Various wideband and dual-band antenna designs using dielectric resonators (DR) have been proposed. A rectangular DR antenna generally operates in its TE111 mode with a typical bandwidth of 5-8%, depending on its permittivity and dimensions. The TE111 mode has its characteristic electric field distribution within the rectangular DR. Modification in shape will perturb the electric field distribution. By inserting a thin air gap normal to the electric field into the DR, the electric field will be enhanced by several times. Hence, the radiation becomes more efficient and the Q factor of the DR is reduced, rendering a wide impedance bandwidth. Notches or tunnels can also be carved off the DR to increase its bandwidth. The effects of shape modifications on the resonant frequencies are analyzed by using the reaction between the original and the perturbed field distributions. A rectangular DR with shape modification is designed to have dual-band characteristic with bandwidth covering 3.375-3.93 GHz (15%) and 5.08-5.415 GHz (6%), respectively. Each resonant mode in the DR is associated with a unique radiation pattern. For example, a rectangular DR operating in its TE111 mode has a broadside radiation pattern on the H-plane, while that operating in the TE112 mode has a null radiation on the H-plane. The field distribution in a DR becomes the superposition of individual field distributions of different resonant modes when the DR operates at the frequency between the resonant frequencies of different modes. The impedance bandwidth can be increased by merging the bands associated with the TE111, TE112, and TE113 modes. The resonant frequencies of these three modes can be close by proper designing the DR dimensions, making the radiation pattern more consistent over the impedance bandwidth. Moreover, an asymmetric moat is caved off to tilt the beam and hence increase its directivity on the H-plane. A rectangular DR with an asymmetric moat is designed to provide a wide impedance bandwidth of 4.89-6.86 GHz, over which broadside radiation pattern is obtained The interface between air and high-permittivity material can be approximated as a perfect magnetic condition (PMC) wall. If a DR is partially coated by metal, a new resonant mode appears. Coplanar waveguide is used to excite the new resonant mode of the metal-coated DR. The metal coating also acts as a monopole. Merging the bands of the DR and the monopole by proper designing their dimensions, a wide impedance bandwidth can be obtained (4.2-6.8 GHz), over which a nearly omnidirectional radiation pattern is achieved.