Multimode fibers(MMFs)are a promising solution for high-throughput signal transmission in the time domain.However,crosstalk among different optical modes within the MMF scrambles input information and creates seemingl...Multimode fibers(MMFs)are a promising solution for high-throughput signal transmission in the time domain.However,crosstalk among different optical modes within the MMF scrambles input information and creates seemingly random speckle patterns at the output.To characterize this process,a transmission matrix(TM)can be used to relate input and output fields.Recent innovations use TMs to manipulate the output field by shaping the input wavefront for exciting advances in deep-brain imaging,neuron stimulation,quantum networks,and analog operators.However,these approaches consider input/output segments as independent,limiting their use for separate signal processing,such as logic operations.Our proposed method,which makes input/output segments as interdependent,adjusts the phase of corresponding output fields using phase bias maps superimposed on input segments.Coherent superposition enables signal logic operations through a 15-m-long MMF.In experiments,a single optical logic gate containing three basic logic functions and cascading multiple logic gates to handle binary operands is demonstrated.Bitwise operations are performed for multi-bit logic operations,and multiple optical logic gates are reconstructed simultaneously in a single logic gate with polarization multiplexing.The proposed method may open new avenues for long-range logic signal processing and transmission via MMFs.展开更多
Information retrieval from visually random optical speckle patterns is desired in many scenarios yet considered challenging.It requires accurate understanding or mapping of the multiple scattering process,or reliable ...Information retrieval from visually random optical speckle patterns is desired in many scenarios yet considered challenging.It requires accurate understanding or mapping of the multiple scattering process,or reliable capability to reverse or compensate for the scattering-induced phase distortions.In whatever situation,effective resolving and digitization of speckle patterns are necessary.Nevertheless,on some occasions,to increase the acquisition speed and/or signal-to-noise ratio(SNR),speckles captured by cameras are inevitably sampled in the sub-Nyquist domain via pixel binning(one camera pixel contains multiple speckle grains)due to finite size or limited bandwidth of photosensors.Such a down-sampling process is irreversible;it undermines the fine structures of speckle grains and hence the encoded information,preventing successful information extraction.To retrace the lost information,super-resolution interpolation for such sub-Nyquist sampled speckles is needed.In this work,a deep neural network,namely SpkSRNet,is proposed to effectively up sample speckles that are sampled below 1/10 of the Nyquist criterion to well-resolved ones that not only resemble the comprehensive morphology of original speckles(decompose multiple speckle grains from one camera pixel)but also recover the lost complex information(human face in this study)with high fidelity under normal-and low-light conditions,which is impossible with classic interpolation methods.These successful speckle super-resolution interpolation demonstrations are essentially enabled by the strong implicit correlation among speckle grains,which is non-quantifiable but could be discovered by the well-trained network.With further engineering,the proposed learning platform may benefit many scenarios that are physically inaccessible,enabling fast acquisition of speckles with sufficient SNR and opening up new avenues for seeing big and seeing clearly simultaneously in complex scenarios.展开更多
Optical imaging through or inside scattering media, such as multimode fiber and biological tissues, has a significant impact in biomedicine yet is considered challenging due to the strong scattering nature of light. I...Optical imaging through or inside scattering media, such as multimode fiber and biological tissues, has a significant impact in biomedicine yet is considered challenging due to the strong scattering nature of light. In the past decade, promising progress has been made in the field, largely benefiting from the invention of iterative optical wavefront shaping, with which deep-tissue high-resolution optical focusing and hence imaging becomes possible. Most of the reported iterative algorithms can overcome small perturbations on the noise level but fail to effectively adapt beyond the noise level, e.g., sudden strong perturbations. Reoptimizations are usually needed for significant decorrelation to the medium since these algorithms heavily rely on the optimization performance in the previous iterations. Such ineffectiveness is probably due to the absence of a metric that can gauge the deviation of the instant wavefront from the optimum compensation based on the concurrently measured optical focusing.In this study, a square rule of binary-amplitude modulation, directly relating the measured focusing performance with the error in the optimized wavefront, is theoretically proved and experimentally validated. With this simple rule, it is feasible to quantify how many pixels on the spatial light modulator incorrectly modulate the wavefront for the instant status of the medium or the whole system. As an example of application, we propose a novel algorithm, the dynamic mutation algorithm, which has high adaptability against perturbations by probing how far the optimization has gone toward the theoretically optimal performance. The diminished focus of scattered light can be effectively recovered when perturbations to the medium cause a significant drop in the focusing performance, which no existing algorithms can achieve due to their inherent strong dependence on previous optimizations. With further improvement, the square rule and the new algorithm may boost or inspire many applications, such as high-resolution optical imaging and stimulation, in instable or dynamic scattering environments.展开更多
