Computational design software using implicit modeling for robust parametric design and simulation-driven engineering workflows.
NTop offers implicit modeling technology that enables engineers to create unbreakable parametric models, accelerate design iterations, and integrate simulation in the design process for aerospace, defense, and additive manufacturing applications.
Uses signed distance functions instead of traditional CAD boundary representations to create robust, unbreakable parametric models that update reliably without rebuild errors.
Enables capturing engineering logic and intent through visual programming, maintaining parametric relationships automatically for adaptable workflows.
Includes embedded finite element analysis (FEA) and computational fluid dynamics (CFD) to provide real-time physics feedback during design iterations.
Allows engineers to make instant design changes and explore hundreds of variants quickly without fragile geometry or crashes.
Captures and codifies design strategies and engineering intent into reusable workflows that can be applied across multiple projects and variants.
Automates generation of production-ready additive manufacturing geometries including lattice structures, lightweighting, and support optimization.
Supports systematic evaluation of complex geometries and assemblies with stable geometry that scales with design complexity.
Integrates simulation early and continuously in the design process to reduce trial and error and surface risks before costly errors occur.
Input initial parameters, constraints, and performance criteria relevant to the engineering project.
Use nTop's implicit modeling and visual programming to build a flexible, unbreakable parametric geometry.
Pricing details are gathered from the official nTop website and are provided for reference only. Always confirm the latest information directly with the vendor.
| Plan | Price | Highlights |
|---|---|---|
| Contact Sales | Custom Pricing | Access to full software capabilities
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Embed FEA or CFD simulation within the design to evaluate performance and identify risks in real time.
Rapidly modify parameters to generate and assess multiple design variants without geometry failures.
Save successful design logic as reusable workflows to apply across different projects or product families.
