What is possible now that was not possible before?
For the first time, human creativity, artificial intelligence, physics-based simulation, biology, advanced manufacturing, robotics, sensing, optimization, and institutional memory can begin to operate as one integrated engineering system. MNEOS Systems is being built to create that system.
Reunifying engineering.
A computational-engineering institution being developed under NuvoNexus, LLC. Initial operating center in Fairlawn, Virginia.
Engineering knowledge does not compound the way it should.
Modern technical work is fragmented. Physics is separated from biology. Artificial intelligence is separated from manufacturing. Simulation is separated from test data. Engineering judgment remains trapped in individual minds. Company knowledge disappears when people leave. Research becomes papers without becoming buildable systems. Teams repeat failures because the reasoning behind earlier decisions was never preserved.
The tools may improve, but the institution forgets.
MNEOS exists to reverse that.
A computational-engineering institution.
MNEOS is being built as a long-lived institution where scientists, engineers, builders, and intelligent systems work together to solve physical-world problems beyond the reach of any one company, discipline, tool, or founder.
It combines aspects of a research institute, engineering laboratory, technical residency, AI-systems organization, manufacturing-aware design environment, venture platform, and institutional memory system. It is not reducible to any one of them.
Institutions outlive products. Architectures outlive tools. Memory outlives conversations. Capability should compound.
Beyond AI. Beyond simulation. Beyond automation.
Computational engineering is the integrated practice of using computation to understand, design, optimize, manufacture, test, and deploy physical systems. It brings together physics-based simulation, AI-assisted reasoning, computational electromagnetics, computational biology, computational materials science, optimization and inverse design, scientific machine learning, robotics and embodied intelligence, digital manufacturing, experimental evidence, human engineering judgment, institutional memory, and governed decision systems.
Engineering becomes a continuous intelligence loop.
DIAGRAM · NINE FORMS OF ENGINEERING INTELLIGENCE CONVERGING
From observation to institutional knowledge.
Observe
Field data, sensing, experiments, documents, images, conversations, and system behavior.
Remember
Context, evidence, assumptions, decisions, failures, relationships, and prior work.
Infer
Patterns, hypotheses, analogies, uncertainty, causal possibilities, and cross-domain insight.
Design
Models, architectures, materials, simulations, optimization, manufacturability, and test plans.
Build
Prototype, fabricate, print, machine, assemble, integrate, and deploy.
Test
Measure, validate, falsify, compare to models, and update assumptions.
Adapt
Redesign, refine, scale, transition, and respond to new evidence.
Institutionalize
Preserve the lessons, models, design rules, evidence, and reasoning so future work starts further ahead.
THAT IS THE MNEOS LOOP.
Human-led. AI-amplified. Evidence-governed.
MNEOS does not begin from the premise that artificial intelligence should replace scientists or engineers.
Human beings remain essential for judgment, intuition, ethics, taste, mission understanding, physical experience, relationship trust, responsibility, and final authority. Artificial intelligence can expand search, synthesis, simulation support, pattern recognition, hypothesis generation, design exploration, code generation, anomaly detection, optimization, and documentation.
The collaboration must be governed.
DIAGRAM · HUMAN–AI GOVERNANCE FLOW
The operating system for institutional intelligence.
Beneath MNEOS is DOS, the governed computational substrate that connects people, AI systems, documents, decisions, simulations, experiments, workflows, equipment, projects, relationships, evidence, and action.
DOS allows humans and artificial intelligence systems to collaborate across time without losing memory, context, authority, provenance, or accountability. It is not simply another assistant interface. It is the architecture through which MNEOS remembers, reasons, coordinates, verifies, and acts.
Organized around hard problems — not product categories.
Physics-first engineering
Electromagnetic propagation, RF structures, antennas, waveguides, metamaterials, thermal systems, fluid-structure interaction, multiphysics modeling, and complex physical systems.
Biological architecture
Biological signal processing, evolutionary optimization, distributed sensing, adaptive control, immune-inspired detection, developmental systems, and bio-inspired architecture.
From atoms to fielded systems
Ceramic systems, additive manufacturing, composites, programmable materials, process modeling, manufacturability, digital qualification, and scalable fabrication.
