Learning from the LattePanda Mu Reference Board

Learn how to design a real computer with KiCad High-Speed PCB Design — a hands-on course from Tech Explorations. In this project, you’ll design a carrier board for the LattePanda Mu (Intel N100) compute module from schematic to manufactured PCB, mastering the professional techniques that make complex digital systems work reliably. This course goes beyond hobby-level design to teach the physics of high-speed signals and how to engineer your board for performance, stability, and manufacturability. You’ll work through differential pair routing, impedance control, grounding strategies, and DFM verification — all using KiCad’s advanced toolset. 💡 You’ll learn: • How to manage impedance, return paths, and signal integrity • Differential pair routing for USB 3.0 and HDMI • Layer stack-up design and controlled geometry • Power distribution and EMI management • Preparing and verifying your design for manufacturing 🎁 Launch Offer: Use coupon HIGHSPEED30 for 30 % OFF until November 10 (AEST). Prefer Udemy? The same coupon is valid there until October 31 (PDT). 👉 Learn more and enrol here → https://txplo.re/speed_pcb In this lecture, I explain the core principles of high-speed PCB design and how they differ from low-speed boards like Arduino or ESP32. You’ll learn when a trace stops behaving like a wire and becomes a transmission line, how reflections occur, and why impedance control, layer planning, and signal matching are essential for reliability. Through practical examples using USB 2.0 and USB 3.0, I demonstrate how rise time and trace length define design constraints. You’ll also discover six key principles of high-speed layout — from return paths to differential pair tuning — and how KiCad’s modern tools make these techniques accessible to all designers. KiCad, KiCad 9, high-speed PCB design, KiCad high speed, impedance control, signal integrity, differential pair routing, transmission line PCB, USB 3.0 PCB, HDMI PCB design, LattePanda Mu, LattePanda N100, PCB layout tutorial, PCB design guidelines, stack-up design, KiCad tutorial, KiCad course, PCB education, electronics engineering, PCB reflections, controlled impedance, routing strategies, power integrity, return path design, EMI reduction, Tech Explorations, Peter Dalmaris, design a computer with KiCad, learn KiCad, hardware design tutorial, high-speed design KiCad