This thesis is devoted to develop a rapid, low-cost, portable device for on-site diagnosis of Odontoglossum ringspot tobamovirus (ORSV), one of the most prevalent viruses in Orchids. Orchids are the most important economic crops in Taiwan; it has more than 164 million of US dollars in export value in 2012. The cantilever sensor with piezoresistive mechanism possesses the advantage of portable, rapid and accuracy that can be utilized in on-site virus detection. Wheatstone bridge with signal readout system is used to detect the small bio-signal. By integrating reference cantilevers as mechanical filter in the sensor, the detection result is more reliable since the signal change is mostly contributed from biomolecule-recognition between ORSV antibody and antigen. The ORSV detection limit of the cantilever sensor was measured at 50 ng/μl and showed great specificity. One of the problems in piezoresistive cantilever biosensor is thermal drift problem since the electric currents flowing through the piezoresistors, caused additional heat dissipation. The discrete measurement was designed to solve the problem. Different methods of characterize the stiffness of composite cantilever were also conducted and compare in the thesis. The device further adapts commercially-available TSMC 0.35 2P4M CMOS technology with BioMEMS post-processes, showing its potential as a low-cost, rapid, label-free and point-of-care (POC) device for orchid virus (ORSV) detection.