Every material has its unique material properties, which can bring benefits or shortcomings. As advances of technologies, use of only one particular material very often cannot meet the demand of products. Thus, joining of dissimilar materials, especially between metal and plastic, has become a key issue in many industries. Industrial joining of dissimilar materials is generally performed by using adhesive bonds. Nevertheless the usage of adhesives is not environmentally friendly and takes long curing time. Several direct adhesion technologies have been developed, such as insert injection molding, hot pressing, laser welding, ultrasonic welding, and friction lap welding. These technologies were achieved by several different joining mechanisms, however, micro mechanical interlocking is considered as one of the major factor of the direct adhesion. The direct adhesion technologies based on micro mechanical interlocking were studied and developed in this thesis. In the first part, ABS and PBT+30%GF parts were formed and joined on micro-structured A5052 parts by injection molding method. An in-mold heating device was used to heat the metal insert independently. The PBT+30%GF could be joined onto the anodized, PEO, laser treated metal insert when the metal insert heated over 130°C. However, the ABS part could only joined onto laser specimen. In the second part, a low energy demand ultrasonic direct adhesion technology was carried out by the laser micro structure on the metal surface. The ABS parts were joined onto A5052 laser specimens by weld energy lower than 100J in 1sec. A method to predict the shear bond strength of micro-mechanical interlocking was established, and the shear bond strength of ABS/A5052 laser structured specimens were near the theoretical strength. The highest shear bond strength of injection molding was 14MPa, which was 36% of the plastic tensile strength. The highest shear bond strength of ultrasonic direct adhesion was 11MPa, which was 28% of the plastic tensile strength.