Beyond VR: How Spatial Computing Turns Tribal Knowledge Into Digital Workforce Intelligence

Why industrial training simulators are becoming safer, smarter, and more scalable ways to prepare workers for complex equipment, hazardous environments, and mission-critical procedures.

Beyond VR: How Spatial Computing Training Turns Tribal Knowledge into Digital Workforce Intelligence

Industrial training is facing a new kind of pressure.

Experienced operators are retiring. Younger workers are entering the field with different expectations for how they learn. Equipment is becoming more complex. Safety expectations are increasing. And many organizations are being asked to do more with fewer highly experienced people available to train the next generation.

This is not just a staffing issue. It is a knowledge-transfer issue.

For decades, many industrial organizations have relied on a combination of classroom instruction, manuals, shadowing, and on-the-job learning. Those methods still matter, but they are not always enough for today’s equipment, procedures, and workforce challenges. A new operator may need to understand machine controls, jobsite awareness, equipment inspection, emergency procedures, team coordination, and the consequences of small mistakes — often before they have meaningful access to the real equipment.

That is where spatial computing-based simulation training becomes valuable.

Spatial computing is often associated with VR headsets, AR glasses, and mixed-reality devices. But the real value is not the headset. The real value is the ability to turn physical equipment, operational procedures, jobsite environments, safety risks, and expert decision-making into interactive 3D training systems.

For industrial organizations, this means workers can practice before they perform. They can make mistakes without damaging equipment, interrupting operations, or putting themselves and others at risk. They can repeat difficult procedures until they build confidence. And trainers can measure not just whether someone completed a course, but how they actually performed.

Lower Costs and Less Downtime

That shift, from passive instruction to measurable practice, is why spatial computing is becoming an important tool for workforce development.

The workforce problem is also a training problem

The U.S. manufacturing sector alone may need as many as 3.8 million workers between 2024 and 2033, with roughly 1.9 million of those roles at risk of going unfilled if workforce challenges are not addressed, according to reporting on research from Deloitte and The Manufacturing Institute. The same reporting notes that digital skills, including simulation software skills, are becoming increasingly important in manufacturing environments.

That matters because the skills gap is not only about finding people. It is about preparing people.

Industrial work often depends on expertise that is difficult to capture in a manual. Experienced operators know what a machine should sound like. They know where not to stand. They know which steps are easy to overlook, which shortcuts are dangerous, and which abnormal conditions require immediate attention. Much of that knowledge is learned through years of experience.

The challenge is that organizations cannot always wait years for new workers to develop that judgment.

Simulation-based training helps close that gap by turning expert knowledge into structured, repeatable training experiences. A simulator can recreate the machine, the controls, the surrounding environment, the required sequence of actions, the common mistakes, and the consequences of those mistakes. Instead of relying entirely on one-on-one instruction from senior personnel, companies can preserve and scale that expertise across locations, teams, and generations of workers.

Faster Workforce Onboarding

Beyond “VR”: the simulator is the training system

It is tempting to think of spatial computing training as simply “putting someone in VR.” But that misses the point.

The headset, display, desktop interface, touchscreen, HoloLens, or physical controls are only the delivery mechanism. The real intelligence is in the simulation model underneath.

A strong industrial training simulator can include:

• Accurate 3D equipment models
• Realistic control behavior
• Physics-based machine movement
• Guided procedures
• Fault conditions and emergency scenarios
• Performance tracking
• Instructor tools
• Team-based multiplayer training
• Scoring and assessment
• Scenario variation
• Integration with physical controls or hardware mockups

This is where spatial computing becomes more than an immersive visualization. It becomes a digital training environment.

A trainee does not just look at a machine. They operate it. They inspect it. They respond to problems. They experience the results of their decisions. And over time, the simulator can produce data that helps trainers understand where individuals or teams need more practice.

Recent industrial VR safety-training research supports this direction. A 2024 study of VR-based safety training for refinery hazards described VR as a way to provide risk-free immersive practice for emergency protocols, equipment handling, spatial navigation, and evacuation procedures in high-risk industrial settings.

That is the key idea: simulation creates a safe place to practice unsafe, expensive, rare, or difficult-to-reproduce scenarios.

