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Ford Motor Company
Sitting on an anonymous stretch of pavement in Long Beach, California, is Ford’s Electric Vehicle Development Center (EVDC), where the Detroit-based automaker is building something far more consequential than a new vehicle. Within this complex of white, non-descript buildings the company is redefining how it engineers, validates, and ultimately delivers its next generation of electric vehicles—starting with a compact pickup aimed squarely at the heart of the global market.
The process of designing, engineering, and building this new EV represents a ground-up rethink of how Ford creates vehicles in the electric era, anchored by what the company calls its “Universal Electric Vehicle Platform". The goal is as ambitious as it is necessary: create a flexible, scalable architecture that can underpin multiple vehicles while dramatically reducing cost, complexity, and development time.
Advanced technology and tools allow for rapid iteration and development of new components
Ford Motor Company
Ford’s Universal EV platform is designed to do something traditional vehicle architectures struggle with—adapt quickly. Unlike internal combustion platforms that are constrained by engine packaging, transmission tunnels, and legacy structural requirements, this new architecture is built around a flat, modular battery pack and a highly configurable chassis. The result is a flexible foundation that can support multiple body styles, wheelbases, and use cases without requiring a complete redesign for each variant. For the upcoming compact pickup, this means optimizing for urban usability, efficiency, and affordability—without sacrificing the durability expectations that come with a truck body style.
Engineers at the EVDC emphasized a key target: reducing platform complexity by as much as 30 percent compared to previous programs. A design mantra, stated by multiple EVDC team members while touring the plant, says: “The best part is no part; the second-best part is a part that serves more than one purpose.” This approach is reflected in the Universal EV platform using 20% fewer parts, and 40% fewer workstations during assembly. That reduction translates directly into faster development cycles and lower production costs—two critical factors as automakers face increasing pressure to make EVs profitable.
Building an EV isn’t just about engineering—it’s about manufacturing at scale. And this is where the EVDC’s work becomes particularly critical. One of the primary goals for the Universal EV platform is to streamline assembly processes. That means fewer parts, fewer steps, and more modular components that can be produced efficiently across different facilities.
Team members highlighted the use of large-scale casting techniques to replace multiple smaller structural components with single, integrated pieces. This approach not only reduces weight but simplifies assembly, improves structural rigidity and reduces cost. Additionally, the platform is designed to be compatible with existing manufacturing infrastructure wherever possible, minimizing the need for costly factory overhauls. The end result is a production system that can adapt quickly to changing demand—an essential capability in today’s volatile automotive market.
The EVDC has extensive fabrication capabilities, allowing it to rapidly create components and prototypes to test
Ford Motor Company
Perhaps the most striking aspect of the EVDC’s work is the emphasis on speed. Traditional vehicle development cycles can take four to five years. Ford’s new approach aims to cut that timeline significantly—leveraging digital simulation, rapid prototyping and iteration, and integrated software development to accelerate progress. Engineers described a process where virtual reality testing plays a much larger role, allowing teams to identify and resolve issues earlier in the development cycle. Full-size physical prototypes are still essential, but they’re used more strategically, reducing both time and cost.
The Universal EV Platform’s faster development pace is further supported by in-house prototyping for nearly every component. The EVDC can fabricate everything from suspension pieces to body panels to wiring harnesses and connectors, removing the need to wait weeks or longer for outside vendors to produce a component for testing. This means faster, lower-cost journeys from initial concept to final production sign off.
Ford’s Universal EV will use prismatic LFP (Lithium Ion Phosphate) battery packs and a 48-volt electrical system. This battery pack structure allows Ford to use the top of the pack as the floor in the vehicle cabin, reducing parts, weight, and cost. And the high-flow 48-volt electrical system, along with optimized hardware modules and integrated electronic controllers, allowed the team to remove over 4,000 feet of copper wiring, reducing, once again, materials, weight, and cost.
Ford’s EVDC also has full “climatic” testing capabilities to measure how the batteries and electronics perform under extreme temperature conditions. A four-wheel chassis dyno can recreate real-world driving conditions under these varying temperatures while the development team monitors everything from power output to charge time to driving efficiency to the battery’s temperature as it’s being maintained by the vehicle’s on-board heating and cooling systems. Full EPA testing and certification can also be performed at the EVDC.
A collaborative environment contributes to speed and innovation at Ford's Electric Vehicle Development Center
Ford Motor Company
After a few hours spent touring the EVDC it was clear the site’s capabilities cover a broad spectrum of vehicle design, engineering, fabrication, and testing while leveraging some of the most advanced equipment currently being employed at an automotive facility. But what really impressed me was the integrated approach across this spectrum of capabilities. Every EVDC team member talked about how effective they feel in their department because every other department is not only on site but anxious to communicate throughout the process. The term “silos” is often used to describe a corporate or manufacturing environment at large companies, and never in a complimentary way.
The EVDC atmosphere appears to be the opposite of silos. Instead of feeling like a single, isolated stage of vehicle development, each team and team member at the EVDC described a cohesive, collaborative atmosphere where iteration and cross-team feedback are central to the process. The facility itself is also quite impressive and seems ideal for human gatherings. Yes, it’s chock full of advanced equipment and capabilities, but every area also had an almost “college campus science lab” vibe throughout it.
I’ve seen this approach – a dedicated, fully-empowered team of enthusiastic Ford employees, working together in their own environment toward a common goal – once before. It was almost 25 years ago, at a specific Dearborn facility where a team of talented Blue Oval folks worked diligently to turn the 2002 Ford GT40 concept car into a full-fledged production vehicle for Ford’s Centennial Celebration – in just 18 months.
In both cases, the motivation to succeed was driven by enthusiastic Ford employees fully committed to meeting a challenging goal, a goal every team member believed in. It worked in 2003, and bodes well for Ford’s Electric Vehicle Development Center and the models it will spawn, starting with a compact electric truck next year.
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