Best Engineering Software for Simulink

MATLAB® offers a desktop environment specifically optimized for iterative design and analysis, paired with a programming language that allows for straightforward expression of matrix and array mathematics. It features the Live Editor, which enables users to create scripts that merge code, output, and formatted text within an interactive notebook. The toolboxes provided by MATLAB are meticulously developed, thoroughly tested, and comprehensively documented. Additionally, MATLAB applications allow users to visualize how various algorithms interact with their data. You can refine your results through repeated iterations and then easily generate a MATLAB program to replicate or automate your processes. The platform also allows for scaling analyses across clusters, GPUs, and cloud environments with minimal modifications to your existing code. There is no need to overhaul your programming practices or master complex big data techniques. You can automatically convert MATLAB algorithms into C/C++, HDL, and CUDA code, enabling execution on embedded processors or FPGA/ASIC systems. Furthermore, when used in conjunction with Simulink, MATLAB enhances the support for Model-Based Design methodologies, making it a versatile tool for engineers and researchers alike. This adaptability makes MATLAB an essential resource for tackling a wide range of computational challenges.

Simcenter Amesim, the most integrated and scalable platform for system simulation, allows system engineers to simulate and optimize mechatronic system performance. This will increase overall system engineering productivity, from the initial development stages to the final performance validation and controls calibration. Simcenter Amesim is a combination of ready-to-use multiphysics libraries and industry-oriented solutions. It supports powerful platform capabilities that allow you to quickly create models and perform analysis. This open environment can be easily integrated with major computer-aided designing (CAD), computer-aided engineering and controls software packages.

With TPT, you can test ECU software and embedded control systems in all development phases such as model-in-the-loop (MiL testing), software-in-the-loop (SiL testing), processor-in-the-loop (PiL testing), hardware-in-the-loop (HiL testing), ECU testing and vehicle testing. TPT offers unique features that allow you to create simple or complex system tests. TPT can meet safety standards up to the highest level. Relevant standards, such as ISO 26262, are well supported. TPT supports all aspects of testing, including test case design/generation and execution, reporting, and management. TPT was designed to be the best tool to test signal-oriented systems. TPT makes it easy to design test cases that are powerful, simple to use, and easy to maintain for complex systems with many interfaces.

A Digital Thread is essentially a graph consisting of nodes that represent various elements found in enterprise repositories, tools, and systems for version control, with edges denoting both intra-model relationships within each tool and inter-model connections that Syndeia facilitates between these nodes. Additionally, Syndeia offers model transformation capabilities that help construct the digital thread graph, allowing for operations such as seamlessly dragging and dropping requirements from Jama or DOORS-NG into SysML, generating Simulink models and PLM part structures derived from SysML models, linking behavior elements in SysML to corresponding software code in GitHub, and even monitoring the development progress of a sub-system in JIRA directly from SysML. Furthermore, Syndeia enhances the functionality of the digital thread by providing services for searching, comparing, and bi-directionally synchronizing interconnected models, enabling users to compare and synchronize alterations in system architecture with the PLM part structure or align changes made in DOORS-NG requirements with SysML, illustrating the comprehensive capabilities of digital thread management. Ultimately, this interconnected approach not only streamlines workflows but also ensures that all components of a project remain aligned and up-to-date across multiple platforms.

NVIDIA DRIVE® Map is an advanced mapping platform crafted to support the utmost levels of vehicle autonomy while enhancing safety measures. By merging precise ground truth mapping with the agility and scale of AI-driven fleet-sourced mapping, it achieves remarkable results. The system utilizes four distinct localization layers—camera, lidar, radar, and GNSS—ensuring the necessary redundancy and flexibility for sophisticated AI drivers. With a focus on exceptional accuracy, the ground truth map engine generates DRIVE Maps by integrating a variety of sensors, including cameras, radars, lidars, and differential GNSS/IMU, all captured through NVIDIA DRIVE Hyperion data collection vehicles. It delivers an impressive accuracy of better than 5 cm, particularly in high autonomy scenarios (L3/L4), in environments like highways and urban areas. Designed for rapid operation and global adaptability, DRIVE Map leverages both ground truth and fleet-sourced information, encapsulating the shared knowledge of millions of vehicles on the road. This innovative approach not only enhances mapping precision but also contributes to the evolving landscape of autonomous driving technology.