Robot dossier

Verified Jul 4, 2026

Apollo 2

Release

Jun 30, 2026

Price

Price TBA

Connectivity

1

Status

Active

Humanoid Active

Apollo 2

Apollo 2 is Apptronik's current-generation humanoid platform, unveiled with its expanded Robot Park data-collection facility in Austin. The platform is offered in both bipedal and wheeled-base configurations so Apptronik can train and deploy the same core humanoid technology across logistics, manufacturing, retail, and other real-world work environments. Official materials describe Apollo 2 as the Robot Park workhorse for more than a year, with fleets already operating at Apptronik facilities and customer or partner sites, while data from teleoperation and autonomous execution supports Apptronik's Google DeepMind collaboration on Gemini Robotics models and the future Apollo 3 commercial fleet.

Listed price

Price TBA

No public pricing or general commercial sale terms announced; Apollo 2 is active in Apptronik Robot Park and customer/partner data-collection deployments.

Release window

Jun 30, 2026

Current status

Active

Apptronik

Last verified

Jul 4, 2026

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Technical overview

Core specifications and system stack

A fast read on the mechanical profile, sensing package, and platform integrations behind Apollo 2.

Technical Specifications

Height

Not officially disclosed

Weight

Not officially disclosed

Battery Life

Swappable batteries designed for 7x22 operation; per-pack runtime not officially disclosed

Charging Time

Not officially disclosed; supports opportunity charging and tethering

Max Speed

Not officially disclosed

Operational profile

How this robot is configured

Capabilities

8

Connectivity

1

Key capabilities

Bipedal humanoid mobilityWheeled-base humanoid mobilityDexterous manipulationHuman-robot interaction with speech, listening, LED mouth, and chest displayTeleoperated and autonomous real-world data collectionLogistics and manufacturing task trainingRetail and customer-site workflow trainingFleet monitoring and task orchestration

Ecosystem fit

Apptronik ArtemisApptronik Fleet ConnectGoogle DeepMind Gemini Robotics research collaboration

About the Apollo 2

4Sensors1Protocol8Capabilities

The Apollo 2 is a Humanoid robot built by Apptronik. Apollo 2 is Apptronik's current-generation humanoid platform, unveiled with its expanded Robot Park data-collection facility in Austin. The platform is offered in both bipedal and wheeled-base configurations so Apptronik can train and deploy the same core humanoid technology across logistics, manufacturing, retail, and other real-world work environments. Official materials describe Apollo 2 as the Robot Park workhorse for more than a year, with fleets already operating at Apptronik facilities and customer or partner sites, while data from teleoperation and autonomous execution supports Apptronik's Google DeepMind collaboration on Gemini Robotics models and the future Apollo 3 commercial fleet.

Pricing has not been publicly disclosed. See all Apptronik robots on the Apptronik page.

Spec Breakdown

Detailed specifications for the Apollo 2

Battery Life

Swappable batteries designed for 7x22 operation; per-pack runtime not officially disclosed

With a battery life of Swappable batteries designed for 7x22 operation; per-pack runtime not officially disclosed, the Apollo 2 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.

The Apollo 2 uses Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development. 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.

Apollo 2 Sensor Suite

The Apollo 2 integrates 4 sensor types, forming the perceptual foundation that enables autonomous operation.

This sensor configuration enables the Apollo 2 to perceive its 3D environment, recognize objects and people, navigate complex spaces, and perform precise manipulation tasks. Multiple sensor modalities provide redundancy and more robust perception than any single sensor type alone.

Explore sensor technologies: components glossary · full components directory

Apollo 2 Use Cases & Applications

Humanoid robots are designed for environments built for humans — warehouses, factories, healthcare facilities, and eventually homes. Their bipedal form allows them to navigate stairs, doorways, and workspaces designed for human bodies without requiring environmental modifications.

Capabilities That Enable Real-World Use

The Apollo 2 offers 8 distinct capabilities, each contributing to the robot's practical utility.

Bipedal humanoid mobility
Wheeled-base humanoid mobility
Dexterous manipulation
Human-robot interaction with speech, listening, LED mouth, and chest display
Teleoperated and autonomous real-world data collection
Logistics and manufacturing task training
Retail and customer-site workflow training
Fleet monitoring and task orchestration

These capabilities work together with the robot's 4 onboard sensor types and Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development. AI platform to deliver practical, real-world performance.

Ecosystem Integration

The Apollo 2 integrates with the following platforms and ecosystems, extending its utility beyond standalone operation.

Apptronik Artemis Apptronik Fleet Connect Google DeepMind Gemini Robotics research collaboration

This ecosystem compatibility enables the Apollo 2 to work as part of a broader automation setup rather than operating in isolation.

