Simplistic framework of single-pixel-programmable metasurfaces integrated with a capsuled LED array

Yuxi Li; Jiafu Wang; Sai Sui; Ruichao Zhu; Yajuan Han; Hongya Chen; Xinmin Fu; Shaojie Wang; Cunqian Feng; Shaobo Qu

doi:10.1364/PRJ.506044

Journals >Photonics Research >Volume 12 >Issue 5 >Page 884 > Article

Photonics Research
Vol. 12, Issue 5, 884 (2024)

Simplistic framework of single-pixel-programmable metasurfaces integrated with a capsuled LED array

Yuxi Li¹, Jiafu Wang^1、*, Sai Sui^1、3, Ruichao Zhu^1、4, Yajuan Han¹, Hongya Chen¹, Xinmin Fu¹, Shaojie Wang¹, Cunqian Feng², and Shaobo Qu^1、5

Author Affiliations

¹Shaanxi Key Laboratory of Artificially-Structured Functional Materials and Devices, Air Force Engineering University, Xi’an 710051, China

²Air and Missile Defense College, Air Force Engineering University, Xi’an 710051, China

³e-mail: suisai_mail@foxmail.com

⁴e-mail: zhuruichao1996@163.com

⁵e-mail: Qushaobo@mail.xjtu.edu.cn

show less

DOI: 10.1364/PRJ.506044 Cite this Article Set citation alerts

Yuxi Li, Jiafu Wang, Sai Sui, Ruichao Zhu, Yajuan Han, Hongya Chen, Xinmin Fu, Shaojie Wang, Cunqian Feng, Shaobo Qu. Simplistic framework of single-pixel-programmable metasurfaces integrated with a capsuled LED array[J]. Photonics Research, 2024, 12(5): 884 Copy Citation Text

EndNote(RIS)

BibTex

Plain Text

show less

Fig. 1. Schematic diagram of the principle of SPPM and its application.

Download full size | View in the Article

Dynamic meta-atom: (a)–(c) structure diagram and geometric parameters; (d) simulated reflection amplitude in the “0,” “1” states; (e) simulated reflection phase in the “0,” “1” states; (f), (g) surface current distribution in the “0,” “1” states.

Fig. 2. Dynamic meta-atom: (a)–(c) structure diagram and geometric parameters; (d) simulated reflection amplitude in the “0,” “1” states; (e) simulated reflection phase in the “0,” “1” states; (f), (g) surface current distribution in the “0,” “1” states.

Download full size | View in the Article

Fig. 3. Simulation diagram: (a)–(c) distribution diagrams of meta-atom state for different coding sequences; (d)–(f) far-field scattering pattern for theory of different coding sequences; (h)–(i) far-field scattering pattern for simulation of different coding sequences.

Download full size | View in the Article

Fig. 4. Diagram of the experiment setup: (a) experimental sample; (b) LED array; (c) device connection diagram; (d) diagram of S-parameter experimental measurement devices; (e) diagram of far-field scattering pattern experimental measurement devices.

Download full size | View in the Article

Fig. 5. Experimental measurement results: (a), (b) S-parameter measurement results; (c), (d) counterclockwise, clockwise measurement results of four beams; (e) measurement result of RCS reduction; (f) measurement result of vortex beam.

Download full size | View in the Article

Fig. 6. Simulation results: (a) amplitude at different resistance values; (b) phase at different resistance values.

Download full size | View in the Article

Fig. 7. S-parameter simulation results under different structural parameters: (a), (b) S-parameter simulation results under different l1; (c), (d) S-parameter simulation results under different l2.

Download full size | View in the Article

Fig. 8. S-parameter simulation results under different device parameters: (a), (b) S-parameter simulation results under different inductances when the capacitance is 0.5 pF; (c), (d) simulation results of S-parameters under different capacitances when the inductance is 0.5 nH.

Download full size | View in the Article

Fig. 9. Phase distribution and two-dimensional far-field scattering pattern of different EM functions: (a), (b) four beams; (c), (d) RCS reduction; (e), (f) vortex beam.

Download full size | View in the Article