This dissertation focuses on the design of compact reconfigurable antennas using L-shaped slots. A compact switched-beam antenna is proposed firstly. The antenna is composed of a four-element antenna array based on L-shaped quarter-wavelength slot antenna elements. Such an antenna element is a planar structure and presents a directional radiation pattern on the azimuthal plane. Its maximum radiation direction is toward near the direction of the open end of the slot. As a result, the open ends of the four slot antennas are arranged toward 0, pi/2 , pi, and pi*3/2, respectively. The statuses of these antennas are controlled by some diodes. Consequently, by carefully controlling the diodes, an antenna with several switchable patterns can be achieved. To prove the concept, a 2.4-2.5 GHz switched-beam antenna for WLAN applications is designed and implemented. Its size is 52mm in square. The antenna possesses eight directional patterns and many nearly omni-directional patterns on the azimuthal plane. The envelope correlations and the characteristics of the designed antenna are also discussed in the dissertation. Due to the compact size and low manufacture cost, such a design can be a promising solution for digital home applications to overcome multipath problems and increase the transmission data rate. Next, a basic antenna structure to design pattern, frequency, and pattern/frequency reconfigurable antennas is proposed. The structure consists of an L-shaped slot, PIN diodes, lumped capacitors, and bias networks. The PIN diodes and the lumped capacitors located at specific positions are used to create short circuits across the slot. By carefully controlling these diodes, the induced current distribution around the slot can be changed, resulting in different antenna radiation patterns. Thus, a pattern reconfigurable antenna can be achieved. The proposed structure is then extended to design frequency and frequency/pattern reconfigurable antennas by simple modifications. A series of compact reconfigurable antennas based on the proposed structure is designed and implemented to prove the design concepts. Owing to the compact size, low manufacture cost and planar feature, the proposed structure can be applied to compact wireless devices such as smart phones and notebook computers.