In this study, we investigate the imaging properties of reflection-type digital holographic microscopy (DHM) system and how to improve the axial resolution and lateral resolution in the DHM system. First, we study the acceptable radius of curvature and the maximum height of the sample are restricted to the objective lens of reflection-type DHM. Then we present a full-field three-dimensional surface profile technique for measuring the topography of sample. We also describe the influence of coherent illumination on phase measurement accuracy in DHM. To improve net phase accuracy, the spatial and temporal averaging techniques are applied simultaneously to suppress the phase noises caused by the light source and CCD image sensor. A comparison between a laser diode operated in single- and multi-modes on the fringe visibility and the reconstructed phase accuracy is given. Axial sub-nanometer accuracy in DHM is performed using a wavelength-stabilized laser diode in single-mode operation. Another research work is to improve the lateral resolution of the DHM system using synthetic aperture technique. Simulated results show that the angular-multiplexed synthetic aperture can reach superresolution imaging by one-shot in DHM system.