Intelligent coding metasurface is a kind of information-carrying metasurface that can manipulate electromagnetic waves and associate digital information simultaneously in a smart way. One of its widely explored applications is to develop advanced schemes of dynamic holographic imaging. By now, the controlling coding sequences of the metasurface are usually designed by performing iterative approaches, including the Gerchberg–Saxton (GS) algorithm and stochastic optimization algorithm, which set a large barrier on the deployment of the intelligent coding metasurface in many practical scenarios with strong demands on high efficiency and capability. Here, we propose an efficient non-iterative algorithm for designing intelligent coding metasurface holograms in the context of unsupervised conditional generative adversarial networks (cGANs), which is referred to as physics-driven variational auto-encoder (VAE) cGAN (VAE-cGAN). Sharply different from the conventional cGAN with a harsh requirement on a large amount of manual-marked training data, the proposed VAE-cGAN behaves in a physics-driving way and thus can fundamentally remove the difficulties in the conventional cGAN. Specifically, the physical operation mechanism between the electric-field distribution and metasurface is introduced to model the VAE decoding module of the developed VAE-cGAN. Selected simulation and experimental results have been provided to demonstrate the state-of-the-art reliability and high efficiency of our VAE-cGAN. It could be faithfully expected that smart holograms could be developed by deploying our VAE-cGAN on neural network chips, finding more valuable applications in communication, microscopy, and so on.
Intelligent coding metasurface holograms by physics-assisted unsupervised generative adversarial net
【摘 要】
:
Intelligent coding metasurface is a kind of information-carrying metasurface that can manipulate electromagnetic waves and associate digital information simultaneously in a smart way. One of its widely explored applications is to develop advanced schem
【机 构】
:
InstituteofElectromagneticSpace,SoutheastUniversity,Nanjing210096,ChinaStateKeyLaboratoryofMillimete
【出 处】
:
PhotonicsResearch
【发表日期】
:
2021年9期
论文部分内容阅读
其他文献
X射线激光器仍然是一个高度秘密,据推测这是因为和军事应用有重大利害关系的缘故。然而,现在人们正在公开谈论建立波长并不是十分短的其它新型激光器(其军事应用较小)的计划,其目标是在几十毫微米量级的波长上产生激光发射,这样的波长较之超级机密的1.4毫微米X射线激光的波长要长10倍或更多。据说1.4毫微米X射线激光器已为利弗莫尔实验室的研究者所演示过。尽管通常把上述较长的波长看作“超紫外”部分,然而X射线波段的界限本是较模糊的,况且有一些研究人员已经习惯于把这样的波长称为X射线一这种习惯将有助于使它们得到比人们可
期刊
基于耦合模理论,研究了镀吸收型薄膜长周期光纤光栅(LPFG)的模式转换及其折射率响应特性。讨论了镀膜LPFG包层模有效折射率随薄膜厚度的响应特性,从模场分布和波导传输本质上统一了模式转换与模式跳变两种表述。在此基础上分析了镀吸收型薄膜情形下LPFG包层模有效折射率实部与虚部随膜厚及薄膜折射率的变化,给出并解释了高阶和低阶包层模发生的一步、二步模式转换情况,进一步考察了薄膜消光系数对模式转换区域的影响。结果表明,薄膜消光系数对模式转换区域变化的影响很小。最后研究了转换区及其附近区域的镀吸收型膜LPFG透射谱
The images recorded by a ground-based telescope are often degraded by atmospheric turbulence and the aberration of the optical system. Phase diversity-based blind deconvolution is an effective post-processing method that can be used to overcome the turbul
Output nonlocality and nonclassicality for the two modes are investigated in an entanglement laser system. Within the framework of a quantum theory of multiwave mixing, nonlocality and nonclassicality are discussed according to the violations of Bell ineq
本文首次报道了氩离子激光在溶胶CdS半导体毫微晶中产生的自聚焦、热自散焦及自位相调制,实验测得此种材料具有很大的克尔(Kerr)非线性系数n2,比CS2大105倍。并且,文中还分析了这种具有弱吸收的半导体溶胶毫微晶的非线性自位相调制机理及其与热自位相调制的差别。
采用激光-电阻复合焊接LF6铝合金,对焊接特性进行研究。通过激光和电阻热源相互作用,接头熔深和焊缝面积显著增加,实现了在小功率激光条件下铝合金熔透焊接,提高了焊接生产率,降低了焊接成本。与激光焊接相比,激光-电阻复合焊接铝合金接头中的气孔数量大幅下降。激光-电阻复合焊接的焊缝区的强化β(Al8Mg5)相弥散分布,呈铸态组织特征,热影响区(HAZ)的强化β相聚集长大。接头在焊缝断裂,呈韧性剪切断裂,平均抗拉强度可达292 MPa,约为母材的83.4%。
计算表明,Sc18 和Ti19 的5f—3d和5d—3p跃迁波长处于水窗当中.进而,详尽地计算了这两个元素类锂离子的精细能级(n≤12,l≤5)及它们间的辐射跃迁几率.
Microwave photonic components and subsystems can replace or complement their electronic counterparts with a net gain in functionality, bandwidth, size, mass, complexity, and cost, facilitating the innovative implementation of radio frequency (RF) syste
期刊