MOQ: | 1 |
Price: | USD70~150 |
Standard Packaging: | KK carton (hard card) |
Delivery Period: | 2-3 working days |
Payment Method: | T/T/Paypal |
Supply Capacity: | 45000 pieces per month |
High-Frequency PCB for Demanding Applications
When it comes to high-frequency PCB design, precision and attention to detail are critical. The right choice of materials, stackup, and manufacturing processes can make all the difference in maintaining signal integrity and achieving optimal performance. The PCB being described in this article is an example of a high-quality design that meets the demands of demanding applications.
The board is made from Rogers RO3010 ceramic-filled PTFE composites, which are known for their low dielectric constant and loss tangent. This makes them an excellent choice for applications requiring high-speed data transmission, as signal distortion and delay can be minimized. The use of ceramic-filled material also provides good thermal stability and mechanical strength, which is important for maintaining the board's integrity over time.
The stackup of the board consists of two layers of copper with a thick layer of RO3010 dielectric material in between. This provides good impedance control for high-frequency signals, as the thickness and dielectric constant of the material can be precisely controlled to meet required specifications. The use of a lead-free process ensures that the board meets environmental regulations and is safe for use in a variety of applications.
The construction details of the board are also worth noting. The board has a small size of 100.00mm x 100.00mm, with a finished board thickness of 1.35mm and a finished Cu weight of 1 oz (1.4 mils) all layers. Despite its small size, the board has a high density of components and pads, with a minimum trace/space of 7/8 mils and a minimum hole size of 0.25mm. High-precision manufacturing processes are required to ensure that the design is properly fabricated and meets the required specifications.
The board is finished with ENIG (Electroless Nickel Immersion Gold), a surface finish that provides good conductivity and corrosion resistance. The use of nickel in the finish can have negative effects on RF performance, but these losses can be mitigated by the gold layer, which provides a non-magnetic material with good conductivity. The effectiveness of the gold layer in reducing losses can be impacted by its thickness and quality, but high-quality materials and processes can ensure that the finish meets required specifications.
One area of potential concern for the board is the lack of impedance matching, which can lead to signal reflections and degradation of signal quality. It's important to consider whether impedance matching is necessary for the specific application and to consult with a PCB engineer if unsure. Additionally, the lack of silkscreen and solder mask may make assembly and inspection processes more challenging, but these features may not be necessary for all applications.
In summary, the PCB described in this article is a high-quality design that meets the demands of demanding applications. Its use of Rogers RO3010 ceramic-filled PTFE composites, a precise stackup, and high-quality manufacturing processes help ensure optimal performance and signal integrity. While there are some potential areas of concern, these can be addressed through careful consideration of the specific application and consultation with a PCB engineer.
MOQ: | 1 |
Price: | USD70~150 |
Standard Packaging: | KK carton (hard card) |
Delivery Period: | 2-3 working days |
Payment Method: | T/T/Paypal |
Supply Capacity: | 45000 pieces per month |
High-Frequency PCB for Demanding Applications
When it comes to high-frequency PCB design, precision and attention to detail are critical. The right choice of materials, stackup, and manufacturing processes can make all the difference in maintaining signal integrity and achieving optimal performance. The PCB being described in this article is an example of a high-quality design that meets the demands of demanding applications.
The board is made from Rogers RO3010 ceramic-filled PTFE composites, which are known for their low dielectric constant and loss tangent. This makes them an excellent choice for applications requiring high-speed data transmission, as signal distortion and delay can be minimized. The use of ceramic-filled material also provides good thermal stability and mechanical strength, which is important for maintaining the board's integrity over time.
The stackup of the board consists of two layers of copper with a thick layer of RO3010 dielectric material in between. This provides good impedance control for high-frequency signals, as the thickness and dielectric constant of the material can be precisely controlled to meet required specifications. The use of a lead-free process ensures that the board meets environmental regulations and is safe for use in a variety of applications.
The construction details of the board are also worth noting. The board has a small size of 100.00mm x 100.00mm, with a finished board thickness of 1.35mm and a finished Cu weight of 1 oz (1.4 mils) all layers. Despite its small size, the board has a high density of components and pads, with a minimum trace/space of 7/8 mils and a minimum hole size of 0.25mm. High-precision manufacturing processes are required to ensure that the design is properly fabricated and meets the required specifications.
The board is finished with ENIG (Electroless Nickel Immersion Gold), a surface finish that provides good conductivity and corrosion resistance. The use of nickel in the finish can have negative effects on RF performance, but these losses can be mitigated by the gold layer, which provides a non-magnetic material with good conductivity. The effectiveness of the gold layer in reducing losses can be impacted by its thickness and quality, but high-quality materials and processes can ensure that the finish meets required specifications.
One area of potential concern for the board is the lack of impedance matching, which can lead to signal reflections and degradation of signal quality. It's important to consider whether impedance matching is necessary for the specific application and to consult with a PCB engineer if unsure. Additionally, the lack of silkscreen and solder mask may make assembly and inspection processes more challenging, but these features may not be necessary for all applications.
In summary, the PCB described in this article is a high-quality design that meets the demands of demanding applications. Its use of Rogers RO3010 ceramic-filled PTFE composites, a precise stackup, and high-quality manufacturing processes help ensure optimal performance and signal integrity. While there are some potential areas of concern, these can be addressed through careful consideration of the specific application and consultation with a PCB engineer.