In Augmented Reality systems, real time integrating 3D virtual objects into the real environment requires camera calibration techniques for spatial alignement. The accuracy of the parameters is then a crutial task for designing an effective Augmented Reality (AR) systems, and the challenge to meet this requirement is made harder when dealing with moving zoom-lens cameras. Although recent approaches have been proposed using 2D/3D patterns, the use of zooming lens cameras brings new problems for robust and continuous estimation of the intrinsic parameters. This paper propose a robust algorithm for variable focal length calibration combining interferometry and 2D pattern detection to tackle the problem. A global optimization routine is driven to search for the best calibration parameters that fit the system. After a description of the different methods involved in each step of the process, the approach is validated with AR experimental results on a real time AR touristic application.