Metasurface-based key for computational imaging encryption

Optical metasurfaces can offer high-quality multichannel displays by modulating different degrees of freedom of light, demonstrating great potential in the next generation of optical encryption and anti-counterfeiting. Different from the direct imaging modality of metasurfaces, single-pixel imaging (SPI) as a typical computational imaging technique obtains the object image from a decryption-like computational process. Here, we propose an optical encryption scheme by introducing metasurface-images (meta-images) into the encoding and decoding processes as the keys of SPI encryption. Different high-quality meta-images generated by a dual-channel Malus metasurface play the role of keys to encode multiple target images and retrieve them following the principle of SPI. Our work eliminates the conventional digital transmission process of keys in SPI encryption, enables the reusability of a single metasurface in different encryption processes, and thereby paves the way toward a high-security optical encryption between direct and indirect imaging methods.

Automated summary

The research proposes an optical encryption scheme by introducing metasurface-images (meta-images) into the encoding and decoding processes of SPI encryption as the keys. This approach eliminates the conventional digital transmission process of keys in SPI encryption, enabling the reusability of a single metasurface in different encryption processes. It paves the way toward high-security optical encryption between direct and indirect imaging methods.