Apollo 2 Capabilities

8

Capabilities

4

Sensor Types

AI

Apptronik Artemis coordinate…

Bipedal humanoid mobility
Wheeled-base humanoid mobility
Dexterous manipulation
Human-robot interaction with speech, listening, LED mouth, and chest display
Teleoperated and autonomous real-world data collection
Logistics and manufacturing task training
Retail and customer-site workflow training
Fleet monitoring and task orchestration

Connectivity & Integration

How the Apollo 2 communicates with your network, smart home devices, cloud services, and companion apps.

Network & Communication Protocols

Network protocols for device communication — enabling the Apollo 2 to participate in various networking scenarios.

Apollo 2 Technology Stack Overview

The Apollo 2 by Apptronik integrates 6 distinct technology components across sensing, connectivity, intelligence, and interaction layers.

Perception — 4 Sensor Types

The perception layer is built on Perception systems, Configurable perimeter-zone safety detection, Impact-zone safety detection, Status, battery, charging, and task-progress chest display. 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.

Connectivity — 1 Protocol

For communications, the Apollo 2 relies on Fleet Connect operations layer. This connectivity stack ensures the robot can communicate with cloud services, local smart home devices, mobile apps, and other networked systems in its environment.

Intelligence — Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development.

Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development. 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.

Who Should Consider the Apollo 2?

Target Audience

Humanoid robots are typically targeted at enterprise customers, research institutions, and forward-thinking businesses looking to automate tasks that require human-like form and dexterity. While some models are approaching consumer pricing, the majority remain in the commercial and industrial space.

Key Considerations

When evaluating a humanoid robot, payload capacity, degrees of freedom, and manipulation dexterity are critical factors. Battery life and charging time determine operational uptime. The AI platform determines how well the robot can adapt to new tasks and environments. Consider whether the robot needs to work alongside humans (requiring safety certifications) or will operate independently.

Pricing

Apollo 2 does not currently have publicly listed pricing. Contact Apptronik directly for quotes and availability information.

Availability

Active

The Apollo 2 is in active commercial production and currently sold by Apptronik. Check the manufacturer's website or authorized retailers for the latest stock and ordering information.

Apollo 2: Strengths & Trade-offs

Engineering compromises and where this humanoid robot excels

What the Apollo 2 does well

Solid sensor coverage

The Apollo 2 integrates 4 sensor types, providing good perceptual coverage for its intended applications. This sensor complement covers the essential modalities needed for effective humanoid operation while keeping complexity manageable.

Broad capability set

With 8 distinct capabilities, the Apollo 2 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.

What to consider carefully

Undisclosed pricing

Apptronik has not published a public price for the Apollo 2. 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 Apollo 2'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 Apptronik manufacturer page or visit the official product page. Use the comparison tool to evaluate these trade-offs against competing robots in the same category.

How Humanoid Robot Technology Works

Understanding the engineering behind this category

Humanoid robots represent one of the most technically ambitious categories in robotics. Building a machine that walks, balances, manipulates objects, and interacts naturally with humans requires breakthroughs across multiple engineering disciplines simultaneously. Understanding the technology behind humanoid robots helps buyers and enthusiasts appreciate both the capabilities and limitations of current systems.

Navigation & Mobility

Humanoid robots navigate using a combination of visual SLAM (Simultaneous Localization and Mapping), depth sensing, and inertial measurement. Unlike wheeled robots that simply avoid obstacles, humanoids must plan footstep placement, maintain dynamic balance on uneven surfaces, and anticipate terrain changes. Advanced systems use predictive models to plan several steps ahead, similar to how humans unconsciously adjust their gait when approaching stairs or rough ground. The computational requirements for real-time bipedal navigation are substantial, often requiring dedicated motion-planning processors separate from the main AI system.

The Role of AI

Artificial intelligence in humanoid robots serves multiple roles: high-level task planning (understanding what needs to be done), perception (recognizing objects, people, and environments), manipulation planning (figuring out how to grasp and move objects), and social interaction (understanding speech, gestures, and context). Modern humanoids increasingly use large language models and vision-language models for task understanding, allowing them to interpret natural language instructions and generalize to new tasks without explicit programming for each scenario.

Sensor Fusion & Perception

The sensor suite in a humanoid robot must provide comprehensive environmental awareness while maintaining real-time processing speeds. Sensor fusion algorithms combine data from cameras, LiDAR, depth sensors, force/torque sensors, and IMUs to create a unified model of the robot's surroundings. This multi-modal perception is critical because no single sensor type works perfectly in all conditions — cameras struggle in darkness, LiDAR cannot distinguish materials, and touch sensors only detect what the robot physically contacts. By combining these inputs, the robot achieves more robust and reliable perception than any individual sensor could provide.