Optical techniques offer a wide variety of applications as light-matter interactions provide extremely sensitive mechanisms to probe or treat target media.Most of these implementations rely on the usage of ballistic o...Optical techniques offer a wide variety of applications as light-matter interactions provide extremely sensitive mechanisms to probe or treat target media.Most of these implementations rely on the usage of ballistic or quasi-ballistic photons to achieve high spatial resolution.However,the inherent scattering nature of light in biological tissues or tissue-like scattering media constitutes a critical obstacle that has restricted the penetration depth of non-scattered photons and hence limited the implementation of most optical techniques for wider applications.In addition,the components of an optical system are usually designed and manufactured for a fixed function or performance.Recent advances in wavefront shaping have demonstrated that scattering-or component-induced phase distortions can be compensated by optimizing the wavefront of the input light pattern through iteration or by conjugating the transmission matrix of the scattering medium.展开更多
As an outstanding two-dimensional material,black phosphorene,has attracted significant attention in the biomedicine field due to its large surface area,strong optical absorption,distinct bioactivity,excellent biocompa...As an outstanding two-dimensional material,black phosphorene,has attracted significant attention in the biomedicine field due to its large surface area,strong optical absorption,distinct bioactivity,excellent biocompatibility,and high biodegradability.In this review,the preparation and properties of black phosphorene are summarized first.Thereafter,black phosphorene-based multifunctional platforms employed for the diagnosis and treatment of diseases,including cancer,bone injuries,brain diseases,progressive oxidative diseases,and kidney injury,are reviewed in detail.This review provides a better understanding of the exciting properties of black phosphorene,such as its high drug-loading efficiency,photothermal conversion capability,high'O2 generation efficiency,and high electrical conductivity,as well as how these properties can be exploited in biomedicine.Finally,the research perspectives of black phosphorene are discussed.展开更多
基金The Hong Kong Polytechnic University(P0038180,P0039517,P0043485,P0045762)Shenzhen Science and Technology Innovation Program(JCYJ20220818100202005)+3 种基金Guangdong Science and Technology Department(2019BT02X105)Hong Kong Research Grant Council(15217721,C7074-21GF,R5029-19)Innovation and Technology Commission(GHP/043/19SZ,GHP/044/19GD)National Natural Science Foundation of China(81930048)。
文摘Multimode fibers(MMFs)are a promising solution for high-throughput signal transmission in the time domain.However,crosstalk among different optical modes within the MMF scrambles input information and creates seemingly random speckle patterns at the output.To characterize this process,a transmission matrix(TM)can be used to relate input and output fields.Recent innovations use TMs to manipulate the output field by shaping the input wavefront for exciting advances in deep-brain imaging,neuron stimulation,quantum networks,and analog operators.However,these approaches consider input/output segments as independent,limiting their use for separate signal processing,such as logic operations.Our proposed method,which makes input/output segments as interdependent,adjusts the phase of corresponding output fields using phase bias maps superimposed on input segments.Coherent superposition enables signal logic operations through a 15-m-long MMF.In experiments,a single optical logic gate containing three basic logic functions and cascading multiple logic gates to handle binary operands is demonstrated.Bitwise operations are performed for multi-bit logic operations,and multiple optical logic gates are reconstructed simultaneously in a single logic gate with polarization multiplexing.The proposed method may open new avenues for long-range logic signal processing and transmission via MMFs.
基金Agency for Science,Technology and Research(A18A7b0058)Innovation and Technology Commission(GHP/043/19SZ,GHP/044/19GD)+2 种基金Hong Kong Research Grant Council(15217721,C5078-21EF,R5029-19)Guangdong Science and Technology Department(2019A1515011374,2019BT02X105)National Natural Science Foundation of China(81627805,81930048)。
文摘Information retrieval from visually random optical speckle patterns is desired in many scenarios yet considered challenging.It requires accurate understanding or mapping of the multiple scattering process,or reliable capability to reverse or compensate for the scattering-induced phase distortions.In whatever situation,effective resolving and digitization of speckle patterns are necessary.Nevertheless,on some occasions,to increase the acquisition speed and/or signal-to-noise ratio(SNR),speckles captured by cameras are inevitably sampled in the sub-Nyquist domain via pixel binning(one camera pixel contains multiple speckle grains)due to finite size or limited bandwidth of photosensors.Such a down-sampling process is irreversible;it undermines the fine structures of speckle grains and hence the encoded information,preventing successful information extraction.To retrace the lost information,super-resolution interpolation for such sub-Nyquist sampled speckles is needed.In this work,a deep neural network,namely SpkSRNet,is proposed to effectively up sample speckles that are sampled below 1/10 of the Nyquist criterion to well-resolved ones that not only resemble the comprehensive morphology of original speckles(decompose multiple speckle grains from one camera pixel)but also recover the lost complex information(human face in this study)with high fidelity under normal-and low-light conditions,which is impossible with classic interpolation methods.These successful speckle super-resolution interpolation demonstrations are essentially enabled by the strong implicit correlation among speckle grains,which is non-quantifiable but could be discovered by the well-trained network.With further engineering,the proposed learning platform may benefit many scenarios that are physically inaccessible,enabling fast acquisition of speckles with sufficient SNR and opening up new avenues for seeing big and seeing clearly simultaneously in complex scenarios.
