The present disclosure belongs to the technical field of information storage, and particularly relates to a method for information storage based on a hybrid material. The method for information storage based on a hybrid material provided by the present disclosure includes a step of applying an external force to a hybrid material for driving, such that the hybrid material shows a fluorescent state or a non-fluorescent state, thereby realizing two-state or three-state information storage. By only applying the external force to the selected hybrid material for driving, energy band alignment methods can be transformed under the driving of the external force with an energy level difference between different components in the hybrid material. Therefore, the hybrid material shows the component fluorescent state or the non-fluorescent state. One storage cell has two or three states, so the present disclosure can be used to store two-state or three-state data.

A system includes a multiplexed optical identifier and a reader for the optical identifier. The multiplexed optical identifier includes an optical substrate, and a plurality of volume holograms in the optical substrate. The reader includes an illumination source and a camera. The illumination source is configured to direct light into the optical identifier to produce an image of a corresponding one of the volume holograms at the camera, and the camera is configured to capture the image, which is stored in a digital format by the system. The multiplexed optical identifier contains more than one code page, wherein each of the code pages is used for a different purpose.

In example implementations, an optical gate is provided. The optical gate receives at least one optical signal via a waveguide of an optical memory gate. The optical gate compares a wavelength of the at least one optical signal to a resonant wavelength associated with a resonator. When the wavelength of the at least one optical signal matches the resonant wavelength, a value that is stored in the resonator is read out via the at least one optical signal. Then, the at least one optical signal with the value that is read out is transmitted out of the optical gate.

A system includes a plurality of optical identifiers and a reader for the optical identifiers. Each optical identifier has an optical substrate and a volume hologram (e.g., with unique data, such as a code page) in the optical substrate. The reader for the optical identifiers includes an illumination source (e.g., a laser), and a camera. The illumination source is configured to direct light into a selected one of the optical identifiers that has been placed into the reader to produce an image of the associated volume holograms at the camera. The camera is configured to capture the image. The captured image may be stored in a digital format by the system.

A detection circuit may be configured to receive an input signal indicative of a data state and to detect the data state using charge sharing between two capacitors to achieve detection with threshold compensation . The detection circuit may include semi-latch circuitry and boosting circuitry to expedite the detection, thereby achieving high speed at low power consumption and low circuit size.

In this application, a 2D or 3D optical storage and a physical encryption method with ultrahigh storage density are presented. Designed information patterns can be written in an expanded hydrogel via laser patterning, followed by volume shrinkage and dehydration of the hydrogel to achieve physical encryption, ultrahigh storage density, and long-term storage. For decryption, the dehydrated gel is re-expanded, and then immersed in a solution of fluorescent materials to retrieve the stored information via an imaging system.

In example implementations, an optical gate is provided. The optical gate receives at least one optical signal via a waveguide of an optical memory gate. The optical gate compares a wavelength of the at least one optical signal to a resonant wavelength associated with a resonator. When the wavelength of the at least one optical signal matches the resonant wavelength, a value that is stored in the resonator is read out via the at least one optical signal. Then, the at least one optical signal with the value that is read out is transmitted out of the optical gate.

In a recording technique in which a plurality of light spots are simultaneously formed by using an ultra-short pulse laser and a spatial phase modulator, and a plurality of recording dots having refractive indexes different from those of the vicinities thereof are formed inside a recording medium, it is hard to make recording quality and a recording density compatible. Therefore, a plurality of dots are recorded at a predetermined dot pitch, and then other dots are recorded between the recorded dots.

A system includes a multiplexed optical identifier and a reader for the optical identifier. The multiplexed optical identifier includes an optical substrate, and a plurality of volume holograms in the optical substrate. The reader includes an illumination source and a camera. The illumination source is configured to direct light into the optical identifier to produce an image of a corresponding one of the volume holograms at the camera, and the camera is configured to capture the image, which is stored in a digital format by the system. The multiplexed optical identifier contains more than one code page, wherein each of the code pages is used for a different purpose.

The present disclosure belongs to the technical field of information storage, and particularly relates to a method for information storage based on a hybrid material. The method for information storage based on a hybrid material provided by the present disclosure includes a step of applying an external force to a hybrid material for driving, such that the hybrid material shows a fluorescent state or a non-fluorescent state, thereby realizing two-state or three-state information storage. By only applying the external force to the selected hybrid material for driving, energy band alignment methods can be transformed under the driving of the external force with an energy level difference between different components in the hybrid material. Therefore, the hybrid material shows the component fluorescent state or the non-fluorescent state. One storage cell has two or three states, so the present disclosure can be used to store two-state or three-state data.