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With the growing demands for electromagnetic compatibility (EMC), designing printed circuit boards (PCBs) is becoming increasingly complex. Shielding is a key technique that protects electronic components from electromagnetic interference (EMI). In this article, we discuss the main challenges and best practices related to designing shielding for PCB components in terms of EMC.
The electronics market is undergoing dynamic changes, and with the increasing number of wireless devices and consumer electronics, electromagnetic compatibility (EMC) has become a critical aspect of design. Electronic devices, from smartphones to advanced medical and automotive systems, must meet strict EMC standards to ensure safe and efficient operation. The rapid development of technologies such as 5G, the Internet of Things (IoT), and wearable electronics contributes to the growing number of devices that operate at higher frequencies. This, in turn, increases susceptibility to electromagnetic interference (EMI).
In 2023, the global electromagnetic shielding market reached a value of $7 billion, highlighting the growing importance of this technology. It is estimated that by 2030, the market value will increase by another 50%, driven by the growing number of applications that require EMC compliance. Companies must invest in advanced shielding techniques to meet these demands. A lack of proper shielding can lead to device compatibility issues and negatively affect their performance and reliability.
Problems related to electromagnetic interference date back to the early use of radio technologies in the early 20th century. The first radio communication systems were particularly susceptible to interference caused by other sources of electromagnetic radiation. As electronics and telecommunications developed, engineers began to notice that these interferences could significantly impact signal quality and device reliability. Even then, the first steps were taken to protect systems from EMI, mainly through the use of proper grounding and signal isolation techniques.
In the 1970s, with the rapid growth in the number of electronic devices, the problem of electromagnetic interference became more common and serious. Companies such as Bell Laboratories began conducting intensive research on methods of protection against EMI. The introduction of the first EMC-related regulations, such as the MIL-STD-461 standards for military equipment, forced manufacturers to design devices with shielding in mind.
In the 1980s and 1990s, the development of microprocessor technologies and digital devices further increased the need for EMC compliance. More advanced techniques, such as the Faraday cage, and dedicated shielding materials began to be widely used in the industry. From that moment on, electromagnetic shielding became a standard element of electronic circuit design, especially for devices operating at high frequencies.
Today, shielding techniques and electromagnetic interference management are integral parts of the electronics industry, especially in the context of emerging 5G technologies, IoT, and the automotive industry, where autonomous and electric systems are becoming increasingly common.
With the ongoing miniaturization of electronic devices, designers face the challenge of efficiently placing components in limited space. The smaller the size of the PCB, the harder it is to maintain proper distance between interference-emitting elements and sensitive components. When designing analog, digital, and power systems, it is especially important to avoid mutual interference. Improper component placement can lead to interference, which affects device stability.
A uniform, unbroken ground plane is the foundation for designing PCBs that are resistant to electromagnetic interference. The ground plane plays a key role in absorbing conducted interference. However, designing multi-layer PCBs, especially for complex devices like cell phones or medical equipment, can lead to discontinuities in the ground plane. Vias can further introduce problems with conducted interference if they are not properly placed and grounded.
Ground loops are a common problem in multi-layer devices. They occur when different sections of the board have different ground potentials, leading to conducted interference. Signals that flow through these loops can cause interference between components. To prevent this phenomenon, designers must carefully plan grounding and signal paths to minimize the risk of such loops.
Choosing the right shielding materials plays a key role in ensuring effective protection against EMI. Materials such as copper, aluminum, and stainless steel have different conductivity and interference attenuation properties. Copper, due to its excellent conductivity, is most commonly used, especially in high-performance designs. Stainless steel, though cheaper, offers poorer interference attenuation and is used in less demanding applications. The high frequencies at which today's devices operate require the use of more advanced materials and techniques, such as multi-layer shielding coatings.
Radiated interference can penetrate key components such as microprocessors, oscillators, or radio modules. Especially in IoT devices, which often operate in high-EMI environments, it is important for designers to use proper shielding and signal isolation techniques. The high operating frequencies of such devices, reaching even tens of GHz, mean that standard shielding techniques may not be sufficient. In such cases, the use of special shielding materials and precise circuit design becomes essential.
One of the most important aspects of designing EMC-compliant PCBs is the proper separation of analog and digital signals. High-frequency digital signals can introduce interference into analog signal paths, affecting measurement accuracy and device stability. Therefore, it is recommended that, where possible, analog and digital sections be placed on different layers or physically separated on the board.
Vias are often used in multi-layer designs, but improper placement can lead to conducted interference. To avoid this, vias should not be placed near sensitive components and should be introduced symmetrically to minimize potential differences on the ground plane.
EMI-absorbing materials, such as ferrite beads and films, can significantly reduce the electromagnetic radiation generated by components. Especially in high-density devices, where space is limited, these materials can be used in places where standard shielding techniques are difficult to implement.
Low-impedance connectors, such as coaxial connectors, provide effective protection against interference. They are especially important in high-frequency connections, where even small impedance differences can lead to signal reflections and interference. Choosing the right type of connector, along with its precise placement, can significantly improve the EMC compliance of the entire system.
Designing EMC-compliant PCBs requires a comprehensive approach that considers both the selection of appropriate materials and design techniques. Miniaturization, high operating frequencies, and the complexity of modern electronic devices make EMC compliance an increasingly challenging task. Using best practices, such as shielding, proper placement of vias, and signal isolation, minimizes the risk of interference and ensures the reliability and safety of device operation.
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