Video encryption/compression using compressive coded rotating mirror camera

Matin, Amir; Wang, Xu

doi:10.1038/s41598-021-02520-8

Cited by 6 publications

(3 citation statements)

References 55 publications

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“…A rotating-mirror CUP system has been applied to the video recording of complex fluid dynamics and interactions at the microscale. 148 A schematic of rotating-mirror-based CUP is shown in Fig. 16(a) .…”

Section: Biomedical Applicationsmentioning

confidence: 99%

Tutorial on compressed ultrafast photography

Lai,

Marquez,

Liang

2024

J. Biomed. Opt.

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. Significance Compressed ultrafast photography (CUP) is currently the world’s fastest single-shot imaging technique. Through the integration of compressed sensing and streak imaging, CUP can capture a transient event in a single camera exposure with imaging speeds from thousands to trillions of frames per second, at micrometer-level spatial resolutions, and in broad sensing spectral ranges. Aim This tutorial aims to provide a comprehensive review of CUP in its fundamental methods, system implementations, biomedical applications, and prospect. Approach A step-by-step guideline to CUP’s forward model and representative image reconstruction algorithms is presented with sample codes and illustrations in Matlab and Python. Then, CUP’s hardware implementation is described with a focus on the representative techniques, advantages, and limitations of the three key components—the spatial encoder, the temporal shearing unit, and the two-dimensional sensor. Furthermore, four representative biomedical applications enabled by CUP are discussed, followed by the prospect of CUP’s technical advancement. Conclusions CUP has emerged as a state-of-the-art ultrafast imaging technology. Its advanced imaging ability and versatility contribute to unprecedented observations and new applications in biomedicine. CUP holds great promise in improving technical specifications and facilitating the investigation of biomedical processes.

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Section: Biomedical Applicationsmentioning

confidence: 99%

Tutorial on compressed ultrafast photography

Lai,

Marquez,

Liang

2024

J. Biomed. Opt.

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“…To achieve the goal of video security, the video is categorized into three aspects, which are confidentiality, integrity, and availability [21]. Existing video encryption schemes can achieve integrity and confidentiality, but not many can achieve better usability; this is because many traditional video encryption techniques encrypt the original video into pixel-homogenized snowflake speckles [22][23][24][25], sacrificing the encrypted video's usability, making the technique unsuitable for many video applications that provide features such as video previewing, video categorization, and so on. For example, when users want to download a video that they need from the cloud, they have to decrypt all videos that they have stored before they can find the target video, which wastes a great amount of their time.…”

Section: Introductionmentioning

confidence: 99%

A Visually Meaningful Color-Video Encryption Scheme That Combines Frame Channel Fusion and a Chaotic System

An,

Hao,

et al. 2024

Electronics

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Compared to text and images, video can show information more vividly and intuitively via a moving picture; therefore, video is widely used in all walks of life. However, videos uploaded or stored in various video applications have not been treated with any protection, and these videos contain a lot of sensitive information that is more likely to be compromised. To solve this problem, video encryption schemes have been proposed. However, the main concern with existing video encryption schemes is that the private information in the encrypted video should be effectively protected, and, thus, the pixel distribution of the original video can be greatly damaged in the process of encryption, resulting in no or poor visual usability of the encrypted video. To this end, a novel color-video encryption scheme is proposed, which can effectively protect video privacy information while retaining certain visual information, thus enhancing the usability of encrypted videos. Firstly, the R, G, and B channels of the original color video are viewed as a whole for splitting. The dimensions of the blocks are three-dimensional, and permutation encryption is performed in three-dimensional blocks, which eliminates the redundancy of information between the video frame channels. Secondly, after permutation encryption, the channels of the video frame are separated, and then each channel is divided into blocks. The shape of the blocks is a square, and substitution encryption and permutation encryption operations are performed in turn. The whole encryption process is combined with the 2D-LSM chaotic system to improve the security of the scheme, as well as to reduce the time. Extensive experiments have been carried out, and the results show that the proposed scheme allows the encrypted video to retain rough visual information and, at the same time, effectively protects privacy, achieving the goal of encrypted video security and usability.

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“…Video-based applications, which have become widespread in all areas of life such as business, entertainment and military, reveal security requirements. This situation has led to the need for many segments to produce solutions in this field, from personal data security to industrial data security [2][3][4]. The security of in-plant video images, which are critical in data communication between facilities in the energy sector, is becoming increasingly important.…”

Section: Introductionmentioning

confidence: 99%

A New hyper chaotic algorithm for energy video communication security

Kurt

MÜLAYİM²

2022

Journal of Energy Systems

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The usage of the cameras in facilities in the energy sector is becoming more and more common. In addition, with the widespread use of SCADA and the increase in automation of camera-based applications, ensuring security in video data communication has become more and more important. In this study, methods that have been successful in providing image security in previous studies in Ref.[1] have been improved to ensure the security of video data communication. These methods use Kurt-Modified Chua’s Circuit (KMCC) as random number generator. Proposed algorithms are efficient for energy sector secure video communication because of using hyperchaotic random number generator and also bit level scrambling, diffusion encryption to each frame of video.

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Video encryption/compression using compressive coded rotating mirror camera

Cited by 6 publications

References 55 publications

Tutorial on compressed ultrafast photography

Tutorial on compressed ultrafast photography

A Visually Meaningful Color-Video Encryption Scheme That Combines Frame Channel Fusion and a Chaotic System

A New hyper chaotic algorithm for energy video communication security

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