed
2.0 m/s
Payload
Up to 101.5 kg allowable payload on relatively flat terrain in the 40 Ah configuration; Clearpath markets a 100 kg max payload
Operational profile
Capabilities
12
Connectivity
6
Key capabilities
Ecosystem fit
Certifications
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The Husky A300 is a Research robot built by Clearpath Robotics. Clearpath Robotics' Husky A300 is the next-generation version of the company's rugged Husky unmanned ground vehicle for robotics research, rapid prototyping, and light industrial deployments. The current platform pairs a weather-resistant IP54 chassis with four in-wheel brushless motors, ROS 2 Jazzy support, payload power breakouts, and configurable battery packs for long outdoor test days. Clearpath positions it as a build-and-expand research base: users can add cameras, LiDAR, GPS, manipulators, custom payloads, or the Husky AMP package with OutdoorNav autonomy software for field missions. It is a research and industrial platform rather than a consumer home assistant, but its open ROS stack, heavy payload capacity, outdoor autonomy path, and mobile-manipulation package ecosystem make it useful context for tracking capable mobile robots.
Pricing has not been publicly disclosed. See all Clearpath Robotics robots on the Clearpath Robotics page.
Detailed specifications for the Husky A300
Height
372 mm chassis heightAt 372 mm chassis height, the Husky A300 is sized for its intended operating environment and use cases.
Weight
78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configurationWeighing 78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configuration, the Husky A300 balances structural integrity with portability and maneuverability.
Dimensions
990 x 698 x 372 mmThe overall dimensions of 990 x 698 x 372 mm define the robot's physical footprint and determine what spaces it can navigate and what clearances it requires for operation.
Battery Life
Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycleWith a battery life of Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycle, the Husky A300 can operate for sustained periods before requiring a recharge. Battery life is measured under typical operating conditions and may vary based on workload intensity and environmental factors.
Charging Time
Standard charger: 4-12 h in North America or 5-15 h in Europe depending on battery configuration; faster optional chargers are availableA charging time of Standard charger: 4-12 h in North America or 5-15 h in Europe depending on battery configuration; faster optional chargers are available means the ratio of operation to downtime is an important consideration for applications requiring near-continuous availability. Some deployments use multiple robots in rotation to maintain uninterrupted service.
Maximum Speed
2.0 m/sA top speed of 2.0 m/s is calibrated for the robot's primary operating environment and safety requirements.
Payload Capacity
Up to 101.5 kg allowable payload on relatively flat terrain in the 40 Ah configuration; Clearpath markets a 100 kg max payloadA payload capacity of Up to 101.5 kg allowable payload on relatively flat terrain in the 40 Ah configuration; Clearpath markets a 100 kg max payload determines what the robot can carry or manipulate. This is a critical spec for practical applications where the robot needs to handle physical objects.
The Husky A300 uses Ships with Ubuntu/ROS 2 Jazzy support, Clearpath documentation, tutorials, demos, and ROS developer utilities. The Husky AMP configuration adds OutdoorNav autonomy software, an integrated outdoor sensor suite, mission setup through a web interface, and API access for custom applications. as its intelligence backbone. This AI platform powers the robot's decision-making, perception processing, and autonomous behavior. The sophistication of the AI stack directly impacts how well the robot handles unexpected situations and adapts to new environments.
The Husky A300 integrates 6 sensor types, forming the perceptual foundation that enables autonomous operation.
This sensor configuration enables the Husky A300 to perceive its environment and operate autonomously in its intended use cases. Multiple sensor modalities provide redundancy and more robust perception than any single sensor type alone.
Explore sensor technologies: components glossary · full components directory
Research robots serve as platforms for advancing robotics science and engineering. They enable researchers to test theories about locomotion, manipulation, perception, and human-robot interaction in controlled and real-world environments.
The Husky A300 offers 12 distinct capabilities, each contributing to the robot's practical utility.
These capabilities work together with the robot's 6 onboard sensor types and Ships with Ubuntu/ROS 2 Jazzy support, Clearpath documentation, tutorials, demos, and ROS developer utilities. The Husky AMP configuration adds OutdoorNav autonomy software, an integrated outdoor sensor suite, mission setup through a web interface, and API access for custom applications. AI platform to deliver practical, real-world performance.
The Husky A300 integrates with the following platforms and ecosystems, extending its utility beyond standalone operation.
This ecosystem compatibility enables the Husky A300 to work as part of a broader automation setup rather than operating in isolation.
