According to several industry estimates, the global humanoid robot market could reach between $30 billion and $60 billion by 2035, with annual growth exceeding 35%. Yet today, less than 1% of industrial companies use humanoids in real production environments. The gap between potential and adoption is telling.

From Technical Demonstration to Industrial Reality

Recent advances in robotics, driven by artificial intelligence and imitation learning, have made it possible to cross a major threshold. In 2025, several prototypes capable of performing picking or assembly tasks were unveiled. In 2026, some manufacturers are announcing tests involving fleets of 10 to 100 robots in controlled environments.

But those figures remain marginal. For comparison, a single automotive plant can deploy more than 1,000 traditional industrial robots.

The transition toward mass adoption involves challenges of a completely different nature:

• System standardization
• Large-scale maintenance
• Software interoperability
• Total cost of ownership (TCO)

Today, the cost of a humanoid robot still ranges between $50,000 and $150,000, which significantly limits large-scale deployment.

The real challenge is no longer
making a robot walk, but making
it work at scale.

We are no longer selling machines,
but ecosystems where hardware is
only the visible part of the data layer.

A Redefinition of the Robotics Model

The traditional robotics framework is evolving toward a systemic approach. In 2026, the most advanced players are no longer selling robots alone, but complete solutions integrating:

• Hardware
• Software
• Infrastructure
• Services
• Data

There is a clear convergence with SaaS models, where value shifts toward operations and data management.

Humanoid robotics is entering a new phase. After the era of technological innovation (2015–2025), the decade 2025–2035 will be defined by large-scale deployment.

The bottleneck has shifted toward infrastructure, regulation, and market integration. The companies that will dominate this market will not simply be those designing the most advanced robots, but those capable of deploying them at scale in real-world environments.

The next revolution will not be technological. It will be operational.

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In 2026, this silent war has taken a turn that the industrial press has not yet clearly named. Beckhoff closed 2025 with €1.24 billion in revenue, up 6% in a contracting market. At the same time, Rockwell Automation was cutting 900 jobs, lowering its forecasts, and promising that the “tailwinds from AI” would become visible “quarter by quarter.” Schneider Electric, meanwhile, was quietly reinventing its control architecture with an announcement that went under many people’s radar: the industry’s first software-defined DCS, Foxboro SDA, launched in February 2026.

This is not a story about brands fighting each other. It is a story about architectures, and about a fundamental question that industry is putting back on the table: a dedicated controller on a proprietary backplane, or an open industrial PC that runs everything at once?

The proprietary architecture: why it worked so well for so long

To understand what is happening today, we need to understand what worked yesterday.

Rockwell Automation and its Allen-Bradley systems have built one of the strongest installed bases in industrial history, particularly in North America. ControlLogix is robust, reliable, well documented, and mastered by thousands of integrators and maintenance technicians. In large chemical, pharmaceutical and automotive plants, a Rockwell controller is often a non-negotiable requirement from the project owner, not a choice made by the integrator.

The strength of this installed base is real and lasting. Nobody replaces a healthy ControlLogix network just for the pleasure of adopting a more elegant architecture. The cost of migration, in time, training and operational risk, is prohibitive. Rockwell knows this, and this is precisely the rent on which it has built its profitability for the past two decades.

Schneider Electric has followed a similar logic, with one specific difference: a dual foothold in discrete and process industries, in Europe and emerging markets. Its Modicon catalogue for discrete automation, and Foxboro and Triconex for process and safety, give it a presence in sectors that Rockwell has never truly penetrated: petrochemicals, water treatment and energy infrastructure. It also has a distinctive position in energy efficiency, which has been part of its DNA long before it became a regulatory obligation.

Automation is no longer a
hardware choice, it is a
20-year strategy.

In Industry 4.0, software is
the new master of the
forge.

The real question: who specifies new lines in 2026?

The heart of the debate is not technical. It is demographic and economic.

A seasoned industrial analyst put it bluntly in a specialist newsletter that circulated in May 2026: the engineers who specified Allen-Bradley in 2002 and 2010 are retiring. Those specifying new lines in 2026 are in their thirties. Their first contact with PLC programming was not a classroom course in a panel shop, but an open-source simulator on a laptop. They have a natural affinity for open environments, modern IDEs and architectures that feel like software development.

No marketing budget can compensate for a generational shift. Rockwell has an extremely loyal installed base, but its share of new greenfield lines has already been moving unfavorably for several years.

This does not mean Rockwell will collapse in the short term. Maintenance of the installed base, renewals, brownfield projects in plants with 20 years of ControlLogix behind them all of this represents a solid foundation for another 10 to 15 years. But the trajectory on new installations is concerning, and Rockwell’s product response FactoryTalk Optix as a visualization and connectivity layer does not change the underlying architecture. It is a surface adaptation on a proprietary foundation that has not fundamentally evolved.

