[Whitepaper] ASTERIOS®: The Software Development Platform for the Automotive Transformation

Turning points in the car industry The next few decades will likely see the rise of EVs and autonomous vehicles and a diminishing of traditional internal combustion engines in modern transportation systems. This growing EV market is creating opportunities for new business models, while opening the door to new entrants into automotive, rewriting the auto […]

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[Whitepaper] Reaching Higher Productivity Levels with KRONO-SAFE’s LET Based ASTERIOS® Platform

A turning point in realtime embedded systems engineering The evolution of the industry toward Cyber Systems – critically shaping our lives and businesses – calls for an evolution of real-time software development practices. To tackle a growing software complexity and meet the productivity challenge, companies developing real-time embedded systems are being confronted to a massive […]

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[Blog] Four reasons why current software development methodologies and tools are facing their limits in the safety and multi-core fastest growing segments of the embedded systems market

Blog - four reasons why

Real-time embedded systems are found in every innovative industry like aerospace, automotive, industrial, rail transportation, and medical devices. Breakthroughs in artificial intelligence (AI), industrial IoT (IIoT), autonomous transportation, robotics and smart automation are driving exponential growth in the number and complexity of real-time embedded systems. For example, an S-class Mercedes now runs with 20 million […]

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[Video blog] SAFRAN & KRONO-SAFE webinar about Safety on Multicore now available online!


Les architectures multicoeurs sont désormais présentes dans tous les systèmes, et pourtant, elles demeurent un véritable défi pour les développeurs lorsqu’il s’agit de mettre en oeuvre des applications industrielles critiques en matière de sûreté de fonctionnement. En cause, le calcul parallèle tel qu’il est réalisable avec les systèmes multicoeurs augmente inéluctablement le nombre d’interférences et d’asynchronismes possibles, rendant ainsi […]

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[Blog] How to ensure tasks’ timing properties: ASTERIOS vs POSIX-like RTOS


Previous blog posts introduced the principles behind the PsyC programming language and most of those behind the execution runtime used by ASTERIOS RTK. Here are these principles with a link to each dedicated blog post: Time-triggered design approach Multi-task, parallel synchronous programming model named Psy with a programming language based on C that conforms to […]

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[Blog] Demystifying the PsyC language


So, you’ve heard about our technology called ASTERIOS®, and you’ve heard that it can « generate an optimal real-time scheduling in a few minutes, target a multi-core platform as easily as a single CPU, guarantee the determinism by construction, provide strong safety and security evidence by calculation and validate the temporal behavior of your system by […]

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[Blog] Settling the Time- vs. Event-Triggered Debate


In a previous blog post, we briefly came across the differences between Event- and Time-Triggered approaches when it comes to real-time systems design. In this post, we want to focus more extensively on the differences between these approaches, and explain why the time-triggered paradigm (which is the foundation of the ASTERIOS technology) is better suited to design complex, safety-critical […]

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[video blog] ANSYS & KRONO-SAFE webinar recording now available!

Ansys Krono FLOW

Les applications embarquées deviennent de plus en plus complexes. Lorsqu’elles sont de haute criticité, il faut démontrer qu’elles respectent l’ensemble des exigences temps-réels et fonctionnelles. Les approches basées sur les modèles (MBSE, Model-Based System Engineering), accompagnées de la génération automatique et certifiée de code, permettent déjà de répondre en partie à cette problématique. Cependant, dans […]

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