The article discusses the use of random lasers for speckle-free full-field imaging, addressing the limitations of conventional laser and superluminescent diode (SLD) sources in imaging applications due to their high spatial coherence, which leads to coherent artifacts known as speckle. Random lasers, made from disordered materials that trap light via multiple scattering, can be engineered to have low spatial coherence. The authors demonstrate that random laser illumination provides higher resolution images compared to spatially coherent illumination, even in the presence of significant optical scattering. They compare the performance of random lasers with spatially coherent amplified spontaneous emission (ASE) illumination using a Young's double slit experiment and an Air Force resolution test chart. The results show that random laser illumination significantly suppresses speckle and improves image quality, making it well-suited for a wide range of full-field imaging applications, including full-field microscopy and digital light projector systems. The low temporal coherence of random lasers also makes them suitable for coherent imaging applications like optical coherence tomography.The article discusses the use of random lasers for speckle-free full-field imaging, addressing the limitations of conventional laser and superluminescent diode (SLD) sources in imaging applications due to their high spatial coherence, which leads to coherent artifacts known as speckle. Random lasers, made from disordered materials that trap light via multiple scattering, can be engineered to have low spatial coherence. The authors demonstrate that random laser illumination provides higher resolution images compared to spatially coherent illumination, even in the presence of significant optical scattering. They compare the performance of random lasers with spatially coherent amplified spontaneous emission (ASE) illumination using a Young's double slit experiment and an Air Force resolution test chart. The results show that random laser illumination significantly suppresses speckle and improves image quality, making it well-suited for a wide range of full-field imaging applications, including full-field microscopy and digital light projector systems. The low temporal coherence of random lasers also makes them suitable for coherent imaging applications like optical coherence tomography.