计算机科学
解调
调制(音乐)
编码(内存)
符号(正式)
电子工程
语义学(计算机科学)
通信系统
人工智能
光通信
光谱效率
多模光纤
语义鸿沟
光纤
理论计算机科学
频道(广播)
字错误率
网络数据包
语义压缩
解码方法
钥匙(锁)
算法
误码率
语音识别
语义网络
灵活性(工程)
作者
Yuxuan Xiong,Ziwen Zhou,Jianhong Ren,Jingze Liu,Zheng Gao,Ting Jiang,Xuchen Hua,Gang Yao,Yuqi Li,Mingming Zhang,Hao Wu,Siqi Yan,Ming Tang
出处
期刊:Advanced photonics
[SPIE - International Society for Optical Engineering]
日期:2026-04-10
卷期号:8 (03)
标识
DOI:10.1117/1.ap.8.3.036001
摘要
The growing demands of artificial intelligence and immersive media require communication beyond bit-level accuracy to meaning awareness. Conventional optical systems that focused on syntactic precision suffer significant inefficiencies. Here, we introduce a multi-dimensional semantic communication framework that bridges this gap by directly mapping high-level semantic features onto the orthogonal physical dimensions of light, frequency, polarization, and intensity, within a multimode fiber. This synergistic co-design of semantic logic and the photonic channel achieve an unprecedented equivalent spectral efficiency approaching 1000 bit/s/Hz. Moreover, it demonstrates profound resilience, maintaining high-fidelity reconstruction even when the physical-layer symbol error rate exceeds 36%, a condition under which conventional communication systems fail completely. Crucially, this deeply integrated co-design of semantic encoding and physical-layer modulation enables full semantic demodulation with only single-ended intensity detection, therefore significantly reducing system complexity and cost. This work establishes a validated pathway toward hyper-efficient, error-resilient optical networks for the next generation of data-intensive computing.
科研通智能强力驱动
Strongly Powered by AbleSci AI