VisualSim for Defense & Aerospace System Design

Start a conversation

VisualSim Architect enables defense and aerospace engineers to design, validate, and optimize mission-critical systems such as launch vehicles, satellites, aircraft, UAVs, ships, submarines, tanks, and ground communication systems.

Unlike requirements and UML tools (MagicDraw, DOORS) or code-generation and functional algorithm simulators (MATLAB, Keysight ADS, HFSS), VisualSim connects Model Based Systems Engineering (MBSE) architecture exploration with system-level simulation to explore the entire Cyber Physical system.

Engineers can:

Integrate payloads, avionics, control systems, communications, sensors, and power in one model.
Evaluate performance, power, RF resilience, and reliability early in the lifecycle.
Run trade-off studies to optimize architectures before hardware is built.
Reuse encrypted models as integration test benches and reference designs.

What VisualSim Models

Payloads & Sensors
Imaging (EO/IR, SAR), sonar, radar, onboard processing.

Avionics & Control
Flight computers, display autopilot, targeting, navigation.

Communications
SATCOM, tactical radios, mesh networks, jamming resilience.

Electronic Warfare
Jammers, decoys, ECCM, RF front-ends.

Power Systems
Batteries, solar arrays, fuel cells, thermal systems.

Environment
Terrain, atmosphere, and mobility effects.

Applications Across Defense & Aerospace

Space System

Launch vehicle, avionics, telemetry; satellite payloads, TT&C, inter-satellite links; EO/IR and SAR imaging.

Air Systems

Avionics and flight control, UAV autonomy and swarms, EW aircraft with RF jamming and spectrum monitoring.

Naval Systems

Ship/submarine control, secure comms, sonar/radar; naval EW systems with decoys and anti-jam strategies.

Ground Systems

Vehicle navigation and targeting, tactical networking, mobile command centers, battlefield communication.

Start a conversation

Key Advantages Over Other Tools

End-to-End Simulation – From control logic to RF waveforms in one environment.
Test Bench Reuse – Same model supports integration testing and validation.
Encrypted Sharing – Protects IP while enabling OEM and partner collaboration.
Bridges MBSE and Simulation – Combines architecture design with quantitative results.
Multi-Domain Trade-Offs – Explore avionics, comms, power, and EW interactions before prototyping.

Metrics You Can Analyze

RF & Signal – SNR, SJR, BER, waveform fidelity, link margin.
Control & Performance – Latency, stability, tracking accuracy.
Networking – Throughput, QoS, packet loss, multipath delay.
Power – Mission-phase power budgets, amplifier efficiency, margin analysis.
Reliability – MTBF, dynamic failure, degraded-mode analysis, mission survival probability.

Success Stories

Defense Satellite Program
Increased bandwidth by 25%, extended range by 15%.

UAV Fleet Deployment
Reduced comms latency by 40%.

Naval Upgrade
Saved $2M by resolving cabling and antenna placement issues.

Use Cases

Optimize satellite communications under jamming with modulation and coding strategies.

Model UAV swarm coordination to minimize latency and maximize throughput.

Design shipboard EW systems for anti-jam resilience.

Simulate launch vehicle avionics with integrated payload downlink.

Build battlefield networks for resilient, multi-path tactical comms.