Structural analysis using Finite Element Method (FEM) allows engineers to predict the behavior of complex mechanical assemblies under real-life loads and conditions. This accurate computer-aided simulation reduces the product life cycle, enabling OEMs and manufacturers to deliver high-quality, reliable components and assemblies to the market.
For high-speed applications and thermal challenges, electromagnetics including signal and power integrity analyses provide detailed insights.Our simulations for SerDes technology ensure reliable performance in high-frequency environments. We optimize power delivery networks with various analyses, ensuring system reliability.
Functional Safety analysis systematically identifies, assesses, and mitigates risks in safety-critical systems. It involves hazard identification, risk assessment, and implementing safety measures to reduce accident risks. This analysis ensures systems meet required safety integrity levels (SIL) and comply with standards like ISO 26262, ARP 4761, ISO 21434, ISO 21448, IEC 61508, and MIL-STD-882E.
Our simulation suite accelerates the development of ADAS and autonomous driving technologies by offering a cost-effective alternative to physical prototypes. It enables virtual testing of radar, lidar, and camera sensors in realistic scenarios. Our Headlamp simulation validates control behavior and tests edge cases early in the design phase, while streamlining ADAS/AD system development through virtual driving tests, saving significant time and costs.
Model-Based Design & Development for Embedded Safety-Critical Applications uses graphical models to design, simulate, and verify systems in aerospace and automotive industries. Engineers create models for system architecture and requirements, generating code automatically. This method increases productivity, reduces errors, ensures ISO 26262 compliance, and enables rapid prototyping, testing, and validation for robust, efficient systems.