What this looks like in real industrial training

ForgeFX has seen this pattern across a wide range of simulation projects: the most valuable training applications are not generic 3D experiences. They are purpose-built systems designed around specific equipment, specific learners, and specific operational goals.

For example, the JLG AccessReady Fusion XR simulator demonstrates how spatial computing can help train operators on construction equipment such as aerial work platforms and telehandlers. These machines are expensive, physically large, and often used in environments where operator awareness is essential. A simulator gives trainees an opportunity to become familiar with controls, movement, positioning, and safe operation before stepping into the real equipment.

The Somero S22EZ Laser Screed VR Training Simulator shows a similar benefit in concrete construction. Laser screed operation requires an understanding of the machine, the surface being placed, control inputs, and the workflow of the job. In a real-world setting, training time can be limited by equipment availability, job schedules, material cost, and the risk of mistakes. A VR simulator allows operators to practice the procedure in a focused environment where repetition is possible.

The Global Ground Support Aircraft Deicing Simulator shows how simulation training can support aviation ground operations. Deicing requires operators to work around aircraft, equipment, weather constraints, fluid application procedures, holdover time considerations, and team coordination. A simulator can recreate aircraft types, deicing vehicles, environmental conditions, and multi-user scenarios in a transportable format.

And in heavy equipment projects for OEMs such as John Deere, Komatsu, and Caterpillar, simulation helps manufacturers train operators, technicians, dealers, customers, and sales teams on equipment that may be expensive, difficult to transport, or not yet widely available in the field.

Different industries. Different equipment. Same underlying value: spatial computing makes complex work easier to teach, safer to practice, and easier to measure.

The safety benefit: practice the dangerous moments before they happen

No simulator should be treated as a magic solution for safety or compliance. Safety outcomes depend on culture, supervision, procedures, engineering controls, maintenance, and many other factors.

But simulation can play an important role in safety training because it allows organizations to train for moments that are difficult to practice in real life.

Safer Training for High-Risk Tasks

A worker can practice responding to an equipment fault. An operator can learn what happens when a load is positioned incorrectly. A team can rehearse communication during a time-sensitive procedure. A trainee can experience a hazardous scenario without real-world consequences.

This matters because many industrial mistakes happen not because people lack information, but because they lack experience applying that information under realistic conditions.

Traditional training can explain what to do. Simulation lets people practice doing it.

That distinction is especially important for younger workers and new hires. Many digital-native learners are accustomed to interactive environments where they can experiment, receive feedback, and repeat tasks until they improve. Spatial computing-based simulation training aligns well with that learning style while still supporting the rigorous procedural standards required in industrial environments.

The operational benefit: train without disrupting the operation

Industrial training often competes with production.

Real equipment may be in use. A jobsite may not be available. A machine may be too expensive to dedicate to training. A physical training setup may require travel, instructors, fuel, materials, consumables, or downtime. Some scenarios may be too dangerous or rare to recreate safely.

Simulation helps reduce those constraints.

A simulator can be deployed in a training center, at a trade show, on a desktop, in a VR headset, in a transportable hardware station, or across multiple locations. Trainees can practice repeatedly without putting hours on machines, consuming materials, or waiting for ideal field conditions.

For OEMs, this creates an additional advantage. A training simulator can become part of the customer experience. It can help dealers demonstrate equipment. It can help customers understand safe operation. It can support onboarding for new machine models. It can reduce the burden on field trainers and make training more consistent across regions.

That is why more OEMs are viewing simulators not just as internal training tools, but as competitive advantages. A well-designed simulator can help a customer get value from equipment faster.

The measurement benefit: training becomes data

One of the most important advantages of simulation-based training is that it can produce measurable performance data. In a classroom, completion is often measured by attendance or a quiz. In a simulator, completion can be measured by actual behavior.

Measurable Performance Data

Did the trainee follow the correct sequence? Did they look in the right direction before moving? Did they choose the right tool? Did they respond correctly to a fault? Did they communicate with the team? Did they complete the task efficiently? Did they repeat the same mistake across multiple attempts?

This is where simulation turns training into digital workforce intelligence.

When training systems capture performance data, organizations can identify skill gaps, improve curriculum, compare scenarios, support certification programs, and tailor coaching to the individual. Over time, this data can help companies understand not only who has been trained, but who is ready.

That distinction matters in high-consequence industries.

