When the simulation is complete, signals from the Saber side can be analyzed in the Saber environment, and signals from the Simulink side can be analyzed in the Simulink environment. The co-simulation interface is automatically started when the Saber simulator is invoked. Saber is the master simulator and controls the entire co-simulation process. The link between the two simulators is represented by a symbol in each environment's design editor. Simulink is used to design the system control algorithms, while Saber is used to design and model the system hardware.
SABER SYNOPSYS SOFTWARE
This interface allows hardware and software design teams to work in parallel on the same project, thereby increasing design throughput and efficiency. The Saber environment's integration with The MathWorks tools includes a co-simulation interface with the Simulink environment. Applications where Saber is successfully used include motor driver, power conversion, in-vehicle networking, ground-based and airborne x-by-wire control, power net management, and engine regulation. Users can create designs, generate simulation models, analyze system performance, review performance sensitivities, study component stresses, and investigate failure modes. The Saber environment is routinely used for system design and analysis in the automotive, aerospace and power industries. Matlab) as an alternative, for implementing the post-processing functionalities above reported (i.e.Saber™ is a multi-domain, mixed-signal simulation environment well-suited for designing and analyzing complex mechatronic systems.
![saber synopsys saber synopsys](https://www.jmag-international.com/jp/wp-content/uploads/sites/5/partners/synopsys.gif)
The devoted software uses specific AIM language scripts, or an external mathematical calculation environment (e.g.
![saber synopsys saber synopsys](https://slideplayer.com/7/1716191/big_thumb.jpg)
![saber synopsys saber synopsys](http://www.sd173.com/uploads/allimg/210319/2-210319101J3156.png)
SABER SYNOPSYS FULL
The software is implemented as standalone, however requiring the presence of both the Saber schemes and a full Saber package installed on the target machine, but hiding to the user the complexity of the Saber environment. About testing process, a set of devoted criteria is derived, mainly referring to required stability, power quality, reliability and failure mode behavior.Ģ) an user-friendly software is implemented in order to interface with the Saber models and perform the required tests. The ENAM is equipped with a high-level supervisory control scheme, for power management and failure reaction.
SABER SYNOPSYS CODE
Successively, such model is translated into an electrical scheme adopting Saber standard library elements where possible, or user-defined components implemented in MAST code as an alternative. Starting from the literature regarding electrical equipment modeling, first a mathematical model is derived for the SABER models, considering also those that will not be provided in input by the Topic Manager. The project is based on the following keypoints:ġ) a detailed Saber model for the ENAM is implemented in order to perform short transient analyses. The model will be used for the analysis of power quality, stability, failure mode and reliability of different configurations for the Electrical Test Bench (ETB).
![saber synopsys saber synopsys](https://reader025.staticloud.net/reader025/reader/2021043020/5877aa2a1a28ab826e8b6b07/html/bg2.png)
The main objective of MAS DE NADA is the development of an Electrical Network Analysis Model (ENAM) in Saber simulation environment and at behavioral modeling level. MAS DE NADA (Modeling and Advanced Software Development for Electrical Networks in Aeronautical Domain Analysis)Ĭonsortium: Second University of Naples (coordinator) – Aeromechs