Power & Battery Management

Battery technology is one of the primary limiting factors for humanoid robots. Bipedal locomotion is inherently energy-intensive — maintaining balance requires constant motor activity even when standing still. Current lithium-ion battery packs typically provide two to four hours of active operation, with charging times that can match or exceed operational time. Research into more efficient actuators, energy-harvesting techniques, and advanced battery chemistries aims to extend operational windows. Some commercial deployments address this limitation through battery-swap systems or scheduled charging rotations.

Safety by Design

Safety in humanoid robotics is paramount because these robots operate in close proximity to humans. Design approaches include compliant actuators that absorb impact forces, real-time collision prediction systems, force-limited joints that automatically reduce power when unexpected contact occurs, and emergency stop mechanisms accessible to nearby humans. International safety standards like ISO 13482 for personal care robots provide frameworks for evaluating safety, but the field is still developing standards specific to general-purpose humanoid systems. Buyers should inquire about safety testing, certifications, and the robot's behavior in failure modes.

What's Next for Humanoid Robots

The humanoid robotics field is advancing rapidly on multiple fronts. Improvements in foundation models are enabling more generalizable intelligence. New actuator designs are making robots lighter and more efficient. Manufacturing scale is driving down costs. Over the next several years, expect humanoid robots to transition from controlled industrial environments to more varied commercial and eventually residential settings. The convergence of better AI, cheaper hardware, and proven deployment experience will accelerate adoption across industries.

The Apollo 2 by Apptronik incorporates many of these technology pillars. For a detailed look at the specific sensors and components used in the Apollo 2, see the sensor analysis and connectivity sections above, or browse the complete components glossary for explanations of every technology used across the robotics industry.

Apollo 2 in the Humanoid Market

How this robot compares in the humanoid landscape

Apptronik has not publicly disclosed pricing for the Apollo 2, which is typical for enterprise-focused robotics platforms that offer customized solutions and direct-sales relationships.

The Apollo 2's 4 sensor types provide solid perceptual coverage for its intended use cases. This mid-range sensor suite balances cost with capability, covering the essential modalities needed for humanoid applications.

Being currently available for purchase gives the Apollo 2 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.

Head-to-Head Comparisons

Side-by-side specs, capability overlap analysis, and key differentiators.

For the full picture of Apptronik's portfolio and market strategy, visit the Apptronik manufacturer page.

Deployment Readiness and Procurement Signals for Apollo 2

What the public profile tells you, and what still needs direct vendor confirmation

From a buying and rollout perspective, the Apollo 2 should be read as a humanoid platform aimed at human-scale workplaces and pilot automation programs. ui44 currently tracks 8 capability signals, 4 sensor inputs, and a last verification date of 2026-07-04. 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 Apptronik.

Commercial model

Quote-based sales

No public pricing or general commercial sale terms announced; Apollo 2 is active in Apptronik Robot Park and customer/partner data-collection deployments.. That usually means the final commercial package depends on deployment scope, services, or negotiated terms.

Integration posture

1 connectivity option

The profile lists Fleet Connect operations layer, plus Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development. 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 3 declared compatibility links.

Spec disclosure

0/7 core specs public

ui44 currently has 0 of 7 core physical and operating specs filled in for this model, leaving 7 gaps that matter for deployment planning. Missing runtime, charge, speed, or payload details can materially change staffing and site-readiness assumptions.

The current profile is useful for scouting, but it still leaves meaningful operational unknowns. If this robot is heading toward a pilot or purchase discussion, the next step should be a structured vendor Q&A that fills the remaining runtime, charging, payload, safety, or integration blanks before anyone builds ROI assumptions around it.

If you want a faster apples-to-apples read, compare the Apollo 2 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 Apptronik profile helps anchor this robot inside the wider product lineup.

Before you sign off on a pilot, confirm these points

  • Ask for real shift runtime under the intended workload, not just standby endurance.
  • Confirm how the charging workflow works in practice, including charger count, swap options, and expected downtime.
  • Verify travel speed and cycle time if the robot must keep up with people, lines, or service windows.
  • Clarify usable payload or tool-load limits before planning material handling or mounted accessories.

Owning the Apollo 2: Setup, Maintenance & Tips

Practical guide from day one through years of ownership

Initial Setup

Setting up a humanoid robot is substantially more involved than plug-and-play consumer devices. Expect a professional installation or guided setup process that includes physical unpacking and assembly (if shipped disassembled), initial calibration of joints and sensors, environment mapping and safety zone definition, network and cloud service configuration, and application-specific programming or task teaching. Plan for several hours to a full day of setup time, and budget for potential integration consulting if the robot needs to connect with existing systems. The manufacturer or a certified integrator should provide training on safe operation, emergency procedures, and basic troubleshooting.

