Design and Simulation of Compound Eye Lens for Visible Light Communication and Illumination

We proposed a scheme for designing an optical launch system that can make the light intensity more uniform on the receiving plane via a compound eye lens combined with a sunflower plano-convex lens. )e simulation results demonstrate that the light converges on the optical axis after passing through the sunflower-shaped plano-convex lens array and compound eye lens. )e divergence angle and central light intensity of the receiving plane are, respectively, 26.57° and 80.50% of the total emitted light power for the array structure of the compact compound eye plano-convex lens, while those are 21.80° and 62.50% for the discrete compound eye lens. From the above results, it can be seen that the compact compound eye lens is more conducive to the uniform distribution of light intensity on the receiving plane compared with the discrete compound eye lens, taking into account the dual application of illumination and communication.


Introduction
Visible light communication (VLC) technology is an emerging wireless optical communication technology developed on the white light emitting diode (LED) technology of integration [14], it is necessary to design a lens group with a smaller volume and a higher light collection efficiency [15]. e compound eye is a kind of visual imaging method widely existing in nature. It has the advantages of large field of view, three-dimensional imaging, small aberrations, and miniaturization of the imaging system [16][17][18]. In this paper, the optimal design of the optical lens at the transmitting end of the visible light communication system is studied. e main research contents include designing a compound eye lens for the transmitting lens in the visible light communication system, changing the structure parameters of the compound eye lens, using the ray-tracing method to study its light collection efficiency and emission angle, and optimizing the design of the lens structure and parameters. Based on plano-convex microlenses, a compound eye planoconvex lens is designed. rough theoretical modeling, the lens structure parameters are optimized. e flat compound eye lens can be used as a transmitting lens in a visible light communication system, which reduces the requirements for the layout of the light source array.

Design of the Sunflower-Shaped Lens Array
For the simulation design of the sunflower-shaped 9-lamp bead LED array, it is planned to use a microlens array or a conventional lens on the sunflower-shaped 9-lamp bead LED array light board for primary light collection and then use a sunflower-shaped lens array for secondary light collection, and the lens optimizes the design to reduce the volume of the lens group while achieving high emission power and small emission angle, so as to adapt to the occasion with a higher degree of integration. Figure 1 shows the structure of the LED array and lens array. e package size of the LED lamp in the LED array is 3 mm × 3 mm, and the thickness of the microlens is 1.5 mm. e diameter of the designed lens array plate is 106 mm, and the thickness of the bottom plate is 2.5 mm. e radius of curvature of the front surface of the central lens is 17.1 mm, and the radius of curvature of the front surface of the outer lens is 16.6 mm.

Modeling and Simulation of Compound Eye Lens
In the simulation system, the sunflower-shaped lens array is simulated and analyzed by TracePro. e material of the compound eye lens is polymethyl methacrylate (PMMA). e center position of the LED array light board is used as the origin of the coordinates of the XY plane. e luminous flux of each LED is set to 1 watt, the light transmission distance is 50 cm, and the size of the detector's receiving surface is 50 cm × 50 cm square plane. Figure 2 is the effect diagram obtained by ray tracing the sunflower-shaped lens array. Figure 3 is the total-irradiance map diagram of the receiving surface of the sunflower-shaped plano-convex lens array. It can be seen from the figure that the light converges on the optical axis after passing through the sunflower-shaped plano-convex lens array, the light collection efficiency reaches 91.75%, and the divergence angle is greater than 11.31°. It shows that the sunflower-shaped planoconvex lens array can achieve better light convergence effect.
In the visible light communication system, in order to meet the application requirements of both lighting and communication, in the design of the lens array, we need to make the light distribution uniform while ensuring that the receiving end has sufficient light intensity. In this work, we designed a compound eye lens for the visible light communication system. Figure 4 shows the array structure diagram of a compound eye plano-convex lens and the ray-tracing renderings of the sunflower-shaped lens array and compound eye plano-convex lens. e design substrate diameter is 110 mm, the number of lenses in the compound eye lens array is 37, and the radius of curvature is 10 mm. e luminous flux of each LED is also set to 1 watt, the light transmission distance is 50 cm, and the size of the detector's receiving surface is 50 cm × 50 cm square plane. Figure 5 gives the total-irradiance map diagram of the receiving surface of the compound eye plano-convex lens and sunflower-shaped plano-convex lens array. It can be seen that the light converges on the optical axis after passing through the sunflower-shaped plano-convex lens array and compound eye lens. e light collection efficiency falls to 42.35%. e divergence angle is greater than 26.57°. e central light intensity of the receiving plane ranges from 75.00% to 80.50% of the total emitted light power for the array structure of the compact compound eye plano-convex lens. Although part of the light converged by the sunflower lens escapes the receiving range after being refracted by the compound eye lens, the light distribution at the receiving end is more uniform, which is more suitable for the application scenario where multiple discrete receivers receive simultaneously in multi-input multi-output (MIMO) visible light communication.
In order to further research the influence of the number of monocular lenses in the compound eye lens on the light collection efficiency and divergence angle, we compared the compound eye lens with 97 monocular lenses and 127 monocular lenses. Figure 6 gives the array structure diagram of a compound eye plano-convex lens with 97 monocular lenses and 127 monocular lenses. e radius of curvature is 5 mm. e design substrate diameter is 110 mm. Figures 7 and 8 show the total-irradiance map diagram of the receiving surface of the compound eye plano-convex lens and sunflower-shaped plano-convex lens array when the number of monocular lenses is 97 and 127. From Figure 7, it is evident that the light collection efficiency when the number of monocular lenses is 97 is 50.51% and the divergence angle is greater than 21.80°. e central light intensity of the receiving plane is 62.50% of the total emitted light power for the array structure of a compact compound eye plano-convex lens. From Figure 8, it is evident that the light collection efficiency when the number of monocular lenses is 127 is only 41.57% and the divergence angle is 2 Advances in Condensed Matter Physics  greater than 26.57°. From the light intensity distribution diagram of the receiving plane, it can be seen that the light is centered on the axis after the light emitted by the LED array passes through the sunflower lens and the compound eye plano-convex lens. From Figures 5 and 8, the divergence angle and central light intensity of the receiving plane of the array structure of the compound eye lens, as shown in Figures 4(a) and 6(b), are basically the same, approximately 26.57°and 75.00% to 80.50% of the total emitted light power. e light collection efficiency decreases slightly as the number of monocular lenses increases, while the light is more evenly distributed on the receiving plane. In Figure 7, the light collection efficiency of the array structure of the compound eye lens as shown in Figure 6

Conclusion
In this paper, we designed two types of compound eye lens combined with the sunflower plano-convex lens for lighting application and MIMO-VLC systems. e simulation demonstrated the light converges on the optical axis after passing through the sunflower-shaped plano-convex lens array and compound eye lens. From the results, the compact compound eye lens is beneficial to the uniform distribution of light intensity on the receiving plane compared with the discrete compound eye lens, giving consideration to the applications of illumination and communication.

Data Availability
No data were used to support this study.

Conflicts of Interest
e authors declare that they have no conflicts of interest.