Fig. 1. Properties of multi-Gaussian Schell-model beams for different beam orders with λ=632 nm，w₀=1 mm，δ₀=0.1 mm^［15］

Fig. 2. Density plot of the square of the modulus of the degree of coherence of Hermite-Gaussian correlated Schell-model beams for different beam orders^［16］

Fig. 3. Intensity distributions of Hermite-Gaussian correlated Schell-model beams at several propagation distances in free space（m=n=1）^［16］

Fig. 4. Intensity evolution of conventional non-uniformly beams on the x-z plane with w₀=0.5 mm，δ₀=0.5w₀^［34］

Fig. 5. Density plot of the absolute value of the degree of coherence of Hermite non-uniformly correlated beams for different the beam orders^［39］

Fig. 6. Intensity evolution and scintillation index of Hermite non-uniformly correlated beams propagation in turbulence^［40］

Fig. 7. Intensity distribution of radially polarized vector optical coherence lattices beams at several propagation distances in free space^［45］

Fig. 8. Density plots of different square of the degree of coherence of the novel correlated radially polarized partially coherent beam in the source plane^［46］

Fig. 9. Intensity distribution of the focused novel correlated radially polarized partially coherent beam at several propagation distances^［46］

Fig. 10. Spectral degree of polarization of electromagnetic non-uniformly correlated beams on propagation^［48］

Fig. 11. Density plot of the intensity distribution and the state of polarization of radially polarized Hermite non-uniform correlation beams upon propagation in free space^［49］

Fig. 12. Degree of polarization of radially polarized Hermite non-uniform correlation beams upon propagation in free space^［49］

Fig. 13. Spectral density distribution for the electromagnetic cosh-Gauss non-uniformly correlated beam source passing through a linear polarizer with different transmission angles^［50］

Fig. 14. Experimental setup for generating Gaussian Schell-model beams^［55］

Fig. 15. Experimental setup for generating partially coherent beams with different coherence structure^［56］

Fig. 16. Computer generated hologram and intensity distribution of different correlated beams^［56］

Fig. 17. Schematic diagram of an experimental device for generating novel spatially coherent radially polarized partially coherent beams^［46］

Fig. 18. Experimental results of the square of the degree of coherence and the intensity distribution of the novel correlated radially polarized partially coherent beams^［46］

Fig. 19. Experimental setup for generating partially coherent beams by using Monte Carlo^［58］

Fig. 20. Experiment setup for generating vector partially coherent source^［63］

Fig. 21. Schematic diagram of an experimental device for generating novel coherent structure beam using coherent-mode representation^［67］

Fig. 22. Schematic of the experimental setup for synthesizing non-uniformly correlated sources^［70］

Fig. 23. Experimental setup for generation of partially coherent beams with circular coherence^［71］

Fig. 24. Experimental setup for the generation of the electromagnetic non-uniformly correlated beam source^［50］