12
Capabilities
6
Sensor Types
AI
Ships with Ubuntu/ROS 2 Jazz…
How the Husky A300 communicates with your network, smart home devices, cloud services, and companion apps.
The Husky A300 by Clearpath Robotics integrates 13 distinct technology components across sensing, connectivity, intelligence, and interaction layers. The physical platform features a height of 372 mm chassis height, a weight of 78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configuration, a top speed of 2.0 m/s, providing the foundation on which this technology stack operates.
The perception layer is built on Standard 6-axis IMU, Wheel and motor feedback, Programmable status lights, Electronic paper battery/status display, Optional cameras, LiDAR, GPS, wireless emergency stop, and manipulator payloads, Husky Vision Package with stereo cameras and Ouster LiDAR. These work in concert to give the robot a detailed understanding of its operating environment. This multi-sensor approach provides redundancy and enables the robot to function reliably even when individual sensors encounter challenging conditions such as low light, reflective surfaces, or cluttered spaces.
For communications, the Husky A300 relies on ROS 2 Jazzy, Ethernet payload integration, Gigabit Ethernet debug port, USB 3.0 debug port, HDMI debug port, Wi-Fi through configured computer/package options. This connectivity stack ensures the robot can communicate with cloud services, local smart home devices, mobile apps, and other networked systems in its environment.
Ships with Ubuntu/ROS 2 Jazzy support, Clearpath documentation, tutorials, demos, and ROS developer utilities. The Husky AMP configuration adds OutdoorNav autonomy software, an integrated outdoor sensor suite, mission setup through a web interface, and API access for custom applications. serves as the computational brain, processing sensor data, making navigation decisions, and orchestrating the robot's autonomous behaviors. The quality of this AI platform directly influences how well the robot handles novel situations, adapts to changes in its environment, and improves its performance over time through learning.
Research robots are acquired by universities, government labs, and corporate R&D departments. They serve as experimental platforms for developing new algorithms, testing locomotion strategies, and advancing the field of robotics. Some are also used for educational purposes.
Open-source software compatibility (ROS/ROS 2), sensor modularity, programmability, available SDK/API quality, community support, and published research papers using the platform are key factors. Documentation quality and the ability to modify both hardware and software are essential for research use.
Pricing
The Husky A300 is currently available for purchase. Check the manufacturer's website or authorized retailers for the latest stock and ordering information.
Engineering compromises and where this research robot excels
With 6 sensor types onboard, the Husky A300 has one of the more comprehensive perception systems in the research category. This multi-modal approach enables robust environmental awareness, redundant obstacle detection, and reliable autonomous operation even in challenging conditions. More sensor diversity generally translates to better real-world adaptability.
Supporting 6 connectivity protocols gives the Husky A300 flexible integration options. Whether connecting to local smart home networks, cloud services, or companion devices, the breadth of connectivity ensures compatibility across a wide range of deployment scenarios and reduces the risk of network-related limitations.
With 12 distinct capabilities, the Husky A300 is designed as a versatile platform rather than a single-task device. This breadth means the robot can handle varied scenarios and workflows, reducing the need for multiple specialized robots and increasing its utility across different situations.
A battery life of Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycle provides substantial operational runway. For research applications, this means longer work sessions between charges, fewer interruptions, and the ability to complete larger tasks or cover more area in a single charge cycle.
A top speed of 2.0 m/s provides the Husky A300 with the agility to cover ground efficiently. This is particularly valuable for applications that require rapid response, large-area coverage, or keeping pace with human movement in shared environments.
With a payload capacity of Up to 101.5 kg allowable payload on relatively flat terrain in the 40 Ah configuration; Clearpath markets a 100 kg max payload, the Husky A300 can handle meaningful physical tasks. This capacity enables practical applications like carrying tools, transporting materials, or supporting equipment mounts that lighter robots simply cannot accommodate.
With a charging time of Standard charger: 4-12 h in North America or 5-15 h in Europe depending on battery configuration; faster optional chargers are available compared to a battery life of Average 8 h, 16 h, or 24 h depending on 40 Ah, 80 Ah, or 120 Ah battery configuration under Clearpath's stated duty cycle, the Husky A300 spends more time charging than operating. This ratio is common in high-performance robotics but is an important factor for planning continuous-availability deployments.
