Physical AI Platform
Beyond software.
A new layer
of intelligence.
InfinitForm is the Physical AI platform for mechanical engineering, purpose-built for the way physical things are designed, optimized, and made. A new architecture for a new era.
True parametric CAD output, editable from day one
DFM embedded at the solver level, before output is generated
Built for modern manufacturing processes, from CNC to additive
GPU-accelerated: days to minutes, at production scale
Explore the platform — click a capability to jump in
01
Parametric Design for Real Manufacturing
The only AI that outputs CAD your engineers can actually use.
// Core Differentiator
Topology optimization produces shapes. Parametric design produces engineering. One is a suggestion. The other is a part.
InfinitForm's solver operates natively in the parametric domain, generating B-rep geometry with full feature history, dimensional constraints, and manufacturing intent embedded from the first iteration.
Boundary Representation
Output is defined by surfaces, edges, and vertices, not polygons. B-rep geometry is the native format of every professional CAD system in the world.
Full Design History
Every design decision is recorded as a parametric feature: fillets, bosses, pockets, shells. Engineers modify individual steps without rebuilding the part from scratch.
Dimensional Intelligence
Critical dimensions, tolerances, and relationships are maintained as live constraints, not burned into static geometry, enabling downstream modification without creating errors.
Native Format Output
Deliver .sldprt, .prt, and STEP files with full feature fidelity. Your PLM system ingests the result like any other model your team produced.
Pre-Validated Geometry
Output is mathematically valid: no gaps, no non-manifold edges, no zero-thickness walls. Simulation tools and CAM programs run without preprocessing errors.
Multi-Config Exploration
Create multiple projects to explore different manufacturing processes, compare cost analysis, and evaluate manufacturability trade-offs — each producing a fully editable parametric model you can refine independently.
02
AI Co-Pilot
Every engineer enabled with the expertise their project demands.
// Design Philosophy
AI that explains its reasoning is not just more trustworthy. It is a teaching machine. Every Co-Pilot report makes your engineers better engineers.
The goal is not automation. The goal is compounding: AI that makes your engineering team exponentially more capable over time, not dependent on a black box they cannot interrogate or trust.
Design Rationale Reports
Every optimization generates a comprehensive report documenting why the AI made each structural decision, covering material distribution, load path prioritization, and feature placement in plain engineering language.
Multi-Objective Analysis
When performance, weight, and cost pull in different directions, the Co-Pilot surfaces the Pareto frontier: the set of designs where no objective can improve without another getting worse. Each position is explained.
Real-Time Design Query
Ask the platform why a feature exists, what happens if a constraint relaxes, or how the design would change under a different load case. Get structured engineering answers, not natural-language guesses.
Institutional Memory
The Co-Pilot is informed by every optimization your organization has ever run, accruing domain knowledge specific to your materials, processes, tolerances, and customer requirements over time.
Accelerated Competence
Junior engineers working with the Co-Pilot develop manufacturing intuition faster than any mentorship program can deliver, because every design they touch comes with a full explanation of the physics behind it.
Design Review Documentation
Co-Pilot reports serve as living design documentation: fully searchable, version-controlled, and formatted for engineering review boards, customer submissions, and regulatory compliance packages.
Report Format
Structured engineering documentation covering load case summaries, constraint satisfaction tables, sensitivity analysis, and manufacturing readiness assessment. Not a chatbot transcript.
Language
Engineering-native output using FEA terminology, GD&T language, and manufacturing process vocabulary. Co-Pilot communicates like a principal engineer, not a general-purpose AI assistant.
Availability
Advanced and Professional plans. Co-Pilot capability scales with plan tier. Advanced includes standard design rationale; Professional includes full institutional knowledge integration.
03
Automated Design for Manufacturability
Designs that are manufacturable before they leave the optimizer.
// What Changes
The design review meeting where manufacturing sends everything back? That meeting no longer exists.
Wall thickness minimums, draft angle requirements, undercut restrictions, tool radius constraints, and tooling accessibility rules are all applied in real time during optimization, not checked afterward. Every output is already a manufacturable part.
Minimum Thickness Enforcement
The optimizer never generates geometry below your specified minimum wall thickness, eliminating the single most common reason design files are rejected by manufacturing.
Mold and Die Release
For cast and molded parts, draft angles are enforced relative to the pull direction throughout optimization. Every surface that must release from tooling does so by design, not by luck.
Tooling Accessibility
CNC-machined parts are validated for tool access from every required direction. The optimizer cannot create geometry a cutter cannot reach, eliminating EDM workarounds driven by bad DFM.
Stack-Up Analysis
Critical dimensional tolerances and their assembly stack-up implications are factored into the structural optimization, ensuring the tightest tolerance requirements do not conflict with structural geometry.
Tool Radius Constraints
Internal radii are constrained to achievable values for your specified tooling, preventing the generation of sharp internal corners that require EDM or hand-finishing to produce.
