In this thesis, we proposed a printed dual dipole antenna along with a new feeding network that can be applied to wireless communication systems and can also be designed as a dual-linearly-polarized printed dual dipole array for use in polarimetric radar systems. This thesis begins with the basics of dipole antennas and some important parameters and then discusses the radiation principle of printed dual dipole antennas. Based on the feeding structure proposed in [12], we proposed a new T-shaped feeding structure that can reduce the cross-polarization level. Thus, the coupling between adjacent antenna elements with orthogonal polarizations in the array design can be reduced. By properly designing the length and spacing of the printed dual dipole antenna as well as the length and width of the T-shaped feeding structure, the desired bandwidths and frequency bands for the IEEE 802.11 wireless local area network standard can be achieved. For verification, simulated and measured results of the fabricated prototype are given and compared. The simulations are conducted using full-wave simulation software. For practical consideration, commercially available inexpensive boards are used as the substrate to achieve a cost-effective antenna for wireless local area network applications. A comparison between the recently published works and our design is given as well. Moreover, a dual-linearly-polarized array antenna for polarimetric radar system is designed based on the printed dual dipole antenna. The orthogonally polarized printed dual dipole elements and the spacing between adjacent elements need to be designed carefully. A three-dimensional feeding network is proposed for the array design, including horizontal and vertical parts. The concept of mortise and tenon is used in this design, making it compatible to PCB-process and easy for assembly, welding, and positioning of the vertical and horizontal parts of the feeding network. The results of the simulation and experiment agree well, meaning that the proposed three-dimensional feeding network is feasible for practical applications. Finally, the designed dual-linearly-polarized radar array antenna is used for radar target identification. Based on the polarization-entropy-based method previously proposed by our lab, decent identification performance can be obtained. Compared with the dual-linearly-polarized square patch antenna used in our previous work, the dual- linearly-polarized radar array antenna proposed in this thesis demonstrates a wider frequency bandwidth and greater flexibility for practical applications.