At 78.5 kg to 105 kg depending on 40 Ah, 80 Ah, or 120 Ah battery configuration, the Husky A300 is a substantial piece of equipment. This weight contributes to stability and robustness but also means the robot requires careful consideration of floor load limits, transportation logistics, and the potential impact force in the event of unexpected contact with people or objects.
Clearpath Robotics has not published a public price for the Husky A300. While common for enterprise-class robotics, the absence of transparent pricing can complicate budgeting and comparison shopping. Prospective buyers will need to engage directly with the manufacturer for quotes, which may vary by configuration and volume.
Note: This strengths and trade-offs assessment is based on the Husky A300's documented specifications as tracked in the ui44 database. Real-world performance depends on deployment conditions, firmware maturity, and environmental factors. For the most current information, check the Clearpath Robotics manufacturer page or visit the official product page. Use the comparison tool to evaluate these trade-offs against competing robots in the same category.
Understanding the engineering behind this category
Research robots serve a fundamentally different purpose than commercial or consumer models. They are platforms for discovery — enabling scientists and engineers to test theories, develop algorithms, and push the boundaries of what robots can do. The technology in research robots prioritizes openness, flexibility, and access to raw data over consumer-friendly packaging or commercial reliability. Understanding this distinction is important for anyone considering a research robot platform.
Research robots typically expose their navigation systems at a much lower level than commercial products. Researchers can access raw sensor data, modify SLAM algorithms, implement custom path planners, and test novel navigation approaches. ROS (Robot Operating System) and ROS 2 compatibility is standard, providing a common framework for sharing navigation modules across the research community. This openness enables rapid iteration — a researcher can swap between different SLAM implementations, test new obstacle avoidance strategies, or develop entirely novel navigation paradigms without being locked into a vendor's proprietary stack.
Research robots serve as physical testbeds for AI algorithms that may eventually appear in commercial products years later. Reinforcement learning, imitation learning, few-shot task learning, and human-robot interaction studies all require robot platforms that can execute AI-generated commands in the physical world. The gap between simulation (where training is cheap and fast) and reality (where physics is unforgiving) makes physical robot platforms essential for validating AI approaches. Research robots must support rapid deployment of new AI models without extensive integration work.
Research platforms prioritize sensor modularity and data access. Standard mounting interfaces allow researchers to attach custom sensors alongside built-in ones. Raw sensor data streams (not just processed results) are accessible for developing novel perception algorithms. Precise time-stamping and synchronization across sensor streams enable accurate multi-modal fusion research. Many research robots include more sensors than strictly necessary for any single application, providing researchers with rich datasets for developing and testing new algorithms.
Research robots balance operational runtime with practical lab use. Sessions of one to four hours are typical, with quick charging between experiments. Some research setups use tethered power for long-running experiments where battery limitations would interrupt data collection. Power monitoring and logging capabilities help researchers understand the energy costs of different behaviors and algorithms — important for developing efficient approaches that will eventually run on battery-constrained commercial systems.
Research environments present unique safety challenges because robots are constantly being programmed with untested behaviors. Hardware safety limits (joint speed caps, force limits, emergency stops) must be robust regardless of software commands. Safety-rated monitored stop and speed monitoring ensure the robot cannot exceed safe operating parameters even when running experimental code. Collaborative operation standards apply when researchers work alongside the robot during experiments. Many labs implement layered safety with physical barriers for high-speed testing and open-area operation restricted to validated, lower-risk behaviors.
Research robot platforms are becoming more accessible and capable. Cloud robotics enables remote experiment execution and shared datasets. Digital twins and high-fidelity simulators reduce the need for physical hardware time while improving sim-to-real transfer. Standardized benchmarks and open datasets enable fair comparison of results across labs. The democratization of robotics research — through lower-cost platforms, open-source software, and cloud infrastructure — is expanding who can contribute to advancing the field.
The Husky A300 by Clearpath Robotics incorporates many of these technology pillars. For a detailed look at the specific sensors and components used in the Husky A300, see the sensor analysis and connectivity sections above, or browse the complete components glossary for explanations of every technology used across the robotics industry.
How this robot compares in the research landscape
Clearpath Robotics has not publicly disclosed pricing for the Husky A300, which is typical for enterprise-focused robotics platforms that offer customized solutions and direct-sales relationships.
With 6 sensor types, the Husky A300 has an extensive sensor suite. This comprehensive sensing capability places it among the more perception-capable robots in the research category, enabling more robust autonomous operation in varied conditions.
Being currently available for purchase gives the Husky A300 a practical advantage over competitors still in development or prototype stages. Buyers can evaluate the actual product rather than relying on spec-sheet promises that may change before release.
