Taconic Advanced Dielectric Division-Fachartikel für HF- und Mikrowellen Laminate Abstract019



	Effects of Surface Finish on HF Signal Loss Using Various Substrate Materials The amount of information transferred on wireless networks has increased dramatically with the tremendous growth of mobile phones, Internet access, and hand held devices. In order to build the infrastructure needed to handle ever-increasing data transfer, manufacturers of electronic devices turn to high speed, high frequency electronic signals. The need to render these electronic devices portable is another technology driver. The merge of high-frequency signals with small geometry conductive traces means that the topic of signal loss has reached a critical point in existing device production. The integrity of a high-frequency signal can be affected by several factors during Printed Circuit Board (PCB) construction. The geometry of the conductor, the type of metallization used in/on the conductor, the signal frequency, the temperature of the substrate, and the type of dielectric material insulating the conductor all play an important role. Representatives of material supply, board fabrication, and chemical process supply commenced a project to study some of the influential factors in more detail. A primary variable was the type of metallization used on the circuit board surface. Organic solderability preservative (OSP), hot air solder leveling (HASL), electroless nickel immersion gold (ENIG), and immersion silver were studied as PCB surface finish alternatives. Substrates under investigation included woven glass PTFE, ceramic-filled woven glass PTFE, and FR4 epoxy as a control. Specifically designed microstrip circuits were tested within a frequency range of 60 MHz to 26.0 GHz for signal loss across a range of PCB operating temperatures. At this stage, data was used to 10.0 GHz. Continuing studies will inspect data to 40 GHz. The results from the investigation allow prediction of signal loss characteristics across a broad frequency range when parts are re-designed to use alternative Pb-free surface finishes on PTFE substrates. Back Download PDF