Level 1 — Absolute Beginner
Japan Airlines is a big airline in Japan. They fly planes to many places in the world. Now they are using robots to help at the airport.
The airport is called Haneda. It is in Tokyo, Japan. The robots look like people. They are called humanoid robots.
The robots will carry bags and clean planes. This is hard work that people usually do. Japan does not have enough workers. The robots can help.
The robots will work at the airport for two years. Japan Airlines thinks robots will be very useful in the future.
- airline
- a company that flies passengers and cargo in planes
- robot
- a machine that can move and do tasks automatically
- humanoid
- looking or moving like a human being
- airport
- a place where planes take off and land
- baggage
- suitcases and bags that passengers carry on a trip
- labor shortage
- when there are not enough workers to do all the jobs available
- trial
- a test to see if something works well
- deploy
- to put something into use in a specific place
Level 2 — Elementary
Japan Airlines, also known as JAL, has started testing humanoid robots for ground operations at Tokyo's Haneda Airport in May 2026. The airline is partnering with GMO AI and Robotics to run a two-year trial. The goal is to achieve full commercial use of the robots within three years.
The robots are based on models made by Unitree Robotics, a company from Hangzhou, China. They are 132 centimeters tall and weigh 35 kilograms. They can move like humans with 23 to 43 degrees of freedom. Their top speed is 7.2 kilometers per hour. However, they can only work for two to three hours before their battery needs charging.
Japan is experiencing a serious labor shortage because of its aging population. The country has fewer young workers each year. Haneda Airport serves more than 60 million passengers every year, making efficient ground operations very important. The robots can help fill the gap left by retiring workers.
The program will begin by studying airport workflows to find the safest places for robots to work. After simulations, the robots will begin real-world testing alongside human workers. Japan Airlines hopes this project will serve as a model for other airlines around the world.
- ground operations
- tasks performed at an airport on the ground, such as loading baggage and cleaning aircraft
- degrees of freedom
- the number of different directions a machine joint can move, more means more flexible movement
- simulation
- a computer model or rehearsal that copies real-world conditions for testing
- aging population
- a demographic trend where the average age of a population increases over time
- workflow
- the sequence of tasks needed to complete a process or job
- commercialization
- the process of turning a new technology or product into a profitable business
- capacity
- the maximum amount a place or system can handle
- ramp
- the outdoor area at an airport where planes park to load and unload passengers and cargo
Level 3 — Intermediate
Japan Airlines launched a two-year trial of humanoid robots for ground operations at Tokyo's Haneda Airport in May 2026, making it one of the first major commercial airlines to commit to an operational humanoid deployment in a demanding aviation environment. The airline is partnering with GMO AI and Robotics in a pilot program aimed at achieving commercialization within three years.
The robots are based on the Unitree Robotics platform, developed in Hangzhou, China. They stand 132 centimeters tall, weigh 35 kilograms, and are equipped with 23 to 43 degrees of freedom, enabling human-like movement in tight operational spaces such as cargo holds and aircraft cabins. Their top speed is 7.2 kilometers per hour, though battery life is a current constraint, with each unit operating for only two to three hours per charge cycle. GMO AI and Robotics is developing proprietary battery-swapping infrastructure to address this limitation.
Japan's aviation sector is under severe labor pressure. The country's working-age population is projected to shrink by roughly 10 million over the next decade due to demographic decline and historically low immigration rates. Haneda Airport, which handles over 60 million passengers annually and ranks among the five busiest airports globally, faces growing gaps in its ramp and cabin-cleaning workforce despite offering above-market wages.
The program begins with a careful analysis of airport workflows to identify where robots can operate safely alongside humans, followed by simulation trials before live testing. Japan's position as both a leader in robotics research and a strictly safety-conscious aviation regulator makes it a compelling test environment. A successful two-year pilot at Haneda would constitute powerful evidence for the commercial viability of bipedal robots in high-stakes infrastructure settings.
- bipedal
- having two legs; in robotics, describing a robot that walks on two legs like a human
- demographic decline
- a decrease in population size, often due to low birth rates and aging
- proprietary
- owned exclusively by a company; not available to competitors
- constraint
- a limitation or restriction that affects what is possible
- commercial viability
- the ability of a product or technology to generate profit and succeed in the market
- infrastructure
- the basic physical systems of an organization or country, such as airports, roads, and power grids
- ramp agent
- an airport worker who handles baggage, fueling, and aircraft positioning on the tarmac
- autonomous
- able to operate independently without human control
Level 4 — Advanced
Japan Airlines has launched what industry analysts describe as the most consequential humanoid-robot deployment in civil aviation to date, installing Unitree Robotics-based machines in live ramp and cabin-cleaning workflows at Haneda Airport under a two-year agreement with GMO AI and Robotics commencing in May 2026. The initiative is structurally distinct from prior airport-robot pilots -- autonomous tug vehicles, bag-drop kiosks, and wayfinding units -- in that it involves a bipedal, general-purpose platform designed to execute the same physical manipulation tasks as a human ground-handling agent in unstructured environments.
The Unitree-derived units are 132 cm tall, weigh 35 kg, and offer 23-43 degrees of freedom enabling manipulation in environments such as cargo holds whose floor geometries vary aircraft-to-aircraft. Operational speed tops at 7.2 km/h. The principal constraint is duty cycle: a two-to-three hour battery life per charge mandates fleet-rotation scheduling that increases the footprint required for any given operational throughput. GMO AI and Robotics is developing proprietary battery-swapping infrastructure to mitigate this, analogous to the rack-exchange system Tesla developed for its semi-truck fleet.
The structural impetus for the program is a macroeconomic imperative with no near-term market solution. Japan's working-age population is projected to contract by approximately 10 million over the coming decade -- a compression that the Ministry of Land, Infrastructure, Transport and Tourism has identified as a primary constraint on aviation sector expansion. Haneda, which handles 60+ million passengers annually and ranks among the five busiest airports globally by passenger throughput, has already raised ramp-agent wages materially above the sector median and still faces unfilled vacancies across baggage-handling, aircraft servicing, and cabin-cleaning functions.
The three-year commercialization target is ambitious relative to comparable deployment timelines. Boston Dynamics' Stretch logistics robot took six years from prototype demonstration to volume commercial rollout. The JAL-GMO program benefits from a more forgiving regulatory posture -- the Civil Aviation Bureau's framework for humanoid airport robots is still being drafted -- but will encounter non-trivial Foreign Object Debris protocols, proximity-alert requirements for fueling operations, and RFID interference constraints that warehouse environments do not impose. If the Haneda pilot achieves the utilization metrics necessary to underwrite a 2028 commercialization announcement, it will represent the most persuasive proof-of-value for bipedal industrial robotics yet documented in a real-world, safety-critical infrastructure setting.
- unstructured environment
- a physical space without fixed, predictable layouts, requiring adaptive problem-solving
- duty cycle
- the proportion of time a machine is operational versus idle or charging
- fleet-rotation scheduling