Side-by-side specs, capability overlap analysis, and key differentiators.
For the full picture of Clearpath Robotics's portfolio and market strategy, visit the Clearpath Robotics manufacturer page.
What the public profile tells you, and what still needs direct vendor confirmation
From a buying and rollout perspective, the Husky A300 should be read as a research platform aimed at labs and development teams validating robotics workflows. ui44 currently tracks 12 capability signals, 6 sensor inputs, and a last verification date of 2026-06-23. That mix gives buyers a useful first-pass picture, but it is still only the public layer of due diligence, especially when procurement, uptime, and support commitments are decided directly with Clearpath Robotics.
Commercial model
Pricing not public
Clearpath's official product page uses quote/contact-sales flows and does not publish a manufacturer MSRP.. That usually means the final commercial package depends on deployment scope, services, or negotiated terms.
Integration posture
6 connectivity options
The profile lists ROS 2 Jazzy, Ethernet payload integration, Gigabit Ethernet debug port, USB 3.0 debug port, HDMI debug port, Wi-Fi through configured computer/package options, plus Ships with Ubuntu/ROS 2 Jazzy support, Clearpath documentation, tutorials, demos, and ROS developer utilities. The Husky AMP configuration adds OutdoorNav autonomy software, an integrated outdoor sensor suite, mission setup through a web interface, and API access for custom applications. as the AI stack. That is enough to infer the basic network posture, but buyers should still confirm APIs, fleet management, and workflow integration details. ui44 currently tracks 10 declared compatibility links.
Spec disclosure
7/7 core specs public
The profile exposes the full operating-envelope set that ui44 tracks for this section, giving buyers a relatively clear starting point for technical validation.
The current profile is detailed enough to support early comparison work, shortlist creation, and cross-checking against other research robots. It is still worth validating the final deployment package, because integration services, support coverage, software entitlements, and site-preparation requirements often sit outside the raw hardware spec sheet.
If you want a faster apples-to-apples read, compare the Husky A300 against nearby alternatives in ui44's compare view, then cross-check the underlying AI, sensor, and subsystem terms in the components glossary. For manufacturer-level context, the Clearpath Robotics profile helps anchor this robot inside the wider product lineup.
Practical guide from day one through years of ownership
Research robot setup combines hardware assembly with software environment configuration. Unpack and assemble the platform following the manufacturer's documentation. Install the development framework — typically ROS or ROS 2 — and verify sensor connectivity. Calibrate all sensors using the manufacturer's tools and procedures. Set up the simulation environment (Gazebo, Isaac Sim, or equivalent) alongside the physical platform for parallel development. Establish version control for your experiment code and configuration. Document the initial calibration values and system state as your baseline for future reference. Plan network and computing infrastructure to handle the data rates your sensors will generate.
Research robots need maintenance that preserves the precision required for valid experimental results. Regularly verify sensor calibration — drift in camera intrinsics or IMU biases can invalidate experiment data. Maintain clean workspace conditions to protect optical sensors. Document any hardware modifications or maintenance performed, as these can affect experimental reproducibility. Update software dependencies carefully, documenting versions used for each experiment. Joint and actuator wear in research robots that perform repetitive tasks should be monitored and factored into experimental design.
Research robot software updates require careful management to maintain experiment reproducibility. Document the exact software versions used for each experiment. Test updates in a separate environment before applying to your experiment platform. Contribute bug fixes and improvements back to the community when using open-source frameworks. Be aware that ROS and other framework updates may require code changes in your custom packages — budget time for integration testing after major framework updates.
Research robots often have longer productive lives than commercial products because they can be upgraded and repurposed. Extend your investment by maintaining clean mechanical and electrical systems, documenting all modifications for future lab members, and keeping spare parts for common wear items. When specific components become obsolete, community forums and lab networks can be valuable sources for replacements. Consider the platform's modularity when planning future research directions — a platform that can accept new sensors and actuators adapts to evolving research questions.
For Clearpath Robotics-specific support resources and documentation, visit the Clearpath Robotics page on ui44 or check the manufacturer's official website at Clearpath Robotics's product page.
All Husky A300 data on ui44 is verified against official Clearpath Robotics sources, including spec sheets, product pages, and press releases. Last verified: 2026-06-23. Official source: Clearpath Robotics product page. If you find outdated or incorrect information, please let us know — accuracy is our top priority.
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