Dazzling Particle Effects in Photoshop
Dazzling is an adjective that refers to a bright light or the visual effects of light. The bright light could be an object or the glow of a star in the sky. It could also be referring to an intense glow or the effect caused by a flashlight or headlight. The word dazzling can also refer to a person who has a great deal of energy and enthusiasm.
The word dazzling can be used in both casual and formal contexts. The most common uses are in the form of a noun, such as a person who is dazzling or a dazzling performance. The word can also be a verb, such as when a person is dazzling someone else.
In this article, we'll learn how to create some dazzling particle effects in Photoshop. We'll start by creating a new layer, and then using the Brush Tool to paint in some of the glowing effects. We'll then copy those layers to the rest of our particles, and then adjust the colors a bit so that they fit the overall look of the scene we're trying to create.
A person who is dazzling is arousing in others the impression that he or she has great charm, good looks, and/or charisma. Unlike eloquence, which is more an intellectual or mental skill, charm is more an emotional quality, and thus more likely to be contagious.
Several image quality assessment algorithms are commonly used for laser-dazzling images, including the normalized mean square error (NMSE) and SSIM. These methods can be improved by using wavelet transform and multi-scale structural similarity. However, they may not reflect the subjective evaluation. In this paper, a cross-distorted method WWMS-SSIM is proposed and the evaluation results are more suitable to the subjective visual feeling than those of NMSE and SSIM for laser-dazzling images.
In addition, this algorithm is more appropriate to the dynamic laser-dazzling condition and can improve the image quality of imaging systems by removing the influence of the noises. The experimental results indicate that WWMS-SSIM can provide more reasonable evaluation scores for laser-dazzling images of different laser irradiance power and spot position than SSIM and NMSE. These quantitative results contribute to the better understanding of laser-dazzling, and can be helpful for designing efficient means to protect imaging systems from interferences by laser irradiance.