Humanoid robots are having a moment—from viral videos to billion-dollar valuations. The reality behind the headlines is more complex. While demonstrations dazzle, most deployments remain early-stage, with heavy reliance on human supervision.

These robots, typically bipedal with dexterous movement, advanced sensing and vision, and AI-powered reasoning, drew about $2.5 billion in venture capital investment in 2024. Expectations for their deployment are partly driven by demand: Demographic changes in some advanced economies could lead to labor shortages as working-age populations decline by up to 25%. (For more on the underlying economics, read the Bain Brief “Humanoid Robots at Work: What Executives Need to Know.”)

Humanoids, along with other types of robots (industrial, mobile, collaborative with humans), are part of an expanding automation toolkit to address workforce gaps and productivity challenges. For executives navigating automation strategies, understanding the real technology trajectory is critical. Companies making investment decisions need to understand which capabilities are advancing fastest, and what realistic adoption timelines look like across industries.

Reality check: Humanoid robots aren’t ready for prime time yet

Most humanoid robots today remain in pilot phases, heavily dependent on human input for navigation, dexterity, or task switching. This “autonomy gap” is real: Current demos often mask technical constraints through staged environments or remote supervision. Lessons from the autonomous vehicle sector suggest a phased approach: safe environments first, building trust through performance, then scaled deployment.

Controlled environments such as industrial, portions of retail, and select service environments are likely to be where humanoid robots are deployed first—places where the layout and environment are well known and closely controlled, and where tasks are likely to fall within a limited subset. More variable environments with greater potential for direct human interaction, such as homes, cities, or the outdoors, will take longer, especially given the capability advances that will be needed for true autonomy in unconstrained settings. 

Four capabilities will determine progress

Today, core technologies in humanoid robotics remain below human capabilities. Intelligence and perception, however, are advancing rapidly and are likely to be the first to reach human-level performance (see Figure 1).

• Intelligence: Generative AI is advancing rapidly, enabling high-level reasoning, planning, and spatial awareness. These capabilities are likely to surpass human performance in many tasks within the next two to three years. In physical work settings, specialized knowledge is often needed, raising the bar on what data the robots must be trained on and what situations they must be able to think through.
  
  
• Perception: Sensors, especially vision, are at a similar stage to generative AI, catching up with human capabilities powered by advances across LiDAR and other technologies. However, vision sensors still lag the human eye in dynamic range—particularly in low-light conditions—and in identifying reflective or transparent objects, such as shiny surfaces and clear plastics.
  
  
• Handling: Despite advances, dexterity and fine-motor control are still in relatively earlier stages, with real gaps in tactile sensitivity and precision. But not all jobs require human-level dexterity. Tasks such as warehouse sorting or tray delivery can be executed with current levels of mechanical reach and grip. Tasks such as precision manufacturing or lab work will require further advances and potentially significantly higher cost to be addressable.
    
• Power: Battery performance is improving, but slowly. Most humanoids today operate for only about two hours. Achieving a full eight-hour shift without recharging could take up to 10 years or even longer, as energy density improves and costs decline (see Figure 2). Until then, operators will need to rely on operational innovations such as swappable batteries and fast charging, or limit operations to environments where robots can remain continuously plugged in.

Managing expectations: Where humanoids will deploy first

The most promising short-term value for humanoids lies not in general-purpose humanoids, but in hybrids that combine human-like perception with wheeled or static platforms or limited dexterity. For example, some companies are developing humanoids with a two-arm torso on a wheeled base to perform warehouse logistics.  

In the next three years, the first commercial applications will come from semi-structured tasks such as tote picking, palletizing, or line feeding inside durable goods factories, warehouses, and even transportation settings, where humanoids can take advantage of existing automation infrastructure and workflows. Early deployments will remain in closed environments where traffic is limited and predictable. While industrial robots are already common in these sectors, there remain many areas where automation is still limited, often due to variability or cost, making them prime opportunities for humanoid deployment (see Figure 3).

In five years, improved dexterity and battery modules will likely support robots’ move into semi-structured service settings, where they’ll perform tasks such as cleaning and preparing hotel rooms, hauling laundry, running hospital supplies, or shuttling hazardous materials. Jobs requiring eight-hour shifts will likely be enabled with modular battery “hot swaps” or fast charging. Safety will remain paramount, and use cases will expand into “open,” guest-facing areas only as certification and human-acceptance thresholds are met. 

Within the next decade, we expect physical intelligence—the ability of autonomous systems such as robots, self-driving cars, and smart spaces to perceive, understand, and act in the real world—to reach cross-domain capabilities. Once that happens, and battery power can support a full shift without intervention, real open-ended use cases will start to emerge in applications as diverse as elder-care assistance, light construction, or materials handling in mining and other remote environments.

In short, capabilities will unfold in waves: industrial workflows in controlled environments first, variable service environments next, and finally the messy, open real world, once dexterity and energy density catch up.

Technological readiness is only a part of the story. Turning capability into commercial traction will also require clear regulatory pathways, rigorous safety and certification regimes, workforce acceptance, and perhaps most important, public trust in machines that look and move like us. Progress on those fronts will ultimately determine how quickly humanoid robots shift from headline grabbers to everyday coworkers.

Strategic moves in the humanoid robot ecosystem

Humanoid robots are still in the early stages of development and trial, and the actions that matter most vary depending on where companies play in the emerging and potentially disruptive value chain.

• Technology providers. Identify key control points (e.g., AI, software stack, semiconductors, vision), differentiate offerings, and pilot vertical solutions to gather the industry learnings and data needed to build out physical intelligence. Evaluate monetization strategies, assess operational implications (e.g., over-the-air upgrades and safety certifications), and engage with regulatory bodies.
  
  
• Equipment and component manufacturers (motors, batteries, gearboxes, materials). Innovate and scale batteries, build mechatronics (e.g., motors, tactile sensors, and actuators) that meet humanoid specs and safety requirements, codevelop with original equipment manufacturers (OEMs), and focus on design wins. Support multiple modalities (e.g., high dexterity through limited dexterity). Prioritize lighter and advanced materials to improve efficiency, performance, and safety.
  
  
• Humanoid robot integrators. Define resilient sourcing strategies across mechatronics and technology to navigate the fast-evolving landscape. Combine robots, AI, fleet management, and workflow redesign into turnkey offerings and solutions. Develop a hybrid strategy and industry‑specific playbooks, service contracts, change management approaches, and safety certification pathways to accelerate customer uptake. Establish an operating ecosystem for early adopters, covering spares, services, battery swap infrastructure, and ongoing maintenance to reduce deployment risk and ensure uptime.
  
  
• Humanoid robot adopters. Identify addressable workflows (e.g., tote handling, palletizing, line feeding) and assess where humanoid and non-humanoid automation could generate value across tasks and geos. Run pilots to evaluate potential ROI, data readiness, and technical hurdles, and begin training the workforce. Upgrade IT/OT capabilities, invest in data infrastructure and safety standards, and mobilize broader automation adoption as familiarity with humanoid capabilities grows.

Preparing for the commercial rise of humanoid robots

Humanoid robots will not replace broad swaths of labor overnight, but they will arrive in waves and deliver clear commercial value as part of a broader automation journey across enterprises. Executives who start learning early, identify opportunities across specific tasks, and develop a solid understanding of technology, data, and safety readiness will be well positioned to capture value as soon as the hardware is ready to walk through the door.