Live simulators and material science instruments built for the Serpentis-class architecture. Each tool opens in a dedicated window — run the physics, adjust parameters, observe the system respond.
Interactive acoustic geometry optimizer for the DragonWorx proposed PMN-PT phase-array Mach Effect Thruster. Select from five array configurations — Planar 120°, Tetrahedron, Helical Tower, Spherical Array, Nested Shells — and tune crystal parameters, operating voltage, mass, and phase offset. Outputs array factor, coercive field safety check, acoustic wavelength, and estimated thrust across a logarithmic scale from the Woodward theoretical floor to the PMN-PT enhanced estimate.
Real-time aerodynamic analysis for the Serpentis-class wing. Dial in airspeed, angle of attack, altitude, wing area, and pilot mass. Toggle biomimetic surface features — Denticle, Tubercle LE, Auxetic, Washout, Fairing — and watch lift, drag, glide ratio, and range update instantly. The same surface configurations modelled here map directly to the DragonSuit Apex material stack.
Full four-mechanism adhesion stack modelling across the complete GripSuit platform — vdW nano-pillars (gecko), clingfish compliant lip, remora self-tightening lamellae, and DOPA mussel chemistry — against eight substrates from polished glass to submerged concrete. Each mechanism activates or deactivates based on surface roughness Ra and moisture conditions. Includes mode toggle (vdW-only vs. rough stack vs. Aqua) and live breakdown showing which mechanism is carrying the load at any given Ra.
Models material performance across the full temperature swing of a Serpentis-class jump — from high-altitude cold soak (−40 °C) through freefall aerodynamic heating to ground-impact thermal spike. Shows phase transition windows, SMP stiffness degradation curves, and operational limit flags for each of the five composite layers. Critical for validating exit altitude decisions and suit deployment timing.
Simulates the full Serpentis-class deployment sequence: accelerometer freefall detection → MRE membrane activation → contact area extension vs. altitude consumed. Set exit altitude, terminal velocity, and membrane response time to calculate exactly how much altitude the deployment window consumes before the wing reaches full contact area. Defines the minimum safe exit altitude for any jump profile.
Cycle life estimation for the (TiZrHf)₄₄Ni₂₅Cu₁₅Co₁₀Nb₆ high-entropy alloy vertebral nodes — the structural spine of the Serpentis exo-suit chassis — under repeated dynamic loading. Uses Miner's Rule cumulative damage with a strain-glass microstructure fatigue model. Configure peak strain, loading frequency, operating temperature, and jump frequency to project node service life and maintenance intervals.
Validates the three-layer exo-fascia composite architecture through an egg-drop physics model. Adjust outer shell stiffness, mid-layer energy absorption coefficient, and inner padding compliance — observe in real time how kinetic energy distributes (and dissipates) across each layer before reaching the core. The egg represents the vertebral column. Tune the parameters until the egg survives; those parameters map to your material spec.
The full DragonWorx biological reference matrix — every creature, every mechanism, every platform application, and TRL level across the complete product portfolio. Gecko, humpback whale, peregrine falcon, clingfish, remora, mussel, shark, flea, boxfish, electric eel, and more. The master map of nature's engineering solutions to our design problems.
Interactive Tg and modulus tuning for thermoset shape-memory polymers. Dial in crosslink density, monomer ratio, and chain extender to target independent Tg and rubbery modulus — for DragonSuit rib fabrication, neural probe substrates, and wearable electronics applications. Live stress-strain and DSC curve output.
Model spatially-graded stiffness transitions across multi-layer polymer substrates — from rigid electronic device interface to compliant biological tissue contact. Calculates delamination risk, peak interfacial strain, and mechanical mismatch index across GripSuit pad backing layers and neural probe geometries.
Model furan-maleimide Diels-Alder covalent adaptable networks for reprocessable thermosets, recyclable composites, and shape-morphing structures. Tune crosslink density, monomer MW, and regiochemistry to predict retro-DA temperature, gel fraction, and reprocessing cycle performance.
Design multi-material print schedules for shape-morphing SMP structures. Configure active and passive material zones, fiber orientation angles, and stimulus sequences to predict shape change, curvature, and actuation energy for wearable, biomedical, and aerodynamic applications.
Model electrical impedance spectra and recording quality for softening SMP neural probes across acute and chronic implantation phases. Configure electrode geometry, SMP substrate properties, and tissue response to predict impedance at 1 kHz, charge injection limits, and signal-to-noise ratio over time.