Process-Specific Rulesets
DFM rules are applied per-process. CNC, casting, molding, and additive each have distinct geometric requirements, and InfinitForm applies the correct ruleset for the manufacturing process you specify.
04
Multi-Process Manufacturing Support
Optimized for how the world actually manufactures things.
CNC //
CNC Machining
3, 4, and 5-axis constraints. Tool accessibility validation. Minimum radius enforcement. Fixturing geometry preservation. Prismatic output aligned to machine coordinate systems.
DC //
Die Casting
Draft angle enforcement. Parting line optimization. Wall uniformity for consistent fill. Shrinkage compensation. Gate and runner compatibility. Core pull direction constraint.
IM //
Injection Molding
Draft analysis per pull direction. Sink mark and warp prevention. Gate location optimization. Rib and boss design rules. Uniform wall thickness targets. Side action minimization.
EX //
Extrusion
Constant cross-section constraint. Profile geometry optimization. Wall thickness uniformity. Hollow section and void optimization for structural-to-weight efficiency along the extrusion axis.
AM //
Additive Manufacturing
Overhang control. Support minimization. Build orientation optimization. Layer anisotropy compensation. Lattice structure generation for internal volume. Post-machining allowance preservation.
// Cross-Process Decision Support
Not sure which process is right for a new component? InfinitForm optimizes the same part for multiple processes simultaneously, delivering a structural comparison that quantifies the cost, weight, and performance trade-offs between manufacturing routes.
A decision that previously required separate analyses by separate specialists, resolved in a single platform run. The right process for the right part, with data to defend the choice.
Process Scope
CNC Machining, Die Casting, Injection Molding, Extrusion, and Additive Manufacturing available today. Sheet Metal and Forging on the roadmap.
Plan Availability
Standard: CNC + Additive only. Advanced: CNC + Additive + prismatic output. Professional: All five processes including Die Casting, Injection Molding, and Extrusion.
Output Type
Organic designs available on all plans. Prismatic parametric output, the production-ready format, available on Advanced and above.
05
Seamless CAD Integration
Zero workflow change. Transformational output.
Import
SolidWorks (.sldprt, .sldasm)
Full assembly import
Import
Siemens NX (.prt)
Part and assembly
Import
Autodesk Fusion (.f3d, .step)
Part and assembly
Universal
STEP / IGES
Neutral format import and export
Export
Parametric Native Export
Full feature tree preserved
PLM
Teamcenter / Enovia
Metadata and revision sync
Simulation
Abaqus / Nastran
Pre-validated geometry
// On-Premise Option
For organizations with data sovereignty requirements, InfinitForm deploys fully on-premise: within your firewall, on your infrastructure, with no design data leaving your environment.
ITAR-compliant deployment available. Ideal for aerospace, defense, and government programs where cloud data residency is restricted. Contact us for on-premise licensing.
Step 01 //
Import Existing Assembly
One click. Bring in your existing design, loading conditions, and boundary constraints from your current CAD environment.
Step 02 //
Define Optimization Targets
Specify your manufacturing process, material, performance targets, and constraints. The platform validates inputs before running.
Step 03 //
Optimize and Review
GPU-accelerated optimization runs. Review candidates in the browser-based viewer. Co-Pilot explains each design decision in plain engineering language.
Step 04 //
Export Into Your Workflow
Download the parametric model in your CAD format. It opens as a native part. Your existing tools, unchanged. Your output, transformed.
06
GPU-Accelerated Optimization Engine
Days to minutes. Not an optimization. A different architecture.
// Sequential CPU-Based Optimization
Days
Typical design optimization cycle
// InfinitForm GPU-Accelerated Engine
Minutes
InfinitForm optimization cycle
Massively Parallel Evaluation
Thousands of design candidates are evaluated simultaneously across GPU cores, not sequentially. The full solution space is explored in the time legacy tools spend evaluating a single candidate.
Simultaneous Multi-Constraint
Structural, thermal, dynamic, and manufacturing constraints are applied in a single solver pass, not as sequential filters. The result satisfies all objectives simultaneously, not one at the expense of others.
Multi-Load Case Processing
Real components experience multiple load scenarios across their service life. InfinitForm optimizes for all defined load cases concurrently, producing designs that perform across every operating condition.
Proprietary Solver Architecture
InfinitForm's core solver is not an adaptation of academic topology optimization code. It was built for parametric output in manufacturing contexts: a structurally different mathematical approach to a structurally different problem.
Cloud GPU Scaling
Compute resources scale dynamically with problem complexity. Simple parts run on minimal infrastructure. Large assemblies with many constraints automatically access expanded GPU capacity without configuration.
10x More Design Exploration
When a full optimization cycle takes minutes instead of days, your team runs 10x more iterations in the same calendar time, finding solutions that sequential exploration would never reach within any realistic budget.
// See It In Action
Bring your hardest
engineering problem.
No synthetic demos. No canned examples. Bring a real part, a real load case, and a real manufacturing process. We will run InfinitForm against it, and the output speaks for itself.