Smart safe & connected

1

Explore multiple iterations of system architecture faster and with greater accuracy.
Reuse and integrate legacy models using the open language MODELICA and the Functional Mockup Interface (FMI) standard.
Model and converge optimal mechatronic systems, ensuring performance and compliance with requirements.
Improve product quality by capturing requirements, parameters, and test cases that can then be traced through architecture, models, and simulation results.
Verify subsystems and the entire digital vehicle early in the development cycle, saving costs and minimizing errors.
Accelerate the detection and resolution of potential system performance issues or conflicts.
Virtual detection of performance issues at an early stage, before detailed design, reduces costs for physical prototypes.

2

Enhance productivity with a model-based approach that supports the development of embedded systems for functional, software, and hardware architectures.
Explore alternatives and trade-offs to deliver new innovative features to clients faster.
Manage traceability among all artifacts of Embedded Electronic Architecture.
Increase the reuse of embedded electronic innovations in new vehicle programs.
Automate the generation of specifications from models to request information or quotes from suppliers.

3

Increase software reuse through AUTOSAR methodologies.
Enhance performance with automated models for generating AUTOSAR-compliant code.
Improve software quality through AUTOSAR compliance and testing.
Smooth integration with existing tools and processes based on the open standard ARTOP.

4

Enable system development in a configured context to enhance collaboration and improve efficiency.
Ensure that the performance of electrical systems meets customer requirements.
Explore multiple iterations of electrical systems faster and with greater accuracy.
Virtually define electrical systems and automate the physical three-dimensional design of harnesses, thereby minimizing costly harness materials and operational errors.
Accelerate the detection and resolution of potential performance issues or conflicts in electrical systems.

5

Enable system development in a configured context to enhance collaboration and increase efficiency.
Ensure that the performance of electrical systems meets customer requirements.
Explore multiple iterations of electrical systems faster and with greater accuracy.
Virtually define electrical systems and automate the physical three-dimensional design of harnesses, thereby minimizing costly harness materials and operational errors.
Accelerate the detection and resolution of potential performance issues or conflicts in electrical systems.

6

Multiphysical dynamic modeling and simulation based on the MODELICA language and libraries.
Linking modeling between multiphysical models and three-dimensional kinematics models.
Optimize product design and conduct virtual testing according to customer needs, track simulation results against initial requirements.
Rapid development of systems consisting of mechanics, embedded control software, and electronics.
Minimize development costs and efforts by reusing system models.
Ensure compliance with market and regulatory requirements through a structured approach to model-based system design.
Open solution using MODELICA, FMI (Functional Mockup Interface), and connectors for Simulation and Tests with external tools and applications.

7

Minimize the risk of warranty costs, recalls, and corporate liabilities.
Provide industry-validated resources to ensure compliance with ISO 26262 safety requirements.
Automate reporting capabilities to meet functional safety standards/certifications and adhere to critical deadlines.
Compliance with global/local industry standards, from requirements to final product verification, ensuring comprehensive adherence to functional safety requirements.
Utilize built-in tracking capabilities to ensure accountability.