Random lasers, which are made from disordered materials, offer a new class of illumination sources for full-field imaging. Unlike conventional lasers and superluminescent diodes (SLDs), which have high spatial coherence and produce coherent artifacts like speckle, random lasers have low spatial coherence and high photon degeneracy, making them ideal for speckle-free imaging. This is because the random laser's emission is spatially incoherent, which suppresses speckle and improves image resolution. The study demonstrates that random lasers can provide higher resolution images than spatially coherent sources, even in the presence of significant optical scattering. The random laser's low spatial coherence is achieved by controlling the scattering strength and pump geometry. The photon degeneracy of random lasers is also high, comparable to conventional lasers, but with the added benefit of low spatial coherence. This combination of high photon degeneracy and low spatial coherence makes random lasers uniquely suited for full-field imaging applications. The study also shows that random lasers can improve imaging resolution and contrast-to-noise ratio (CNR) compared to conventional lasers, especially in the presence of scattering media. The results indicate that random lasers are a promising alternative to conventional light sources for full-field imaging applications.Random lasers, which are made from disordered materials, offer a new class of illumination sources for full-field imaging. Unlike conventional lasers and superluminescent diodes (SLDs), which have high spatial coherence and produce coherent artifacts like speckle, random lasers have low spatial coherence and high photon degeneracy, making them ideal for speckle-free imaging. This is because the random laser's emission is spatially incoherent, which suppresses speckle and improves image resolution. The study demonstrates that random lasers can provide higher resolution images than spatially coherent sources, even in the presence of significant optical scattering. The random laser's low spatial coherence is achieved by controlling the scattering strength and pump geometry. The photon degeneracy of random lasers is also high, comparable to conventional lasers, but with the added benefit of low spatial coherence. This combination of high photon degeneracy and low spatial coherence makes random lasers uniquely suited for full-field imaging applications. The study also shows that random lasers can improve imaging resolution and contrast-to-noise ratio (CNR) compared to conventional lasers, especially in the presence of scattering media. The results indicate that random lasers are a promising alternative to conventional light sources for full-field imaging applications.