Most imperix controllers feature 36 bidirectional 3.3V I/O lines, commonly known as USR pins. Driven directly from the FPGA, these custom-application I/Os are ideal for…
This page describes how to upgrade the imperix IP in an existing sandbox project, whether to restore compatibility with a newer SDK version or to…
Beyond the built-in modulators accessible from the user application, the imperix sandbox enables PWM generation directly within the FPGA, allowing for the implementation of custom…
Imperix provides direct access to ADC measurements within the FPGA which allows for reduced delay between the sampling and the processing, but also helps supporting…
On imperix controllers, the CPU exchanges data with the FPGA via the SBIO bus. This memory-mapped bus allows the CPU user app to read and…
This page presents a practical example of Aurora communication with Typhoon HIL simulators, specifically the HIL101, HIL404, HIL506, and HIL606. It provides a ready-to-use user…
Conventional model-based control in power electronics relies heavily on deriving precise mathematical models of the physical system. In contrast, data-driven control shifts this paradigm by…
This technical note introduces the basic principles of HIL simulation and provides practical considerations for the implementation of a controller-HIL setup using the imperix B‑Board…
This article details the underlying clock architecture and timing configurations of imperix controllers, focusing on the four internal time bases (CLK0–CLK3) that govern ADC sampling,…
This note describes the control of an adapted Siemens SINAMICS S120 active line module using the imperix B-Board PRO embedded control platform. With its low…
End of content
End of content
