In this dissertation, we propose three techniques in image sharing by using Boolean operations and modulus operations. Image sharing is a popular technology to secure digital images in storage and transmission. Traditionally, the technology transforms one secret image to several images called shadows or shares. Later, when the number of collected shadows reaches a specified threshold value, then the decomposed image can be reconstructed. In image sharing, polynomial interpolation approach has heavy computational load to retrieve the shared image. To the contrary, visual cryptography approach is fast in decoding but is often needs larger storage space due to pixel expansion property. By using Boolean operations, we propose a missing-allowable (k, n) scheme that is fast and with a reasonable pixel expansion rate (per). The scheme generates n extremely noise-like shadow images for the given secret color (grayscale/binary) image A, and any k out of these n shadows can recover A loss-freely. In average, to decode a color (grayscale/binary) pixel of A, the retrieval uses only 3 exclusion-OR operations among 24-bit (8-bit/1-bit) numbers. Hence, the new method has very fast decoding speed, and its pixel expansion rate is always acceptable (0=2) secret images into n shadows. Later, after gathering all n shadows, all n secret images can be retrieved error-freely. No secret image is revealed if one shadow is absent. The total size of n generated shadows is identical to the total size of n input secret images; hence, this approach does not waste storage space. Each pixel in each secret image is reconstructed using only one Boolean, one modulus and two mathematical operations. Therefore, it is also fast to reconstructing many secret images. Comparisons are included.