Thank you for tuning in to week 214 of the Lindahl Letter publication. A new edition arrives every Friday. This week the topic under consideration for the Lindahl Letter is, “The great manufacturing reset.”
Boston Dynamics captured public imagination when they introduced Spot the dog-like robot back in 2016. Things have changed. Robots that walk around are beginning to enter the commercial landscape, and new entrants continue to appear. A humanoid robot product from Russia built by the company Idol surfaced last week [1]. Other companies such as Agility Robotics (USA), Figure AI (USA), Boston Dynamics (USA), UBTECH (China), and 1X Technologies (Norway/USA) are all working toward delivering humanoid robots. Optimus, the Tesla bot introduced conceptually in 2021 and now in its third-generation prototype which remains part of an internal program and has not yet reached commercial deployment is also being talked about.
The stage is now set, and we are at a point where robotics, autonomous fabrication systems, and advanced materials are converging into a new industrial baseline. The last decade brought low-cost filament printers into hobbyist and commercial spaces at massive scale, and the next decade is poised to move far beyond that early wave. Industrial additive manufacturing has already expanded into metals, composites, and high-performance polymers, with global revenue expected to accelerate over the coming years. At the same time, the field is absorbing rapid advancements in AI-enabled calibration, defect detection, and real-time optimization, allowing machinery to tune production parameters autonomously. That capability shifts what it means to operate a modern fabrication workflow. Things are changing rapidly.
Alongside these developments, humanoid and semi-autonomous industrial robots are transitioning from research demonstrations to contract manufacturing deployments. Several builders are scaling up pilot programs in which general-purpose robots support assembly, materials handling, and repetitive manufacturing tasks. These systems benefit from advances in reinforcement learning, enhanced sensors, and cloud-based model updates. Industrial robotics shipments are increasing rapidly, driven by global demand for flexible production lines and labor-augmentation strategies. The supply side of robotics is not only expanding but also becoming modular and more interoperable across fabrication environments.
The most significant shift may come from the emergence of machines that build machines. That is a topic I’m focused on understanding. Historically, tooling design required long lead times, significant manual labor, and specialized expertise. Today, automated CAM pipelines, printable tooling, adaptive CNC systems, and robotically tended fabrication cells allow factories to generate and regenerate their own production processes. Some aerospace and automotive facilities already deploy these closed-loop systems to create fixtures, jigs, and replacement components internally. This form of self-manufacturing reduces dependency on external suppliers and removes friction from engineering iteration cycles. We are moving toward a world where design, testing, and tooling are all integrated within an AI-guided, robotics-driven feedback loop. That integration is the foundation of the great manufacturing reset.
For the United States, these technologies open a realistic path to reshoring custom and small-batch manufacturing in ways that were not economically viable during the offshoring wave of the late twentieth century. Rising labor costs in traditional manufacturing hubs, geopolitical risk, and supply chain disruptions have already encouraged firms to reconsider where they build things. Additive manufacturing and flexible robotics change the cost structure by reducing reliance on large minimum-order quantities, expensive hard tooling, and long logistics chains. A factory that can print tooling on demand, deploy modular robots, and run AI-optimized production scheduling can serve shorter runs and more specialized designs while remaining geographically close to end customers. In effect, the United States can replace scale-driven arbitrage with speed, customization, and resilience. That is why we are at the inflection point for the great manufacturing reset.
Policy and infrastructure are beginning to support this transition. Federal programs such as Manufacturing USA and its associated network of advanced manufacturing institutes are working to diffuse next-generation production technologies across domestic firms and regions [2]. Investments in semiconductor fabrication, battery plants, and clean-energy hardware have already catalyzed billions of dollars in new onshore manufacturing commitments. The same capabilities that support large facilities can extend to mid-market and smaller manufacturers through shared tooling libraries, regional robotics integrators, and standardized digital design pipelines. Universities and community colleges can align curricula with this reset by emphasizing mechatronics, robotics programming, and design-for-additive principles that translate directly to a modern factory floor.
If the United States leans into this transition, the great manufacturing reset will not simply re-create legacy industrial capacity. It will establish a distributed network of automated, digitally coordinated micro-factories specializing in custom work, rapid prototyping, and short-run production. The strategic advantage will be the ability to move from concept to physical part in days instead of months, while retaining critical capabilities within domestic borders. The risk is that other regions may scale faster and capture the integrator role that coordinates robots, additive systems, and AI platforms across global supply chains. The next few years will determine whether the United States treats these technologies as incremental enhancements or as foundational infrastructure for a new manufacturing baseline. Ideally, this reset will create conditions for a new wave of startups delivering smaller manufacturing runs, bespoke development cycles, and entirely new product categories.
Things to consider:
The economics of reshoring depend as much on automation and design speed as on wage differentials.
Policy support for advanced manufacturing will matter most where it connects directly to tooling, robotics, and workforce upskilling.
Custom, short-run production could become a core competitive advantage for regions that adopt additive and robotics early.
The integrators that connect robots, printers, and AI software may end up more powerful than any single hardware vendor.
Manufacturing resilience will increasingly be measured by how quickly domestic systems can reconfigure to new designs and shocks.
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Links I’m sharing this week!
Footnotes:
[1] Mesa, J. (2025, November 11). Russia ‘human’ robot falls on stage during debut. Newsweek. https://www.newsweek.com/russia-human-robot-falls-stage-during-debut-11031104
[2] Manufacturing USA. (n.d.). Home. https://www.manufacturingusa.com/
