Power Delivery Network Analysis Without the Spreadsheet
Overview
Designing modern power delivery networks (PDNs) for consumer electronics often involves managing numerous power supplies and loads. Traditionally, engineers rely on complex, hard-to-maintain Excel spreadsheets or specialized steady-state tools for initial design and analysis. However, these methods can be cumbersome and limit your ability to dynamically simulate real-world scenarios. This can lead to a slow design process, overly conservative designs, and unexpected failure/overload scenarios.
Join us to discover how MATLAB/Simulink streamlines PDN design with a flexible, graphical workflow. Learn how you can quickly set up and configure detailed models, perform both steady-state and dynamic analyses, and easily control the fidelity of your simulations. Behavioral models allow fine tuning of simulation accuracy from simple data sheet representations to matching measured data. Automate analysis and verification of the design over multiple operating/loading conditions. Go beyond traditional approaches by simulating dynamic load behaviors, fault injection, and power supply startup—all within a single environment. Additionally, automatic reporting capabilities will allow you to translate your results into consumable/shareable formats that your team is already comfortable with.
Highlights
- Quickly model complex networks of power supplies for fast dynamic and steady results for power delivery network design
- Batch out numerous power scenarios with parallel toolbox and get automatic reports on pass/fail conditions
- Generate results to excel to integrate with existing design workflows
Please allow approximately 45 minutes to attend the presentation and Q&A session. We will be recording this webinar, so if you can't make it for the live broadcast, register and we will send you a link to watch it on-demand.
About the Presenter
Joel Van Sickel, Principal Application Engineer at MathWorks, specializes in Simscape Electrical, focusing on power electronics and real-time testing. He earned a Ph.D. in Electrical Engineering from Pennsylvania State University in 2010. He previously worked as a hardware design engineer at Raytheon designing power systems and power supplies for radar systems.
