SoafAii Portfolio Demo

A working tour of the C3D voxel manufacturing platform and four of its strongest applications for IAI strategic interest. Built for screen-share discussion with Meir Shabtai, 21 May 2026.

Francois Flechter · BIS WLL — Bahrain · Confidential

PLATFORM

C3D Architecture

The manufacturing OS: VTL-3 language, multi-backend orchestrator, ExoShield, VIS interposers, QA passport. Click any component to inspect.

PLATFORM

C3D in Operation

Type a natural-language manufacturing intent. Watch the compiler emit VTL-3 triplets, select backends, generate QA passport. Live AI.

APPLICATION

Aero-EM Surfaces

Voxelized wing surface with flow control + EM stealth + crash mitigation + harvesting. Adjustable parameters; sectorized RCS response.

APPLICATION

Quiet Rotors

Trailing-edge micro-appendage arrays for UAV acoustic control. ANC + phase control + actuated edge voxels. Target 8+ dB reduction.

APPLICATION

Active Ground Pads

Voxelized aircraft pushback and apron logistics. Vessel-motion-compensated naval helipads. Vertiport infrastructure.

APPLICATION

μ-Active Capture Decks

Programmable-friction surfaces for VTOL landings. Sectorized μ control. Soft-capture progressing to hard-lock. Sea-state operation.

PLATFORM · USPTO FILED · Master Provisional Consolidated

C3D — Multi-Scale Voxel Manufacturing OS

Click any component in the diagram to inspect. The flow runs top to bottom: natural-language intent compiles to VTL-3 triplets, the orchestrator selects backends, VIS interposers and ExoShield handle compatibility and protection, the QID/PUF passport seals the audit trail.

Select a component

Click any component in the diagram on the left to inspect its role in the C3D manufacturing OS.

PLATFORM · LIVE AI

C3D in Operation — Natural-Language Compilation

Type any manufacturing intent in plain English. The C3D compiler produces structured VTL-3 voxel descriptions, selects backend(s), and emits the QID/PUF passport. Powered by live AI through the SoafAii intent pipeline.

Input natural-language manufacturing intent

Output

Submit an intent to see the C3D compilation result. The output will include VTL-3 voxel triplets, backend selection rationale, VIS/ExoShield choices, and a QID/PUF passport.

VOXEL APPLICATION · USPTO FILED · Aerospace platforms

Reconfigurable Voxelized Aero-EM Surfaces

Voxelized surface integrating four capability classes: active flow control (suction + Coanda), electromagnetic stealth (sectorized RCS reduction), crash mitigation (inflatable voxels), energy harvesting (rectenna voxels). Retrofit-ready into existing composite skins.

Wing Cross-Section — Voxel Layout

Each voxel zone color-coded by function. Adjust controls on the right to see response.

Controls

Operating Mode

Suction Porosity 15%

Coanda Jet Strength 40%

Metasurface Phase 120°

Response

ΔCLmax +0.62

Approach speed Δ −14%

RCS sector (X-band) −12 dBsm

Response time 42 ms

Energy harvest 28 W/m²

VOXEL APPLICATION · USPTO FILED · Aeroacoustic control

Voxelized Trailing-Edge Micro-Appendage Arrays

Rotor and propeller systems with distributed micro-appendage arrays (flagella voxels) on trailing edges, plus protective duct/guard with near-field microphones and outward acoustic emitters. Region-targeted tonal attenuation via rotor phase control + feedforward ANC.

Multi-Rotor — Edge Voxel Detail

Top view of a 4-rotor configuration. Edge voxel array visualized on each blade. Adjust controls to see acoustic response.

Controls

Mission Profile

Active Noise Control 70%

Edge Voxel Actuation 60%

Rotor Phase Δ 15°

Response

Far-field reduction −10.2 dB

Detection range −68%

Thrust penalty −2.8%

Power overhead +4.2%

ISR-COVERT profile: target acoustic signature in the lower half of detectability for ground troops at standoff range. Trade-off prioritises silence over thrust margin.

VOXEL APPLICATION · USPTO FILED · Airport / naval ground systems

Active Voxelized Ground Pad Systems

Dense arrays of mechanically mobile voxels (balls, rollers, driven pads) selectively actuated in position, rotation, friction, and height. Aircraft pushback, gate alignment, apron logistics without tugs. Naval helipads with vessel motion compensation. Vertiport infrastructure.

Top-Down View — Airport Apron / Naval Helipad

Voxel grid actively coordinates aircraft motion. Arrows show actuation direction. Yellow zone = active actuation field.

Controls

Deployment Context

Operation

Voxel Activation Density 55%

Operation Metrics

Pushback speed 5.0 m/s

Position accuracy ±15 mm

Crew required 0

Power draw 38 kW

Apron mode: gate-area pushback and alignment without tug. Replaces conventional pushback tractors with no aircraft modification required. Compatible with existing landing gear.

VOXEL APPLICATION · USPTO FILED · Naval / VTOL landing

μ-Active VTOL Capture Decks & Vertiport Pads

Programmable-friction (μ-active) surfaces with sectorized friction control, flush mechanical locks, optional hexapod motion compensation. Soft-capture progresses to hard-lock with proof-of-seat. Sea-state-resilient naval VTOL operations.

Side View — Naval Capture Deck under Sea State

Helicopter approach + touch + soft-capture + hard-lock. Hexapod compensates vessel motion. Sectorized friction visible on deck.

Controls

Sea State 3

Approach Phase

APPROACH

TOUCH

SOFT

LOCK

Hexapod Compensation ON

Capture State

Stage APPROACH

μ field μLOW center / μMAX perim

Proof of seat Pending

Vessel comp Δ ±2.4° / ±0.8 m

Approach phase: deck broadcasts position and motion vector to inbound aircraft. Friction field configured for soft-capture once contact is initiated.

SoafAii Portfolio Demo

C3D Architecture

C3D in Operation

Aero-EM Surfaces

Quiet Rotors

Active Ground Pads

μ-Active Capture Decks

C3D — Multi-Scale Voxel Manufacturing OS

Select a component

C3D in Operation — Natural-Language Compilation

Reconfigurable Voxelized Aero-EM Surfaces

Voxelized Trailing-Edge Micro-Appendage Arrays

Active Voxelized Ground Pad Systems

μ-Active VTOL Capture Decks & Vertiport Pads

Welcome to the SoafAii IAI Demo

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