In this thesis, we work on finding methods to improve the disadvantages of electrically small antenna (ESA) such as narrow bandwidth and low efficiency at the same time. The research is divided into two parts. The first branch investigates merging two resonances which have higher and lower efficiency, respectively. After merging the two resonances, the efficiency and bandwidth of the one with lower efficiency increased, and the bandwidth of higher one also extended while efficiency is almost fixed. To practice this mechanism, a small planar microstrip antenna which is composed of a split ring resonator (SRR) [higher efficiency] and a shorted spiral [lower efficiency] etched on a upper dielectric slab. The pin drills through a bottom dielectric layer on which a feed line comprising a rectangular microstrip and a meander line for matching is printed. The increase of in bandwidth and efficiency is by more than triple that of the single band counterpart. Compared to conventional patch antennas, the size reduction is by 87%. The second part of the work focuses on improving the performances of zeroth order resonance (ZOR) antennas. The ZOR has infinite wavelength characteristic which causes ZOR can be used for antenna miniaturization. However, the narrow bandwidth and low efficiency limit its applications. By bisecting symmetric ZOR antenna, the antenna dimension and quality factor (Q) are decreased remarkably. We prove it by calculating Q which is extracted from the parameters of equivalent circuit model. Therefore, the bandwidth and efficiency are increased. A bisected ZOR antenna based on bisected inter-digital capacitor-loaded transmission line (B-CL-TL), with extended bandwidth and higher radiation efficiency is proposed. The antenna consists of two cascaded bisected co-planar inter-digital capacitors as series capacitors shorted to the ground plane at one end. A meander-line inductor is implemented for matching. Compared to the CL-TL ZOR antenna, the ratio of increase of bandwidth and efficiency is 2.7 and 1.5, respectively. In this thesis, we prove from theorem and experiment that bisecting symmetric ZOR antenna not only reduce antenna size, but also increase efficiency and bandwidth.