From tribal knowledge to scalable expertise

Every industrial organization has experts whose knowledge is hard to replace. They know the equipment. They know the job. They know the mistakes people make. They know the warning signs that do not always appear in a manual.

Spatial computing-based simulation training gives companies a way to preserve that knowledge and scale it.

Capture Tribal Knowledge

The process often begins by working with subject matter experts to capture procedures, decision points, equipment behavior, environmental constraints, and common failure modes. That knowledge is then transformed into interactive scenarios. The result is not just a digital replica of a machine. It is a training system built around the way work actually gets done.

This is especially valuable when organizations need to train across multiple sites, support new product launches, standardize procedures, or reduce dependence on a small number of senior trainers.

A simulator does not replace experienced instructors. It amplifies them.

It gives instructors better tools. It gives trainees more practice. And it gives organizations a more consistent way to transfer knowledge.

Standardized Training at Scale

The future: multiplayer, AI, and digital twins

The next generation of simulation training will become even more intelligent.

Spatial Computing Simulation-Based Training: Stronger Workforce. Safer Operations. Better Results.

Multiplayer training allows teams to practice coordination, communication, and role-specific responsibilities in shared virtual environments. This is particularly valuable for aviation ground support, defense, oil and gas, construction, emergency response, manufacturing, and other industries where performance depends on more than one person.

AI will support adaptive instruction, automated coaching, scenario generation, and performance analysis. Instead of every trainee receiving the same experience, training systems will be able to adjust based on what the learner does well and where they struggle.

Digital twins will make training environments more connected to real equipment, real procedures, and real operational data. As equipment becomes more instrumented and connected, training simulators can increasingly reflect how machines behave in the field.

ForgeFX Simulations to Showcase VR-Based Operator Training at CONEXPO-CON/AGG 2026

CONEXPO-CON/AGG 2026 is almost here, and ForgeFX Simulations is bringing the future of heavy equipment operator training to Las Vegas.

As the construction and heavy equipment industries continue to face increasing demands for safety, productivity, and workforce readiness, immersive simulation has emerged as a practical, scalable solution. At this year’s show, ForgeFX will demonstrate how VR-based operator training is moving beyond innovation headlines and delivering measurable operational impact.

Visit ForgeFX in North Hall, Booth 10330

ForgeFX Simulations will be exhibiting in North Hall, Booth 10330, where attendees can experience firsthand our latest VR-based operator training simulators built specifically for PICO XR devices.

We’re pleased to be joined in our booth by representatives from PICO XR, demonstrating how tightly integrated hardware and training software create high-performance, enterprise-ready solutions.

Our immersive training systems are designed to help operators develop real-world skills in a safe, controlled environment, as well as reduce risk and improve safety outcomes. ForgeFX Simulations helps our customers accelerate their operators' time-to-competency, increase confidence before operating live equipment, and support workforce development initiatives at scale

By replicating real equipment behavior, jobsite scenarios, and operational challenges, ForgeFX simulations allow trainees to build muscle memory and decision-making skills without exposing equipment, personnel, or production schedules to risk. For heavy equipment manufacturers and industrial organizations, this means improved readiness, reduced downtime, and stronger long-term workforce capability.

From Iron to Impact: Greg Meyers to Speak at CONEXPO

In addition to live demonstrations at the booth, ForgeFX CEO Greg Meyers will present: “From Iron to Impact”, Ground Breakers Stage, Wednesday, March 4 at 3:00 PM.

ForgeFX Simulations at CONEXPO-CON/AGG 2026 — VR operator training simulators built for PICO XR, Booth N10330.

This session will explore how immersive simulation is transforming operator training across the heavy equipment sector.

Drawing on years of collaboration with leading OEMs and equipment manufacturers, Greg will share practical insights on:

• How simulation has evolved from experimental technology to operational strategy

• Lessons learned from implementing immersive training programs at scale

• The measurable safety and performance outcomes manufacturers are seeing

• Why workforce development now requires immersive, repeatable, data-driven training

The presentation reflects decades of experience working alongside industry leaders to modernize training approaches while preserving operational excellence.

Transforming Operator Training for a Changing Industry

The heavy equipment industry is undergoing significant change. Workforce shortages, increased safety expectations, and rising equipment complexity demand smarter training solutions.

Traditional methods alone are no longer sufficient to prepare operators for modern jobsite realities.

