The research topics in this dissertation are divided into two parts; one is microwave filter design, the other is Marchand Balun design. The first topic is to utilize quarter-wave stepped impedance resonator to design high performance filter, study how to quickly design cross-coupled filters, and develop novel coupling schemes. In this dissertation, quarter-wave stepped impedance resonators are utilized to realize quadruplet and canonical-form coupling schemes. The proposed filter is easy to apply and control the source-load cross coupling. General speaking, most of the filter designs are to use coupling coefficients and external quality factor to design cross-coupled filters. Once the physical layout of the resonator is decided, the extracted coupling coefficients can be only used at the center frequency. Furthermore, if one coupling coefficient in the coupling matrix changes sign for shifting the transmission zero from one side of the passband to the other, the physical layout must be reconfigured. The initial design of cross-coupled filters based on segmentation method is not good enough, so tuning of filter performances must spend much time. This dissertation presents new cross-coupled filters based on a conventional parallel-coupled filter. The proposed filters have the advantages of the ability to locate a transmission zero on the lower or upper stopband and a good initial design. Additionally, the novel coupling schemes are presented to exhibit bisymmetric coupling matrix. The novel coupling schemes provide the implementations of symmetric layouts to realize asymmetric filter responses. Using the novel coupling schemes implementation of generalized Chebyshev filters with transmission zeros very close to the passband can be easily realized in planar technology. The second topic is to describe the synthesis method of the networks which are composed of the distributed transmission line circuits. The synthesis method is exact at all frequencies. Richards variable, transmission line networks, Richards theorem, kuroda identities and transmission line approximating functions are discussed in detailed. In addition, high-order wideband Marchand baluns are presented in this dissertation and the exact synthesis of the proposed Marchand baluns with Chebyshev responses are introduced. The proposed high-order Marchand baluns are suitable to design wideband responses.