This dissertation is focused on the design of the novel compact antenna development for handset applications. These antenna designs have the merits of simple in geometry, easy for manufacture and integration, low cost, and exhibits good radiation efficiency. Firstly, the common multi-strip structure of monopole antennas was classified. A comparison of the advantages of multiple-strip design with merged modes, and identified the root cause of modes failing to merge are presented. Based on these observations, a half wavelength mode exists on dual-strip monopole antenna is found, in addition to the fundamental quarter wavelength modes. This half wavelength mode can facilitate mode combination. To explain the mutual coupling effect occurred between any two adjacent traces of the dual-strips monopole antenna for modes mergence, a conceptual equivalent circuit is proposed. This dissertation also provides a layout configuration for exciting the half wavelength mode to resolve the issues preventing non-merged modes from achieving a continuous impedance bandwidth and compact size in proximity to the ground. Hence, a ground proximity multiple-strip monopole antenna with 7mm no-ground area for mobile phones applications is developed. Besides, a small size forked shape multiple-strip monopole antenna with 86% impedance bandwidth is proposed for DVB reception and mobile services applications. Secondly, the material design of metal has become popular and increasingly important. However, the bandwidth and radiation efficiency of conventional antennas in handheld devices tend to decrease when the antenna is in proximity of metal or surrounded by a conducting edge, which affects the impedance matching considerably and renders restoring the performance by adjusting the antenna parameters difficult, examples of these include the monopole antenna, planar inverted-F antenna (PIFA), and inverted-F antennas (IFA); these antennas are widely used in handheld devices. Hence, a compact multi-band antenna is proposed for metal casing mobile phone applications. This structure can generate four resonance modes, including two slot modes and two monopole modes. The advantage of proposed structure is to obtain wide bandwidth (1700-4200MHz) on the high frequency to cover the mobile broadband services. Moreover, a compact dual-slot antenna is proposed for full metal rim application. The dual slots are designed for generating several resonance modes, including loop mode, slot mode, and monopole mode. Each slot can support resonance at low and high frequencies simultaneously achieving a wide impedance bandwidth. In addition, the practical situation is also considered. The energy absorbed from a handset by the human hand is a critical concern because it can alter the radiation pattern and cause considerable degradation of phone performance, particularly in a metal rim handset. The proposed inner slot prevents this issue. Finally, to address the dramatic increase in the demand for mobile broadband services and to support wider transmissions bandwidths of multiuser MIMO (MU-MIMO) and carrier aggregation (CA) functions that fulfill the extremely high data throughput requirements of devices, a multiband and wideband antenna with UWB feeding structure is proposed. This antenna is integrated the advantages of the UWB antenna at high frequency and the coupled-fed structure at low frequency. The proposed structure can obtain a wide bandwidth at low and high frequency to cover all of the handset broadband applications.