A scalable photonic computer solving the subset sum problem

Xu, Xiaoyun; Huang, Xiaolin; Li, Zhanming; Gao, Jun; Jiao, Zhi-Qiang; Wang, Yao; Ren, Ruo-Jing; Zhang, Hepeng; Jin, Xian-Min

doi:10.1126/sciadv.aay5853

Cited by 42 publications

(42 citation statements)

References 47 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Several emerging possibilities have already been discussed by Morimoto and Baum (14) in their methods section. For example, research in nanophotonics strives for understanding and using the complex interactions of light with subwavelength structures for creating exceptional optical functionalities with metamaterials (34)(35)(36)(37)(38)(39), photonic integrated circuitry (40)(41)(42), or photocatalysts (43). Waveform electron microscopy (9) with subcycle time resolution can reveal this controlled imprint of phases, amplitudes, and polarizations onto the electromagnetic field cycles of light with subwavelength and subcycle precision.…”

Section: Discussionmentioning

confidence: 99%

Attosecond metrology in a continuous-beam transmission electron microscope

et al. 2020

View full text Add to dashboard Cite

Electron microscopy can visualize the structure of complex materials with atomic and subatomic resolution, but investigations of reaction dynamics and light-matter interaction call for time resolution as well, ideally on a level below the oscillation period of light. Here, we report the use of the optical cycles of a continuous-wave laser to bunch the electron beam inside a transmission electron microscope into electron pulses that are shorter than half a cycle of light. The pulses arrive at the target at almost the full average brightness of the electron source and in synchrony to the optical cycles, providing attosecond time resolution of spectroscopic features. The necessary modifications are simple and can turn almost any electron microscope into an attosecond instrument that may be useful for visualizing the inner workings of light-matter interaction on the basis of the atoms and the cycles of light.

show abstract

Section: Discussionmentioning

confidence: 99%

Attosecond metrology in a continuous-beam transmission electron microscope

et al. 2020

View full text Add to dashboard Cite

show abstract

“…13(e). 150 Furthermore, quantum polarization entangled states could be well topologically protected on a photonic chip, and the linking of photonic topology and quantum information opens the door to topological enhancement in the quantum regime. 153 Many other applications in the photonic topology and quantum information processing were also reported.…”

Section: Topological Physics and Quantum Information Processingmentioning

confidence: 99%

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

et al. 2021

View full text Add to dashboard Cite

Integrated photonics is attracting considerable attention and has found many applications in both classical and quantum optics, fulfilling the requirements for the ever-growing complexity in modern optical experiments and big data communication. Femtosecond (fs) laser direct writing (FLDW) is an acknowledged technique for producing waveguides (WGs) in transparent glass that have been used to construct complex integrated photonic devices. FLDW possesses unique features, such as three-dimensional fabrication geometry, rapid prototyping, and single step fabrication, which are important for integrated communication devices and quantum photonic and astrophotonic technologies. To fully take advantage of FLDW, considerable efforts have been made to produce WGs over a large depth with low propagation loss, coupling loss, bend loss, and highly symmetrical mode field. We summarize the improved techniques as well as the mechanisms for writing high-performance WGs with controllable morphology of cross-section, highly symmetrical mode field, low loss, and high processing uniformity and efficiency, and discuss the recent progress of WGs in photonic integrated devices for communication, topological physics, quantum information processing, and astrophotonics. Prospective challenges and future research directions in this field are also pointed out.

show abstract

“…The actual circuits we have verified here are physically manufactured to be populated with actin filaments or microtubules [4], although similar devices have been experimentally implemented for bacteria [27]. In [29], the SSP problem has been solved by the NBC approach using a laser photonic system rather than molecular motors as in [20]. Our computational methods and tools are applicable to all the variety of experimental implementation strategies currently developed for NBC and can also be extended to support future NBC technology.…”

Section: Related Workmentioning

confidence: 99%

Formal Semantics and Verification of Network-Based Biocomputation Circuits

Aluf-Medina

Korten

Raviv

et al. 2021

Lecture Notes in Computer Science

View full text Add to dashboard Cite

Network-Based Biocomputation Circuits (NBCs) offer a new paradigm for solving complex computational problems by utilizing biological agents that operate in parallel to explore manufactured planar devices. The approach can also have future applications in diagnostics and medicine by combining NBCs computational power with the ability to interface with biological material. To realize this potential, devices should be designed in a way that ensures their correctness and robust operation. For this purpose, formal methods and tools can offer significant advantages by allowing investigation of design limitations and detection of errors before manufacturing and experimentation. Here we define a computational model for NBCs by providing formal semantics to NBC circuits. We present a formal verification-based approach and prototype tool that can assist in the design of NBCs by enabling verification of a given design’s correctness. Our tool allows verification of the correctness of NBC designs for several NP-Complete problems, including the Subset Sum, Exact Cover and Satisfiability problems and can be extended to other NBC implementations. Our approach is based on defining transition systems for NBCs and using temporal logic for specifying and proving properties of the design using model checking. Our formal model can also serve as a starting point for computational complexity studies of the power and limitations of NBC systems.

show abstract

A scalable photonic computer solving the subset sum problem

Cited by 42 publications

References 47 publications

Attosecond metrology in a continuous-beam transmission electron microscope

Attosecond metrology in a continuous-beam transmission electron microscope

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

Formal Semantics and Verification of Network-Based Biocomputation Circuits

Contact Info

Product

Resources

About