基金National Key Research and Development Program of China(2017YFA0700401)National Natural Science Foundation of China(81627805,81671726,81827808,81930048)+4 种基金Research Grants Council,University Grants Committee(25204416)Innovation and Technology Commission(GHP/043/19SZ,GHP/044/19GD,ITS/022/18)Guangdong Science and Technology Department(2019A1515011374,2019BT02X105)Science,Technology and Innovation Commission of Shenzhen Municipality(JCYJ20170818104421564)Youth Innovation Promotion Association of the Chinese Academy of Sciences(2018167)。
文摘Optical imaging through or inside scattering media, such as multimode fiber and biological tissues, has a significant impact in biomedicine yet is considered challenging due to the strong scattering nature of light. In the past decade, promising progress has been made in the field, largely benefiting from the invention of iterative optical wavefront shaping, with which deep-tissue high-resolution optical focusing and hence imaging becomes possible. Most of the reported iterative algorithms can overcome small perturbations on the noise level but fail to effectively adapt beyond the noise level, e.g., sudden strong perturbations. Reoptimizations are usually needed for significant decorrelation to the medium since these algorithms heavily rely on the optimization performance in the previous iterations. Such ineffectiveness is probably due to the absence of a metric that can gauge the deviation of the instant wavefront from the optimum compensation based on the concurrently measured optical focusing.In this study, a square rule of binary-amplitude modulation, directly relating the measured focusing performance with the error in the optimized wavefront, is theoretically proved and experimentally validated. With this simple rule, it is feasible to quantify how many pixels on the spatial light modulator incorrectly modulate the wavefront for the instant status of the medium or the whole system. As an example of application, we propose a novel algorithm, the dynamic mutation algorithm, which has high adaptability against perturbations by probing how far the optimization has gone toward the theoretically optimal performance. The diminished focus of scattered light can be effectively recovered when perturbations to the medium cause a significant drop in the focusing performance, which no existing algorithms can achieve due to their inherent strong dependence on previous optimizations. With further improvement, the square rule and the new algorithm may boost or inspire many applications, such as high-resolution optical imaging and stimulation, in instable or dynamic scattering environments.
基金supported by National Natural Science Foundation of China(NSFC)(81930048,81627805)Hong Kong Research Grant Council(15217721,R5029-19,C7074-21GF)+3 种基金Hong Kong Innovation and Technology Commission(GHP/043/19SZ,GHP/044/19GD)Guangdong Science and Technology Commission(2019A1515011374,2019BT02X105)National Research Foundation of Korea(2015R1A3A2066550,2021R1A2C3012903)Institute of Information&Communications Technology Planning&Evaluation(IITP,2021-0-00745)grant funded by the Korea government(MSIT).
文摘Optical techniques offer a wide variety of applications as light-matter interactions provide extremely sensitive mechanisms to probe or treat target media.Most of these implementations rely on the usage of ballistic or quasi-ballistic photons to achieve high spatial resolution.However,the inherent scattering nature of light in biological tissues or tissue-like scattering media constitutes a critical obstacle that has restricted the penetration depth of non-scattered photons and hence limited the implementation of most optical techniques for wider applications.In addition,the components of an optical system are usually designed and manufactured for a fixed function or performance.Recent advances in wavefront shaping have demonstrated that scattering-or component-induced phase distortions can be compensated by optimizing the wavefront of the input light pattern through iteration or by conjugating the transmission matrix of the scattering medium.
基金This work was supported in part by the National Natural Science Foundation of China(NSFC)(Grant Nos.8193004&81627805,and 81671726)Guangdong Science and Technology Commission(Nos.2019BT02X105,2019A1515011374)+4 种基金Hong Kong Research Grant Council(Nos.25204416,R5029-19)Hong Kong Innovation and Technology Commission(Nos.ITS/022/18,GHP/043/19SZ,GHP/044/19GD)Shenzhen Science and Technology Innovation Commission(No.JCYJ20170818104421564)Guangdong Basic and Applied Basic Research Foundation for Distinguished Young Scholars(No.2020B1515020027)Guangzhou Science and Technology Bureau(No.202002020070).
文摘As an outstanding two-dimensional material,black phosphorene,has attracted significant attention in the biomedicine field due to its large surface area,strong optical absorption,distinct bioactivity,excellent biocompatibility,and high biodegradability.In this review,the preparation and properties of black phosphorene are summarized first.Thereafter,black phosphorene-based multifunctional platforms employed for the diagnosis and treatment of diseases,including cancer,bone injuries,brain diseases,progressive oxidative diseases,and kidney injury,are reviewed in detail.This review provides a better understanding of the exciting properties of black phosphorene,such as its high drug-loading efficiency,photothermal conversion capability,high'O2 generation efficiency,and high electrical conductivity,as well as how these properties can be exploited in biomedicine.Finally,the research perspectives of black phosphorene are discussed.
