ABSTRACT The goal of this thesis is to solve the crosstalk issue dominated by inductive coupling. Two methods are proposed. The first is to suppress the noise coupling through power lines from the source. An interleaved power line structure is proposed to replace the traditional power line. Compared with the traditional suppression methods, it does not need to occupy additional space and thus particularly suitable for products with small size, fewer layers and dense layouts. In packaging systems with a ground plane, the interleaved power line can achieve 20dB improvement in noise suppression, which is also verified by the experiment. In packaging systems without ground plane layer, the interleaved power line can provide up to 12 dB noise suppression improvement for thick layers. Two kinds of doubly interleaved power line structures are thus proposed to provide good suppression performance in both thicker and thinner substrates, respectively. The second method is to suppress the noise from DC supply end of the RF circuit on the victim side. A T-type filter circuit with small occupied space is proposed. The performance in suppressing S21 is -20dB at 2~6GHz. Design formula is also derived so that the insertion loss in the stopband can be designed by changing the capacitance value while keeping the resonance frequency fixed. Finally, after co-simulation with LNA, the noise from the power supply, with Vn = 1~1000nV, is considered and the proposed filter can successfully suppress NF of the LNA below 3dB. As compared with the conventional methods such as direct inductor and EBG, the proposed filter can yield better performance, including small size and good suppression ability. Index terms – electromagnetic band gap, RF de-sense, electromagnetic interference (EMI), radio-frequency interference (RFI), interleaved power line