The study of the Ferromagnetic/Antiferromagnetic (FM/AFM) bilayer system is important in the research of magnetism. The magnetic behavior of the FM/AFM system is different from single FM layer. The thesis focus on the influence of the antiferromagnetic layer of cobalt oxide on the magnetization reversal of submicron cobalt planar wires using the magneto-transport properties. We used the techniques of lithography and sputtering to fabricate several series of Co planar wires of 30 nm in thickness and 30 μm in length. The widths range from 0.2 to 1.1 m. Some of Co planar wires are in situ covered by a 3 nm thick Au layer to prevent oxidation. Others are forced oxidized by exposing in the air for certain amounts of time before covering Au. The magnetroresistance was measured by the four-probe technique. The resistance of all Co samples increases with decreasing temperature below 10 K indicating that all samples are slightly disordered. The disorder of CoO/Co planar wires is worse. For the Co planar wires, when the wire width is less than 0.5 μm, the shape anisotropy dominates the magnetic behavior and reveals all characteristics of a single domain structure. When the width is between 0.5 μm and 1.2 μm, magnetoresisrtance curve is analog to that of the CoO/Co planar wires implying that there always is a naturally oxidized layer. The influence of such a nature oxidation is strong as the wire width increases. The exchange coupling of the AFM/FM bilayer seems suppress the shape anisotropy induced single domain structure in the high aspect ratio FM layer. Besides, for the planar wires with surface oxidation, the magnetroresistance curve is clearly shifted from the remanent field and has the training effect and a big exchange bias. With increasing amounts of CoO, the above phenomena become more notable.