Connected vehicles offer a range of benefits, such as real-time data sharing, app-to-car connectivity, advanced driver assistance systems (ADAS), and critical safety features like location tracking, remote parking, and in-vehicle infotainment systems (IVIs). These advancements aim to enhance the overall driving and riding experience. However, it is crucial to acknowledge that equipping vehicles with smart features also exposes them to potential cyberattacks. These attacks can result in customer data leakage or even compromise critical safety functionalities.

It’s expected to discover vulnerabilities after the product is released, which could have been easily prevented. For instance, as reported by Bloomberg, a recent increase in car thefts was attributed to the absence of anti-theft computer chips in vehicle critical systems. Therefore, it is imperative to proactively consider and address potential attack vectors right from the initial stages of development. This cybersecurity vulnerability applies to many other industrial applications, such as industrial IoT, SmartCity, and digital healthcare, where every device or system is connected, and every connection is a vulnerability.

Design for security is becoming mainstream and should be part of today’s standard design methodologies.

What you will learn:

1. Why a model-based and system-oriented solution is needed for automotive cybersecurity

2. How to quickly identify threat scenarios

3. Why a pre-silicon security verification flow is essential for secure ICs

4. Using AI to mitigate side-channel vulnerabilities

Who should attend this presentation:

This webinar is valuable to anyone who works with product design, connectivity and security.

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The shift toward the electrification of vehicles and the expansion of the electrical grid for renewable energy integration has led to a considerable increase in the demand for power electronics devices and modernized cable systems — applications that will help ensure a consistent and long-term electricity supply. Simulation is used to drive the design of new power electronics devices (such as solar power and wind turbine systems), which are required to operate efficiently for varying levels of power production and power consumption (in the case of electric vehicles). A multiphysics modeling and simulation approach plays a critical role in meeting design goals and reducing the overall production time.

The COMSOL Multiphysics® software offers a wide range of capabilities for the modeling of energy transmission and power electronics, including quasistatic and time-harmonic electromagnetic fields. Additionally, the COMSOL® software features unique capabilities for coupling thermal and structural effects with electromagnetic fields. Effects such as induction heating and Joule heating, as well as structural stresses and strains caused by thermal expansion, can be studied with user-friendly modeling features.

In this webinar, we will provide an overview of the modeling and simulation functionality in the COMSOL® software for the design of high-power cables and devices for power electronics.

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As wireless systems become complex and reach for more spectrum, RF engineers must rely on high-fidelity simulation solutions to model and test their proposed new networks effectively.

We offer tools to address these challenges and enable network architects and mission planners to digitally model and simulate dynamic wireless networks within an accurate systems simulation environment. Leveraging solutions for electromagnetic wave propagation, electronically steered antenna design tools, and a digital mission simulation, engineers can rapidly deploy models and execute them within a high-fidelity, physics-accurate digital testing environment. Engineers will understand the impacts of terrain, urban landscapes, and the dynamic kinematic motions across any number of simulated scenarios needed to test anticipated wireless network performance against design requirements thoroughly.

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Ansys is combining these industry-leading modeling and simulation tools to provide a workflow-driven solution to these unique needs and challenges. Join us to learn more about the new Ansys RF Channel Modeler and how it can help you and your organization leverage digital modeling and simulation tools like never before.

What you will learn:

• How high-fidelity simulation solutions effectively model and test proposed new networks
• How to enable network architects and mission planners to digitally model and simulate dynamic wireless networks within an accurate systems simulation environment
• How the impacts of terrain, urban landscapes, and the dynamic kinematic motions across any number of simulated scenarios are needed to test anticipated wireless network performance against design requirements

To reduce global warming and the associated effects, the transportation and energy sectors are adopting measures to make different applications potentially fossil free. This has led to a surge in demand for electric machines and the related design and development efforts. The designs of these electrical machines need to meet various specifications, including efficiency and power density requirements. A multiphysics-based simulation and modeling approach plays a critical role in accomplishing the design needs and significantly reducing the lead time to market.

The COMSOL Multiphysics software and its add-on modules provide the capability needed to model the multiphysics phenomena involved in electrical motors, including electromagnetics, thermal, structural mechanics, and fluid flow. The most common motor types, synchronous permanent magnet and asynchronous motors, as well as more recently researched alternatives such as synchronous reluctance or axial flux motors, can be modeled and optimized in COMSOL Multiphysics®. In this webinar, we will demonstrate the capabilities of the software for electrical motor modeling and the optimization techniques available for accelerating product development time.

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Join us for an insightful webinar on high-speed data acquisition in the context of Distributed Fiber Optic Sensing (DFOS) and learn more about the critical role that high-performance digitizers play in maximizing the potential of DFOS across diverse applications. The webinar is co-hosted by Professor Aldo Minardo, University of Campania Luigi Vanvitelli, who will speak about his phi-OTDR DAS system based on Teledyne SP Device’s 14-bit ADQ7DC digitizer.

Register now for this free webinar!