In this study, we observe the wetting behavior of the hydrophobic rough surfaces in two different ways including experiments and simulation. Wetting behavior plays an important role in various industry and has a number of applications. In experiments, we investigate the wetting behavior of hydrophobic, microstructured surfaces containing square array of holes, and observe their wettability by vary the width of hole, spacing and the depth of hole. We measure the advancing contact angles, the receding contact angles and the sliding angles to determine the wetting behavior of the water droplet on the surface. Due to the wide range of the depth (from 0.5 μm to 15 μm), both the Wenzel state and the Cassie state can be observed. We use the squeeze test to check whether the wetting transition between two different wetting states will occur. In the simulation, we simulate a water droplet sitting on a hydrophobic surface with a cosine wave-like square array pattern to determine the contact angle and study on the Cassie-Wenzel wetting transition by the Surface Evolver. At different surface roughnesses, we can obtain multiple metastable states for a fixed droplet volume. Each metastable state represents a contact angle of the liquid droplet. The maximum and minimum contact angles correspond to the advancing/ receding contact angles. By increasing the surface roughness, the wetting transition from the Wenzel state to the Cassie state will be induced. The results from the experiments and the simulation will be discussed and compared. We find there are some common results from two different ways of analysis of wetting behavior on hydrophobic surfaces with hole array pattern. Besides, we also compare the results from this study to the wetting behavior of hydrophobic, microstructured surfaces containing square array of pillars done by previous researches. Seeing the difference and the common parts between two different structures.