News & Updates

SMD components require precisely sized pads for soldering during assembly. The designer is responsible for ensuring pad sizes are correct, either by calculating them and comparing with footprint data, looking through datasheets, or by memorizing SMD pad size standards. If you have a component and you don't have access to the footprint, and you decide to biuld the footprint yourself, what resources are available to ensure you have the correct pad size?

Before we get too deep into this article, I’ll give you the simple answer. You probably can’t fix warping in your PCB after it’s already been fabricated. You can prevent an unwarped board from becoming warped during assembly, but only as long as materials were selected properly and the board is put into reflow correctly. We’ll run over some of these points in this article, and I’ll examine some points that might help you recover a warped board.

The eye diagram is a useful measurement or simulation as part of channel compliance. The measurement shows many different factors that can affect signal behavior simultaneously, ultimately allowing for qualification of errors and losses in a channel. In this article, I’ll run over some of the fundamental measurements that you could manually extract from an eye diagram and how they reveal some strategies for improving channel designs.

This track is for the designer who is new to high-speed layout and routing practices and wants to understand how they relate to signal integrity, and how to get started designing for high-speed digital applications.

To readers who have been working in the PCB industry for most of your career, you have probably seen a very diverse group of professionals with varied skill sets and backgrounds. Designers might get started as engineers or as technicians, and some designers learn how to create beautiful PCB layouts in university. No matter how you got into PCB design, there are some important skills to know that will take you a long way towards advancing your career.

When starting out with PCB design, it’s common to treat the process as simply ‘connecting the dots’: as long as connections are made, it’s not particularly important how these connections are made. Having reviewed quite a number of PCBs of other PCB design engineers over the last few years, there are common, unfortunately erroneous, occurrences between a lot of them. This article aims to illustrate the top five beginner PCB design mistakes and what we can do to avoid making them. Let’s get started!

As the PCB design community embraces the benefits of this new printed circuit board fabrication technique, there are of course many questions to be answered. Today’s blog will address some of the most commonly asked questions related to circuit layer stack up as people are introduced to this new technology.

SPICE simulation saves you critical time in the prototyping phase. Understanding your simulation interface makes it simple to analyze how your circuits work in different scenarios. Altium Designer provides an intuitive, dedicated interface to support your simulation verification, setup, and analysis directly in your schematic environment. You also benefit from growing support for popular model formats, as well as generic models, simplifying circuit definition and simulation.

We are happy to announce that the Altium Designer 22.9 update is now available. Altium Designer 22.9 continues to focus on improving the user experience, as well as performance and stability of the software, based on feedback from our users. Check out the key new features in the What's New section on the left side of this window!

The highest performing operational amplifiers often need a split supply with positive and negative voltages connected to the op amps supply rails. In this project, we’re going to be building a positive/negative dual rail power supply for a differential oscilloscope probe I’m designing. I’m making the power supply a separate project, as a dual rail supply is quite useful to have, and I’m sure I’ll find multiple uses for it in the future.

Importing file-based libraries from your local computer or network drive to your Altium 365 workspace can be done using the Library Importer. Altium’s Library Migrator was renamed Library Importer—the feature’s name was changed to conform more closely to the tool’s purpose. Not only is its name new, but our team has also made several user experience improvements. We have updated the documentation to reflect this change.

The PCB materials industry has spent significant amounts of time developing materials that provide lowest possible signal loss for products with RF applications. For high speed and high frequency designs, losses will limit signal propagation distance and distort signals, and it will create an impedance deviation that can be seen in TDR measurements. In this article, we'll look at the balance between copper foil losses and other types of losses in a PCB, as well as some strategies that are commonly used to overcome roughness.

We are happy to announce that the Altium Designer 22.8 update is now available. Altium Designer 22.8 continues to focus on improving the user experience, as well as performance and stability of the software, based on feedback from our users. Check out the key new features in the What's New section on the left side of this window!

Discover how modern wire harness engineering is evolving to meet the growing complexity of electrified systems. This whitepaper explores best practices, intelligent automation, and ECAD-MCAD collaboration to improve efficiency and reduce errors. Download now to stay ahead in an increasingly connected world.

Ultra-HDI technology is transforming RF design by enabling finer line widths, improved signal integrity, and more compact, high-performance boards. Our brand-new article explores its advantages over traditional methods and the benefits of integrating flexible circuits.

Testpoints are essential for efficient PCBA testing and debugging. Our latest whitepaper dives into testpoint optimization, fault detection, and automated testing strategies, along with a full tutorial on using Testpoint Manager in Altium Designer. Discover how to streamline your testpoint assignments and improve measurement accuracy!

Krishna Sundaram explores the hidden challenges of cable harness design, from routing complexity to mechanical constraints and manufacturability. Learn how to design a robust and efficient harness.

Ultra-HDI technology is transforming PCB design, enabling unprecedented miniaturization and performance. In this article, explore what sets Ultra-HDI apart from traditional HDI and how it’s shaping the future of electronics.

This article addresses common misconceptions about cloud security in PCB design. It explains how modern cloud platforms, such as Altium 365, often provide superior security compared to traditional on-premises solutions. Key features like advanced infrastructure, granular access controls, and compliance with stringent regulations ensure the protection of valuable design data.

Last week, Renesas Electronics and Altium proudly announced the introduction of Renesas 365, Powered by Altium—a first-of-its-kind industry solution designed to streamline electronic system development, from silicon selection to system lifecycle management. Renesas 365 will be demonstrated at Embedded World, Booth 5-371, from March 11-13 in Nuremberg, Germany.

Learn how integrating DFM and DFA principles into systems engineering ensures manufacturable, cost-effective PCB designs by optimizing CAD, CAM, and requirements management in our new article by Javier Alcina.

Crosstalk control is essential for better EMI performance. Learn effective design techniques to reduce interference in the final installment of this series by Dario Fresu.

Part 2 of this series covers essential project management techniques for electronics design teams. Rafał Stępień discusses effective data organization, revision control, and collaboration strategies to improve efficiency and minimize errors.

Read our new article which discusses the advantages of rigid-flex PCBs, such as space-saving designs and enhanced reliability, while also addressing potential challenges in their fabrication. It provides essential design and manufacturing tips to help engineers effectively implement this technology in various applications.

Our new article highlights how automation and robotics are transforming wire harness assembly, improving efficiency, precision, and cost-effectiveness. Technologies like robotic wire handling and AI-driven testing are paving the way for smarter production. However, challenges like custom designs and high costs still persist.

Check out the first part of "Best Practices for Electronics Project Management" by Rafał Stępień. It offers valuable advice on enhancing team communication and documentation in hardware design projects.

Wiring harnesses are mission-critical in space systems, requiring strict adherence to ECSS-Q-ST-70-61C and NASA-STD-8739.4A. In "Wiring for the Final Frontier: A Guide to Space-Grade Harness Design", Kamil Jasiński explores key design principles, material selection, and testing to ensure reliability in extreme environments.

Discover how wire harnesses are evolving to meet the demands of electric vehicles and modern electronics. Our latest article explores key trends like higher voltages, lightweight designs, and smart harnesses, along with challenges such as cost and supply chain issues.

Dario Fresu explores effective decoupling strategies for power distribution networks (PDNs) to minimize EMI in PCB designs. The article covers techniques like decoupling capacitors and power planes to ensure stable power delivery for integrated circuits.