Immersive VR-based training provides a powerful complement to hands-on experience. It enables repetition without risk, performance tracking without downtime, and scalable deployment across multiple locations.

At ForgeFX Simulations, we’ve spent more than 20 years developing advanced training simulators that bridge the gap between equipment engineering and human performance. Our work at the intersection of simulation, virtual reality, and industrial training continues to push operator development forward.

CONEXPO 2026 provides an opportunity to experience that evolution firsthand.

Join Us in Las Vegas

If you’re attending CONEXPO-CON/AGG 2026, we invite you to:

• Visit North Hall, Booth 10330 to experience our VR-based operator training built for PICO XR

• Attend Greg Meyers’ session, “From Iron to Impact,” on Wednesday at 3:00 PM

• Connect with our team to discuss how immersive simulation can support your training objectives

We look forward to the conversations, demonstrations, and insights that will shape the next generation of heavy equipment operator training.

See you in Las Vegas.

Augmented World Expo, ForgeFX Simulations, June 10-12 2025

ForgeFX Simulations is Proud to Sponsor Augmented World Expo (AWE) USA, June 10-12 2025

Augmented World Expo is the premier global event for spatial computing, taking place June 8–10 in Long Beach, California. As a leader in immersive training solutions, ForgeFX is excited to contribute to the conversation around spatial computing’s growing impact on workforce development and enterprise training. 

In addition to exhibiting a collection of immersive training simulators at booth 346 on the expo floor, we’ll be actively engaging with attendees throughout the event—our CEO, Greg Meyers, will be delivering a seminar titled How VR is Bridging the Construction Labor Gap and leading a Roundtable Session titled Scaling XR Training: Lessons from Fortune 500 Deployments, while our Executive Director of Enterprise Partnerships, Mary Pierce, will be hosting exclusive VIP tours on the show floor. We look forward to connecting with industry leaders and innovators shaping the future of spatial computing!

Come experience how we’re using immersive XR simulations to revolutionize workforce training and development across industries.

📍 Visit us at Booth 346 to see live demos, meet the team, and talk about how simulation-based training can supercharge your workforce.

💬 Come to our speaker session: How VR is Bridging the Construction Labor Gap.

🔁 Join our roundtable session: Scaling XR Training – Lessons from Fortune 500 Deployments.

Nuclear Power Plant Training Simulators

If you're in the business of training complex system operators you're well aware of the challenges involved. From making sure that your staff is fluent with the controls, to gauging their level of competency, to guaranteeing year-round training opportunities; virtual training simulators provide you with all of these benefits. And if your operators are charged with mission-critical tasks these benefits become a necessity, rather than a nicety. When it comes to mission-critical tasks, nuclear power plant operation is at the top of the list. And how do you train your nuclear power plant operators? With training simulators of course. The African continent may only have one nuclear power plant, the Koeberg nuclear power station in South Africa, but they already have two state-of-the-art training simulators. The simulators replicate the station's main control room as well as the emergency control facility.

Earlier this year the same company that delivered the simulator to Koeberg, L-3 MAPPS, produced a training simulator for the Embalse nuclear power plant in Argentina. The Embalse simulator runs on a standard Windows operating system platform and simulates all of the plants operational systems, including the reactor, steam supply and electrical systems.

In China, at the Sanmen and Haiyang Nuclear Power Plant, the Westinghouse Electric Company recently installed their AP1000 nuclear power plant training simulators, considered the most modern nuclear power plant operator training simulators in the world. Utilizing the real-world plant instrumentation and controls, the simulator delivers a high degree of realism, allowing plant operators to be prepared to take their operator license examination within 18 months of the start of their training.

Whether you're training operators to run a nuclear power plant, a natural gas power plant, or any other complicated system or piece of machinery - virtual training simulators allow for the highest degree of fidelity, without incurring any of the costs, risks and potential hazards associated with real-world training. Obviously nuclear power plants are at the high end of the spectrum when it comes to the risks associated with training, but regardless of your equipment, if you're training new employees or keeping seasoned operators' skills sharp, training simulators allow you to conduct training year-round, under a variety of simulated conditions and without taking real-world equipment out of production.

 Contact us on ForgeFX  Get updates on Facebook  Get tweets on Twitter Connect on LinkedIn