Where each player still wins, and where each is losing ground

Rockwell remains essential in North American brownfield environments. Large plants with 20 years of ControlLogix will not change architecture over the next decade, whatever the competitive pressure. Sectors with strong regulatory inertia, such as chemicals, high-risk process industries and functional safety, also remain favorable ground. The depth of the Allen-Bradley integrator network in North America is an advantage Beckhoff has not yet reproduced at that scale.

Schneider Electric holds its ground in global process industries. Foxboro and Triconex are references in petrochemicals and functional safety. The Foxboro SDA announcement strengthens this position by adding a modernization layer that did not previously exist. In terms of energy efficiency, an increasingly decisive criterion in industrial specifications, Schneider has a positioning that its competitors have not managed to replicate as completely.

Beckhoff is winning in greenfield discrete automation, motion-intensive systems and vision-integrated machines. Machine builders selling in Europe and Asia on the same specifications one runtime, rationalized SKUs, a coherent architecture have a clear economic argument for TwinCAT and EtherCAT. And the fact that AI can be integrated natively into the runtime, without third-party infrastructure, is starting to weigh in comparisons.

What this battle says about automation in 2026

The “war of architectures” is not a trade-show headline. It is an industrial reality playing out today in every new greenfield project, every machine-builder specification and every runtime choice inside an engineering office.

What is being decided is whether the controller of the future looks like a specialized electronic device, proprietary by nature, or like an open industrial computer capable of hosting any function the machine requires, including AI models directly in the control loop.

The history of computing has already answered this question once, in the 1990s, when proprietary servers gave way to x86 architecture servers. It would be reckless to claim that automation will follow exactly the same path. Real-time constraints, functional safety and industrial reliability are different. But the direction of travel is readable.

Rockwell, Schneider and Beckhoff are each responding in their own way. None of the three will disappear over the next 10 years. But in 10 years’ time, the order of the podium for new installations will probably not look the same as it does today.

Robot Magazine follows developments in the industrial automation market. Are you an integrator, machine builder or technical manager? Your field experience is the most valuable source. Share it in the comments.

Author: Christophe Carl Louis
Content enriched with artificial intelligence tools.

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Safety as an Industrial Foundation

European industry has been built around a core principle: machines must adapt to humans not the other way around.

Standards promoted in particular by the International Organization for Standardization (ISO) have enabled the rise of collaborative robots, secure cells, and advanced control systems.

The results:

• Stronger social acceptance

• Reduced legal risks

• Better integration into existing industrial sites

In robotics, Europe has made a
strategic choice: prioritizing safety
and trust over speed at all costs.

European Regulation: A Barrier… That Protects

European regulation acts as a quality filter. It imposes high requirements in terms of functional safety, liability, and traceability.

In the short term, this can slow down certain deployments. In the long term, it creates a structural advantage for players capable of complying with these standards.

European industrial companies know that a solution certified today will be exportable tomorrow, without major regulatory reassessment.

In Europe, for example, CE marking forms the regulatory foundation for placing any robot on the market whether industrial, collaborative, or humanoid. It certifies that the manufacturer has carried out a comprehensive risk assessment, that the machine meets essential requirements for safety, health, and personal protection, and that it complies with harmonized European standards.

With the entry into force of the EU Machinery Regulation 2023/1230, the CE framework is evolving to better integrate autonomous robots, connected systems, and embedded AI, strengthening requirements related to functional safety, cybersecurity, and traceability. In a context of growing robot deployment in open environments, CE marking is becoming a key factor of trust and industrial acceptability far beyond a simple administrative obligation.

What the United States and China Can Learn

The United States excels in innovation speed and software scalability.
China masters industrial capacity, cost reduction, and rapid scaling.

However, both models are now facing limitations:

• Social acceptability

• Liability in the event of incidents

• Deployment in sensitive environments

The European model offers a complementary answer: trust as an industrial asset.

The next robotics revolution will
not be purely technological it will
be regulatory and societal.

Towards a Convergence of Models

Rather than competing approaches, global robotics may evolve toward cooperation between models:

• The United States brings software innovation and AI

• China brings industrial capacity and speed

• Europe brings standards, safety, and governance

This convergence is essential to deploy robotic systems at scale in complex and highly regulated environments.

Robotics is entering a phase of maturity. In this context, trust is becoming as strategic as performance. By placing standards, safety, and regulation at the heart of its approach, Europe is not slowing the market it is preparing its global sustainability. The United States and China would be well advised to draw inspiration from this model and build alongside it.

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