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Seeing at a distance with multicore fibers: All-optical, ultra-long-distance image acquisition and transmission system

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Seeing at a distance with multicore fibers: All-optical, ultra-long-distance image acquisition and transmission system

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Concept diagram of Multicore Fiber Acquisition and Transmission Image System (MFAT) (a) Different modes in different channels of a multicore fiber are excited by different incident angles of light (in red and yellow). (b) Directly acquired image of the proximal end face of a multicore fiber. The red region of interest zooms in on the detail of a fiber core. The yellow and orange circles divide two different areas for decoding. (c) Workflow of traditional optical fiber-based image acquisition and transmission and MFAT. Credit: Opto-Electronic Advances (2024). DOI: 10.29026/oea.2024.230202

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Concept diagram of Multicore Fiber Acquisition and Transmission Image System (MFAT) (a) Different modes in different channels of a multicore fiber are excited by different incident angles of light (in red and yellow). (b) Directly acquired image of the proximal end face of a multicore fiber. The red region of interest zooms in on the detail of a fiber core. The yellow and orange circles divide two different areas for decoding. (c) Workflow of traditional optical fiber-based image acquisition and transmission and MFAT. Credit: Opto-Electronic Advances (2024). DOI: 10.29026/oea.2024.230202

With the exponential growth of data globally, the demand for high-speed acquisition and long-distance transmission of multidimensional data is escalating. Online video surveillance in sectors like industrial manufacturing has significantly boosted productivity while mitigating security risks. Real-time global video calls have revolutionized people’s daily lives.

Existing systems can leverage high-performance detectors, , and other technologies to gather carrier information like light, sound, and microwaves. This data is then transmitted back to the operator through various mediums such as cables, networks, wireless communications, and optical fibers.

However, in scenarios where narrow or challenging-to-access areas need observation, front-end acquisition equipment and electronic circuits (for tasks like information compression, coding, and modulation) are essential to process the data before transmission. This imposes specific requirements on the system’s timeliness and resistance to interference.

In recent years, optical fiber has gained widespread adoption in due to its low transmission loss and high capacity. Although technologies like wavelength-division multiplexing (WDM) and space-division multiplexing (SDM) using multi-core optical fibers have significantly enhanced system transmission capacity and efficiency, the transmission process still necessitates multiple signal conversions.

All-optical acquisition and transmission enable the transfer of image information from one end to the other at the speed of light without the need for additional electronic components.

Fiber optic bundles can directly convert and transmit two-dimensional light fields end-to-end, making them crucial in extreme environments such as inaccessible and obscured areas like aerospace, industrial production, and health care. However, fiber optic bundles are typically limited in length, costly, and face challenges in ensuring quality during long-distance data transmission due to manufacturing constraints.

Researchers have developed various all-optical networks for tasks like information gathering, encrypted transmission, and image classification, which are anticipated to underpin next-generation communications.

Nonetheless, these systems encounter practical hurdles in their deployment and are generally compatible only with coherent light sources such as lasers. Hence, there is a pressing need for an efficient, high-capacity, and interference-resistant image acquisition and transmission system.

In a new study published in Opto-Electronic Advances, researchers have proposed an all-fiber multiplexed parallel acquisition and transmission one-piece system called Multicore Fiber Acquisition and Transmission Image System (MFAT) to tackle the challenges as mentioned above.

The front-end design, devoid of , obviates the necessity for intricate signal conversion processes, making it suitable for diverse environments and resilient to noise stemming from incoherent light sources. Image data is encoded in the optical domain through coupling.

The multi-channel characteristics of multi-core optical fibers facilitate high-capacity and high-quality transmission. Furthermore, digital aperture technology enables image recovery and reconstruction from an end-plane image that conceals the original information entirely, thereby enabling real-time scene reconstruction from distances of up to one kilometer.

The image acquisition and transmission process comprises two main stages: encoding and decoding. The encoding phase relies on the principle of fiber propagation mode excitation, where different incident light angles reaching the end faces of distinct fiber cores excite varying propagation modes.

In most natural settings, the pattern within each fiber core channel can be perceived as a composite of all object points exciting diverse modes. Consequently, the information from the incident light field is encoded in the spatial and mode components of the multicore fiber for transmission. However, accurately determining the occupancy of each mode is typically challenging and demands substantial computational resources.

To address this, the study introduces a cost-effective digital aperture decoding technique based on image processing methodologies to facilitate swift reconstruction. By extracting and computing feature values for different fiber core regions, decoding diverse spatial information within the dimension of fiber transmission modes can be achieved.

This research showcases the system’s performance in both direct image transmission and encoded image transmission modes. The direct image transmission mode allows for direct observation of the scene at the far end, while the encoded image transmission can be integrated with digital encoding techniques to enable encrypted transmission of multidimensional data.

The concurrent multiplexing of temporal and spatial channels enhances transmission capacity significantly. Moreover, amalgamating polarization, wavelength, and other channel multiplexing techniques further augment the system’s transmission capacity.

The study also delves into factors influencing the system’s reconstruction effectiveness, such as temperature variations, bending, and algorithm robustness. The proposed solution holds significant application value in long-distance image acquisition and transmission, particularly in .

The interference-resistant compact structure forms the basis for transmitting global high-speed media streams. The exploration and utilization of more multi-dimensional information, coupled with advanced algorithms, presents the potential for developing next-generation all-optical parallel transmission systems.

More information:
Haogong Feng et al, Seeing at a distance with multicore fibers, Opto-Electronic Advances (2024). DOI: 10.29026/oea.2024.230202

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