Various techniques for construction of a machine guide dog using a two-mirror omni-camera and an autonomous vehicle for navigations on sidewalks are proposed. The autonomous vehicle can compute 3D information from acquired omni-images to localize itself using pre-selected landmarks, and guide a blind person to follow a planned path to a destination on a sidewalk. Firstly, a method for learning the sidewalk environment is proposed to construct a navigation map, including a navigation path, along-path landmark locations, and relevant vehicle guidance parameters. Next, a navigation system with self-localization and automatic guidance capabilities using landmarks including curb lines, tree trunks, stop lines on roads, lawn corners, traffic cones, and signboards is proposed. By the use of a space-mapping technique, three space line detection techniques for use directly on the omni-image are proposed, which can be used to compute the 3D position of a specific space line in the shape of a sidewalk landmark. Moreover, based on the techniques for detecting three space lines, techniques for detections and localizations of the above-mentioned natural and artificial landmarks are proposed. Using these vehicle self-localization techniques, imprecise vehicle positions due to incremental mechanic errors can be adjusted. In addition, for the purpose of continuous navigation, a curb line following technique is proposed as well to guide the vehicle along a sidewalk when landmarks are not available during the navigation process. To detect landmarks in the outdoor environment, techniques for dynamic threshold adjustments are also proposed for adapting the system’s capability to varying lighting conditions in navigation environments. Good experimental results showing the flexibility and feasibility of the proposed methods for real applications are also included.