This thesis will focus on discussing the coherence of chirped multilayer quantum dot (CMQD) laser and feasibility study of its application on optical coherence tomography (OCT). To acquire the coherence information of CMQD, we have set up a fiber-based and delay-tunable Mach-Zehnder interferometer. The accuracy of measurement has been confirmed by mathematical simulation on commercial lasers. To achieve an OCT light source with higher axial resolution, we have specially designed a chirped multilayer (N=10) quantum dot laser. The measurement of laser characteristics of CMQD was demonstrated, including interferograms. An extremely broad spectrum of 29 nm without any 3dB dip was achieved. It centered at 1270 nm and was expected to have a coherence length less than 50 μm. Due to the longitudinal modes, we conclude that measuring interferogram is a more direct and more practical way to decide if a “broad spectrum” laser is suitable or not for OCT application. Furthermore, the FWHM of the main peak in an interferogram could be viewed as an indicator for judging the broadness of the spectrum for a broadband laser. Finally, suggestions will be provided in order to improve the performance of CMQD.