In the first part of this thesis, a novel dual-band mushroom-like structure is presented. By making L-shaped notches on the patch of mushroom-like structure, the high order mode frequency can be significantly reduced and controlled. A modified triplex bi-directional ring-hybrid is realized with dual-band mushroom-like structures. The proposed circuit yields better performance, and the cost of fabrication has been greatly reduced. Furthermore, by simplifying the topology of triplex bi-directional ring-hybrid, a novel microwave circuit called triplex bi-directional T-type circuit is developed, which has the same mechanism with the original circuit. The result shows that the proposed circuit can provide larger bandwidth and lower insertion loss. A multi-band matching network is proposed in the second part of this thesis. We extend the concept of the mushroom-like structure with suspending microstrip line to the series LC resonator, and realize multi-band matching by a combination of the resonator and multi-stage single stub matching networks. To test the presented approach, a dual-band and a tri-band planar monopole are designed to be the load circuits. Following the proposed matching scheme, the load antennas achieve good return loss at their resonant frequencies.