A novel interferometric stage based on quasi-common-optical-path (QCOP) configuration for large-area displacement applications has been developed. The interferometric stage includes a QCOP measurement system and dual-servo positioning stage. The QCOP measurement system consists of a heterodyne light source, two-dimensional holographic grating, specially designed set of half wave plates and lock-in amplifiers. Two QCOP measurement configurations, for single and differential detection, were designed. The sensitivity, resolution and nonlinear phase error of the differential detection type are better than those of the single detection type. Feasibility and performances of the QCOP measurement system have been addressed and demonstrated using 1D and 2D displacement experiments and a systematic comparison with a commercial capacitive sensor, strain gauge, linear encoder and linear interferometer. The experimental results demonstrate that the QCOP measurement system has the ability to measure long-range (1D) and large-area (2D) straightness and displacement while maintaining high system stability. Furthermore, a micro-stepper was used to integrate with a leaf-spring type PZT stage for 1D and 2D displacement positioning. The suitable parameters of leaf-spring type PZT stage were calculated using an optimization method. By combining the QCOP measurement system with dual-servo positioning stage, the positioning resolution and range of interferometric stage can achieve the nanometer and milimeter levels with high system stability for large-scale applications.