The PCB design industry is one of the world’s leading industries. As the world develops, the importance of the PCB industry seems likely to continue to grow for the foreseeable future. Learning how to manage and track the heat of PCBs is essential to gaining widespread potential in related markets and achieving high-temperature PCBs
A printed circuit board, commonly known as a PCB, is an assembly that uses copper conductors and electricity to create electrical connections between electrical components. PCB manufacturers use a substrate to make it, which houses the components that form the basis of the PCB. PCBs are made of a variety of substrate materials, depending on the requirements of the circuit.
PCB boards are made of a variety of materials that can be used for high-frequency and high-speed applications: hydrocarbon resins, PTFE, LCP (liquid crystal polymer), PPE/PPO etc.
In the modern industrial system, printed circuit boards (PCBs) are the cornerstone of electronic products. From simple household appliances to complex aerospace equipment, PCBs are everywhere, assuming functions such as connection, support, and integrated circuits.
RF (Radio Frequency) PCB design is often described as a “black art” because there are still many uncertainties in theory, but this view is only partially correct. There are also many rules and regulations that can be followed in RF PCB design and should not be ignored
As electronic products become more advanced, they encounter more sources of electromagnetic interference (EMI) that can disrupt device function and potentially harm health. This guide explores strategies for designing PCB boards with optimized electromagnetic compatibility (EMC), focusing on reducing interference and increasing product resilience.
With the development of high-frequency electronic technology, high-frequency PCB boards are increasingly widely used in various electronic systems. Recognizing the importance of high-frequency PCB boards, understanding their characteristics, and paying attention to their application areas are important directions for current scientific and technological innovation and research and development