Dysprosium-doped zinc oxide (Dy:ZnO) thin films are grown by pulsed-laser deposition on c-oriented sapphire substrate and their structural, optical, magneto-optical, and electrical properties at room temperature are discussed. The x-ray diffraction and Raman scattering analysis confirm the wurtzite structure of ZnO without secondary phase. With the Dy dopant concentration increasing, grain size becomes smaller while c-lattice constant does not change much. In photoluminescence spectra, ZnO shows strong near band edge (NBE) emission. The NBE luminous intensity decreases and the defect intensity increases when Dy concentration increases. The main defects are oxygen vacancy (VO), zinc vacancy (VZn) and zinc interstitial (Zni). Study of the magneto-optical Faraday effect spectra shows that all the thin films are paramagnetic, which is the same from SQUID measurement. Verdet constant of Dy:ZnO thin films decrease with increasing wavelength. When analyzing the spectra of defects, take the zinc interstitial as an example, the Verdet constant becomes larger with an increase of Dy concentration. I-V curves show all Dy:ZnO thin films having ohmic contact. Van der Pauw method was used to measure the resistivity of Dy:ZnO thin films and the values are between 0.078 mΩ·cm and 277.72 mΩ·cm. Hall effect measurements shows that pure ZnO thin film is an n-type semiconductor, and Dy:ZnO thin films with 1 and 5 at.% are p-type semiconductors. The carrier density is between 7.89×1018 cm-3 and 5.3×1022 cm-3, and the mobility is between 4.3×10-4 cm2/Vs and 35.15 cm2/Vs.