Sensing in contested environments
Distributed RF systems, conformal arrays, sensor fusion, contested-environment sensing, resilient communications, and edge intelligence.
Intelligence in the physical world
Humanoid systems, autonomous platforms, human-machine teaming, simulation-to-field transition, adaptive control, robotic laboratories, and physical AI.
Intent to engineering
Intent-to-engineering, voice-to-design, simulation orchestration, evidence-aware agents, automated test planning, design memory, laboratory automation, and engineering-tool integration.
Intelligence must enter the physical world.
The next frontier is not only intelligence that generates language, images, or software. It is intelligence that understands physical constraints, interacts with tools and environments, collaborates safely with people, learns from real evidence, and contributes to building, testing, maintaining, and operating complex systems.
MNEOS intends to explore humanoid and mobile robotic systems, robotic laboratory assistants, automated experimentation, dexterous manipulation, robot-supported manufacturing, autonomous inspection, simulation-to-reality transfer, human-machine work allocation, safety, authority, and accountability in embodied AI, and long-duration learning from physical operations.
The goal is not spectacle. The goal is useful, governed physical intelligence.
Computation must connect to making.
Engineering intelligence is incomplete if it cannot move into physical reality. MNEOS will connect design and simulation to real manufacturing constraints, materials behavior, process evidence, inspection, qualification, and field performance.
Initial areas may include additive manufacturing, ceramic and advanced material systems, RF and microwave structures, multimaterial fabrication, digital manufacturing instructions, process simulation, robotic production, quality evidence, design for manufacturability, distributed and allied production, and qualification and certification support.
MacroVation and related operating environments provide practical settings for applying these ideas to real programs and hardware — subject to governed boundaries, permissions, confidentiality, export controls, and originator rights.
Future engineers should inherit more capability than we inherited.
The MNEOS Engineering Commons is the long-term layer through which engineering knowledge compounds. It is not a claim that all knowledge is public, unowned, or freely transferable. It is an architecture for preserving and governing design rules, test evidence, simulation models, manufacturing knowledge, failed attempts, technical decisions, supplier and process knowledge, reusable architectures, people and capability networks, publications and training, research questions, and institutional lessons.
Ownership, permissions, confidentiality, security, export-control requirements, and originator rights must remain visible.
The next project should not begin where the last project began.
Help build the future of computational engineering.
MNEOS is beginning to assemble a multidisciplinary community of scientists, engineers, mathematicians, researchers, software architects, machinists, builders, and technical leaders who want to work on consequential physical-world problems. We are especially interested in people who work across boundaries rather than inside only one discipline.
- Computational physics
- Applied mathematics
- Numerical methods
- Electromagnetics
- RF & microwave engineering
- Scientific machine learning
- Computational materials science
- Computational chemistry
- Multiphysics simulation
- Optimization & inverse design
- Robotics & autonomy
- Humanoid systems
- Advanced manufacturing
- Computer-aided engineering
- Scientific software architecture
- Knowledge representation & provenance
- AI-agent orchestration
- Human–AI systems
- Laboratory automation
- Systems engineering
- Experimental science
No single institution can build this alone.
MNEOS is interested in thoughtful relationships with universities, national and government laboratories, research institutes, defense and aerospace organizations, advanced manufacturers, robotics companies, AI and scientific-computing organizations, portfolio companies, foundations and philanthropic institutions, family offices and strategic capital partners, technical professional societies, and individual scientists and inventors.
Built from a career at the boundary between invention and institution.
David Sherrer is a deep-technology founder, inventor, and operating executive whose career has focused on turning difficult physical technologies into intellectual property, funded programs, manufactured products, operating companies, and strategic acquisitions.
He founded Haleos and Nuvotronics, led the commercialization of PolyStrata® advanced RF and microsystems technology, executed DARPA-backed development through Phase I–III, built manufacturing capability, and has more than 125 issued patents worldwide.
MNEOS emerges from a lesson repeated across those experiences: technical capability does not compound automatically. It compounds only when people, evidence, tools, decisions, manufacturing knowledge, and institutional memory are intentionally connected and preserved.
Assembling the people, architecture, programs, infrastructure, and partnerships.
If you are working on a difficult physical-world problem — or believe your experience can help build the institution itself — we would like to hear from you.
Reunifying engineering.