Ongoing Maintenance

Humanoid robots require regular maintenance to ensure safe and reliable operation. Monthly maintenance typically includes visual inspection of joints and actuators for wear, sensor cleaning (especially cameras and LiDAR), firmware and software updates, battery health checks, and calibration verification. Quarterly maintenance may include more thorough mechanical inspection, lubrication of moving parts, and performance benchmarking to detect gradual degradation. Keep a maintenance log and follow the manufacturer's recommended schedule precisely — humanoid robots are complex systems where small issues can cascade if not addressed promptly.

Software Updates & Long-Term Support

Humanoid robot software is evolving rapidly, and regular updates can significantly improve performance, add new capabilities, and patch security vulnerabilities. Most manufacturers provide over-the-air updates, but enterprise deployments may require staging and testing updates before rolling them out. Evaluate the manufacturer's update track record — frequent, well-documented updates indicate active development and long-term commitment. Be aware that major software updates may require recalibration or retraining of custom behaviors.

Maximizing Longevity

To maximize the useful life of a humanoid robot, avoid operating beyond specified payload limits, maintain a controlled environment (temperature, humidity), keep sensors clean and unobstructed, and address any unusual sounds or behaviors promptly. Battery longevity is improved by avoiding deep discharges and extreme temperatures during charging. Investing in a service contract with the manufacturer or a certified partner provides access to replacement parts and expertise that can extend the robot's productive life significantly beyond the standard warranty period.

For Apptronik-specific support resources and documentation, visit the Apptronik page on ui44 or check the manufacturer's official website at Apptronik's product page.

Frequently Asked Questions

What is the Apollo 2?
The Apollo 2 is a Humanoid robot made by Apptronik. Apollo 2 is Apptronik's current-generation humanoid platform, unveiled with its expanded Robot Park data-collection facility in Austin. The platform is offered in both bipedal and wheeled-base configurations so Apptronik can train and deploy the same core humanoid technology across logistics, manufacturing, retail, and other real-world work environments. Official materials describe Apollo 2 as the Robot Park workhorse for more than a year, with fleets already operating at Apptronik facilities and customer or partner sites, while data from teleoperation and autonomous execution supports Apptronik's Google DeepMind collaboration on Gemini Robotics models and the future Apollo 3 commercial fleet. It features 4 sensor types, 1 connectivity protocols, and 8 distinct capabilities.
How much does the Apollo 2 cost?
Apptronik has not disclosed public pricing for the Apollo 2. Contact the manufacturer directly for pricing information. No public pricing or general commercial sale terms announced; Apollo 2 is active in Apptronik Robot Park and customer/partner data-collection deployments.
Is the Apollo 2 available to buy?
Yes, the Apollo 2 is in active commercial production and currently sold by Apptronik. Check Apptronik's official website or authorized retailers for the latest stock and ordering options.
What sensors does the Apollo 2 have?
The Apollo 2 is equipped with 4 sensor types: Perception systems, Configurable perimeter-zone safety detection, Impact-zone safety detection, Status, battery, charging, and task-progress chest display. These sensors work together through sensor fusion to provide comprehensive environmental awareness for autonomous operation. See the sensor analysis section for details.
How long does the Apollo 2 battery last?
The Apollo 2 has a rated battery life of Swappable batteries designed for 7x22 operation; per-pack runtime not officially disclosed. Actual battery performance may vary based on usage intensity, ambient temperature, and specific tasks being performed. Heavy workloads like continuous navigation and sensor processing will consume battery faster than idle or standby modes.
What AI does the Apollo 2 use?
The Apollo 2 is powered by Apptronik Artemis coordinates perception, planning, controls, safety, task execution, and human-robot interaction; Robot Park data supports Google DeepMind Gemini Robotics model development.. This AI platform handles the robot's perception processing, decision-making, and autonomous behavior. The sophistication of the AI directly impacts how well the robot handles unexpected situations, learns from its environment, and improves over time.
How does the Apollo 2 compare to the Apollo?
The Apollo 2 and Apollo are both humanoid robots, but they differ in key specifications, pricing, and manufacturer approach. Use the side-by-side comparison tool to see detailed differences in specs, sensors, and capabilities. You can also browse other similar robots below.
Does the Apollo 2 work with smart home systems?
Yes, the Apollo 2 is compatible with: Apptronik Artemis, Apptronik Fleet Connect, Google DeepMind Gemini Robotics research collaboration. This ecosystem integration allows the robot to work alongside your existing smart home devices and platforms rather than operating as an isolated system.
How current is the Apollo 2 data on ui44?
The Apollo 2 specifications on ui44 were last verified on 2026-07-04. All data is sourced from official Apptronik documentation, spec sheets, and press releases. If you notice any outdated information, please let us know.

Data Integrity

All Apollo 2 data on ui44 is verified against official Apptronik sources, including spec sheets, product pages, and press releases. Last verified: 2026-07-04. Official source: Apptronik product page. If you find outdated or incorrect information, please let us know — accuracy is our top priority.

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