This thesis consists of three parts: Monopole antennas with dual-band circular polarization, study of compacting size of leaky-wave antenna and suppressing side lobe of tapered leaky-wave antenna, and on-chip antenna for wireless personal area network (WPAN) application. In the first part, novel designs of dual-band circular polarization (CP) monopole antenna are presented. The proposed antenna comprised of a ground plane embedded with an inverted-L slit, which is capable of generating a resonant mode for broadband impedance-bandwidth, and excites left-hand circular polarization (LHCP) at 2.5 GHz and right-hand circular polarization (RHCP) at 3.4 GHz. Furthermore, embedding an I-shaped slit in the rectangular radiator and adding an I-shaped stub in the ground plane, the impedance-bandwidth can be increased to 6.30 GHz, and the 3-dB AR-bandwidth at 3.4 GHz is greatly enhanced from 230 MHz to 900 MHz. In this design, we use a simple method to achieve the dual-band CP radiation and broad impedance bandwidth. In the second part, a compact wideband leaky-wave antenna (LWA) with etched slot elements and suppressing side lobe of tapered leaky-wave antenna are studied. In compact wideband LWA case, by etching slot elements on the ground plane, the current distribution of LWA can be influenced to compact the width of conventional LWA. In order to achieve the impedance matching, this multi-section tapered short leaky-wave antenna is embedded with two rectangular slots. This technique not only improves the impedance matching but also suppresses the back lobe. In suppressing side lobe of tapered LWA case, the proposed LWA contains a tapered microstrip radiator with a shorting pin and two rectangular slots. This design of two slots and a shorting pin can interfere with the current distribution of tapered LWA to suppress the radiation of side lobe. In order to achieve the impedance matching, a matching stub is added along the feeding line. The propose LWAs not only successfully reduces the width of a conventional LWA by more than 20 %, but also suppresses the side lobe. In the third part, an end-fired radiated on-chip monopole antenna for wireless personal area network (WPAN) application is designed. In general, if the on-chip antenna is integrated into RF front-end circuit, the effects electromagnetic interference (EMI) will be considered. Therefore, the proposed antenna can reduce the electromagnetic power to affect the circuit. The architecture of this antenna inherits rectangular monopole antenna except for its asymmetric-fed, slit, and shorting path approaches. The asymmetric-fed provides dual-band around 60 GHz and end-fire radiation. Besides, by embedding a slit on the monopole antenna and shorting pin on the ground plane, this antenna can achieve wide impedance bandwidth. According the simulated results, the proposed antenna can reduce the radiated power at the feed line to affect the front-end circuit, and the impedance bandwidth can be achieved about 30% with respect to the center frequency at 5.38 GHz.