In this thesis, we focus on the design and application of intrusion detection system based on optical fiber interferometers. Laser light is generated in each of the ring laser cavities located at defended zones. The system under study has four perimeter zones to be defended with Wavelength-Division-Multiplexed signal lights generated at the four zones, respectively. The laser lights produced from the four perimeter zones are sent back to four different photodetectors for further signal processing. Only one core, i.e., one fiber, of a four-core fiber cable is used as a disturbance sensor in detecting intrusion along a multi-zone perimeter. The fiber cable is divided into four sections, with each section used for detecting intrusion-induced disturbance in a perimeter zone. In this study, four optical interferometers are constructed along the single fiber for four protected zones, respectively. These protected zones are operated independently, and optical signals transmitted back to the receiver site will be analyzed to determine if there is intrusion upon any perimeter zone. These optical signals from the four perimeter zones are divided using the DWDM technique, and then detected by photodetectors, separately. The obtained signals are get into a personal computer through a data acquisition (DAQ) card for signal acquisition and processing. Three parameters would be derived every 1.024 second from each perimeter zone signal, and compare with their respective thresholds. An intrusion is determined only if all of parameters exceed their respective thresholds. The main advantage of the proposed multi-zone intrusion detection system resides in the usage of only one single-mode fiber simultaneously for disturbance sensing and optical signal transmission. Compared with one of our previous works, the system provides not only a simpler and cost-effective method for multi-zone intrusion detection, but also a power-efficient way to achieve such a goal.