Abstract
Thien-and-Lin’s polynomial-based secret image sharing (PSIS) is utilized as the basic method to achieve PSISs with better performances, such as meaningful shares, two-in-one property and shares with different priorities. However, this (k,n) threshold PSIS cannot achieve lossless recovery for pixel values more than 250. Furthermore, current solutions to lossless recovery for PSIS have several natural drawbacks, such as large computational costs and random pixel expansion. In this paper, a lossless and efficient (k,n) threshold PSIS scheme with reduced shadow size is presented. For lossless recovery and efficiency, two adjacent pixels are specified as a secret value, the prime in the sharing polynomial is replaced with 65,537, and then the additional screening operation can ensure each shared value in the range [0,65,535]. To reduce shadows size and improve security, only the first k−1 coefficients are embedded with secret values and the last coefficient is assigned randomly. To prevent the leakage of secrets, generalized Arnold permutation with special key generating strategy is performed on the secret image prior to sharing process without key distribution. Both theoretical analyses and experiments are conducted to demonstrate the effectiveness of the proposed scheme.
Highlights
In a secret image sharing (SIS) scheme, the secret image is divided into several shadow images without any secret information leakage, and it can be recovered only when a sufficient number of shadow images are combined together
We firstly utilize two adjacent pixel values to form a secret value which can be represented as a 16-bit integer from 0 to 65,535, and specify 65,537 as the prime in the sharing polynomial with the help of a screening operation, to avoid generating share values larger than 65,535 which is the maximum of a 16-bit integer
In our scheme, two adjacent pixel values are specified as a secret value; the total number of secret values is decreased by half, and the total number of sharing phases or recovery phases will be decreased
Summary
In a secret image sharing (SIS) scheme, the secret image is divided into several shadow images (or shares) without any secret information leakage, and it can be recovered only when a sufficient number of shadow images are combined together. In Ding and coworkers’ scheme [24], pixel values more than 250 need to be divided, but both parts are embedded into another two coefficients of the constructed polynomial during one single sharing phase These solutions bring in some other negative effects, such as random shape changes, large shadow size and high computational complexity. We firstly utilize two adjacent pixel values to form a secret value which can be represented as a 16-bit integer from 0 to 65,535, and specify 65,537 as the prime in the sharing polynomial with the help of a screening operation, to avoid generating share values larger than 65,535 which is the maximum of a 16-bit integer These operations guarantee to achieve lossless recovery and high efficiency in our scheme.
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