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EMC issues - grounding techniques and precautions for PCB engineers

Time:2023-08-06 Views:776
MC problem
    When laying the board, attention should also be paid to EMC suppression!! This is very difficult to grasp, distributed capacitors always exist!!
How to Ground
    PCB design originally involves considering many factors, and different environments require different considerations. Additionally, I am not a PCB engineer and have limited experience:)
Division and connection of ground
    Grounding is one of the important means to suppress electromagnetic interference and improve the EMC performance of electronic equipment. Proper grounding can not only improve the product‘s ability to suppress electromagnetic interference, but also reduce external EMI emissions.
The Meaning of Grounding
    The "ground" of electronic devices usually has two meanings: one is "ground" (safety ground), and the other is "system reference ground" (signal ground). Grounding refers to establishing a low resistance conductive path between the system and a potential reference plane. Grounding "refers to connecting the metal casing and circuit reference points of electronic equipment to the earth based on its potential and zero potential.
    The connection between the grounding plane and the earth is often based on the following considerations:
    A. Improve the stability of equipment circuit system operation;
    B. Electrostatic discharge;
    C. Provide safety assurance for staff.
Purpose of grounding
    A. Safety considerations, i.e. protective grounding;
    B. Provide a stable zero potential reference point (signal ground or system ground) for the signal voltage;
    C. Shield grounding.
    Basic grounding method
    There are three basic grounding methods in electronic equipment: single point grounding, multi-point grounding, and floating grounding.
PCB engineer‘s attention
Single point grounding
    Single point grounding refers to the entire system where only one physical point is defined as the grounding reference point, and all other points that require grounding are connected to this point.
    Single point grounding is suitable for circuits with lower frequencies (below 1MHz). If the working frequency of the system is so high that the working wavelength can be compared to the length of the system grounding lead, the single point grounding method is problematic. When the length of the ground wire is close to 1/4 wavelength, it is like a transmission line with a short circuit at the end. The current and voltage of the ground wire are distributed as standing waves, and the ground wire becomes a radiation antenna and cannot function as a "ground".
    In order to reduce grounding impedance and avoid radiation, the length of the ground wire should be less than 1/20 wavelength. In the processing of power circuits, single point grounding can generally be considered. For PCBs that are widely used in digital circuits, due to their rich high-order harmonics, it is generally not recommended to use a single point grounding method.
Multipoint grounding
    Multipoint grounding refers to the direct connection of each grounding point in the equipment to the nearest grounding plane, in order to minimize the length of the grounding lead.
    The multi-point grounding circuit has a simple structure and significantly reduces the high-frequency standing wave phenomenon that may occur on the grounding wire, making it suitable for occasions with high operating frequencies (>10MHZ). However, multi-point grounding may lead to the formation of many grounding loops inside the equipment, thereby reducing its resistance to external electromagnetic fields. In the case of multi-point grounding, attention should be paid to the issue of ground loops, especially when networking between different modules and equipment. Electromagnetic interference caused by ground wire circuit:
    The ideal ground wire should be a physical entity with zero potential and zero impedance. But the actual ground wire itself has both resistance and reactance components, and when a current passes through the ground wire, a voltage drop occurs. The ground wire will form a circuit with other connecting wires (signal, power line, etc.), and when the variable electromagnetic field is coupled to the circuit, an induced electromotive force is generated in the ground circuit, which is coupled to the load by the ground circuit, posing a potential EMI threat.
Floating ground
    Floating ground refers to a grounding method in which the equipment grounding system is electrically insulated from the ground.
    Due to some inherent weaknesses of floating ground, it is not suitable for general large-scale systems, and its grounding method is rarely adopted.
    General selection principles for grounding methods:
    For a given device or system, at the highest frequency of concern (corresponding to wavelength), when the length of the transmission line L>in, it is considered a high-frequency circuit, and vice versa, it is considered a low-frequency circuit. According to the Rule of thumb, it is better to use single point grounding for circuits below 1MHZ; For values above 10MHZ, it is better to use multi-point grounding. For frequencies between the two, as long as the length L of the longest transmission line is less than/20 in, a single point grounding can be used to avoid common impedance coupling.
    The general selection principles for grounding are as follows:
    (1) Low frequency circuits (<1MHZ), it is recommended to use single point grounding;
    (2) For high-frequency circuits (>10MHZ), it is recommended to use multi-point grounding;
    (3) High and low frequency hybrid circuit, hybrid grounding.

 












   
      
      
   
   


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