The goal of this thesis is to design a compact fully planar antenna that satisfies the ultra wide band (UWB) (3.1GHz~10.6GHz) released by the Federal Communication Committee (FCC). The applicatons of planar UWB monopole antennas are limited due to the non-isotropic property of the H-plane radiation patterns. This research starts with the investigation of the characteristics for a simple square monopole antenna of the planar type, by which the concept of introducing certain parallel capacitance to achieve broadband matching is obtained. Two techniques are proposed to realized the compact design of the planar UWB monopole antennas and to improve the isotropic characteristics of the H-plane radiation patterns. One technique is to design the gap shape between the monopole and the ground plane to achieve for broadband matching, in addition, a triangular shape for the monopole is employed to improve the isotropic characteristics of the H-plane radiation pattern. The other is to utilize a meander monopole in a multi-layered printed circuit board environment to achieve the goals of the broadband matching and miniaturization, simultaneously. Meanwhile, the characteristics of the H-plane radiation patterns are improved at the same time. Three designs are tested in this research, it is found that, after optimization, the patch widths are all less than 10mm, and the ground widths are all about 20mm. The overall sizes of the new structures are much smaller than that of the simple square monopole antenna. Finally the antenna prototypes are fabricated and the antenna characteristics are measured in both the time domain and the frequency domain. The antenna characteristics measured includes the S parameter, the radiation patterns, the system transfer function and the time domain waveform, etc. The consistency between the simulated results and the measurement results confirm the practicability of these techniques.