The analogies between paraxial optics and two-dimensional (2-D) quantum mechanics lie in the heart of this thesis. Based on the similarity between Helmholtz equation and time-independent Schrödinger equation, mesoscopic wave functions of quantum billiards are used to interpret the high-order transverse modes of broad-area Vertical-Cavity Surface-Emitting Lasers (VCSELs). Reversely, chaotic-shaped VCSELs can be employed to analogously observe the wave functions of non-integrable billiards which have no analytic solutions. In addition, the free-time evolution of coherent waves suddenly released from quantum billiards can be analogously observed from the free-space propagation of lasing modes emitted from VCSELs. Furthermore, the analogies are not restricted to quantum wave functions and optical transverse modes, the orbital angular momentum (OAM) density carried by a light beam emitted from VCSELs can be analogously analyzed by calculating the OAM of coherent waves abruptly set free from quantum billiards. More interestingly, the lasing modes of VCSELs are not only linearly-polarized but can form the vector fields, in which the polarization is spatially dependent. Since the polarization of light corresponds to the spin of quantum wave, the analyses of the vector fields in VCSELs can provide important information for quantum-billiard systems (such as ballistic quantum dots) with consideration on electronic spin.