It is generally believed that the surface of petal effect possess both nano-and micro-structure. It has been proposed that water droplet penetrate into micro-structure much more than nano- structure. That makes the rose petals have the characteristics of superhydrophobicity (contact angle larger than 150o) and strong adhesion to pin water drops. Based on this phenomenon, we conjecture that changing the roughness of micro-structure can make surface exhibit petal effect, so we make a series of micropillar-like patterned PDMS surfaces with different pillar sizes and spacing are fabricated via soft lithography. In this study, embedded needle method and evaporation method are used to measure advancing and receding angle respectively. An inverted needle method is applied to observe and identify whether water penetrates into the bottom of the substrate when the water droplet contact line is expanding and we also measure sliding angle to observe the ability of water droplet to adhere to micro-structure. We find out that a sequence of wetting transitions: Wenzel→ petal (sticky super-hydrophobic region) → Cassie (slippery super-hydrophobic state) would be consistently observed along with an increase in surface roughness for these micro-structure PDMS substrates. In addition, the ability of water droplet to adhere to micro-structure changes from high adhesion to low adhesion with increasing surface roughness.