Miniature curved artificial compound eyes

Floreano, Dario; Pericet-Cámara, Ramón; Viollet, Stéphane; Ruffier, Franck; Brückner, Andreas; Leitel, Robert; Buss, W.; Menouni, M.; Expert, Fabien; Juston, Raphaël; Dobrzynski, Michal Karol; L'Eplattenier, Géraud; Recktenwald, Fabian; Mallot, Hanspeter A.; Franceschini, Nicolas

doi:10.1073/pnas.1219068110

Cited by 297 publications

(240 citation statements)

References 42 publications

(42 reference statements)

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“…Similarly, specialized micro optic flow sensors have been used for altitude regulation in sub-1 g flying robots 70 . Miniature, curved, artificial compound eyes with a high density of photoreceptors, wide fields of view and computational properties similar to insect eyes have been recently described 71,72 , but have not yet been used in drones.…”

Section: Review Insightmentioning

confidence: 99%

Science, technology and the future of small autonomous drones

Floreano

Wood

2015

Nature

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996

510

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Drones, a popular nickname for unmanned aerial vehicles and micro aerial vehicles, often conjure up images of unmanned aeroplanes that fly thousands of miles for espionage and to deploy munitions. However, over the past few years, an increasing number of public and private research laboratories have been working on small, human-friendly drones that one day may autonomously fly in confined spaces and in close proximity to people. The development of these small drones, which is the main focus of this Review, has been supported by the miniaturization and cost reduction of electronic components (microprocessors, sensors, batteries and wireless communication units), largely driven by the portable electronic device industry. These improvements have enabled the prototyping and commercialization of small (typically less than 1 kg) drones at smartphone prices.Small drones will have important socio-economic impacts (Fig. 1). Images from drones that are capable of flying a few metres above the ground will fill a gap between expensive, weather-dependent and lowresolution images provided by satellites and car-based images limited to human-level perspectives and the availability of accessible roads. Specialized flying cameras and cloud-based data analytics will allow farmers to continuously monitor the quality of crop growth. Such platforms will enable construction companies to measure work progress in real time. Drones will let mining companies obtain precise volumetric data of excavations. Energy and infrastructure companies will be able to exhaustively survey pipelines, roads and cables. Humanitarian organizations could immediately assess and adapt aid efforts in continuously changing refugee camps. Transportation drones that are capable of safely taking off and landing in the proximity of buildings and humans will allow developing countries -without a suitable road network -to rapidly deliver goods and to finally unleash the full potential of their e-commerce telecommunication infrastructure. Transportation drones will also help developed countries to improve the quality of service in congested or remote areas, and will enable rescue organizations to quickly deliver medical supplies in the field and on demand. Inspection drones that are capable of flying in confined spaces will help fire-fighting and emergency units to assess dangers faster and more safely, logistic companies to detect cracks in the inner and outer shells of ships, road maintenance companies to measure signs of wear and tear in bridges and tunnels, security companies to improve building safety by monitoring areas outside the range of surveillance cameras, and disaster mitigation agencies to inspect partially collapsed buildings where ground clutter is an obstacle for terrestrial robots. Coordinated teams of autonomous drones will enable missions that last longer than the flight time of a single drone by allowing some drones to temporarily leave the team for battery replacement. Drone teams will permit rescue organizations to quickly deploy dedicated commu...

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Section: Review Insightmentioning

confidence: 99%

Science, technology and the future of small autonomous drones

Floreano

Wood

2015

Nature

Self Cite

996

510

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“…All parameters displayed here are in the unit of waves. Another fascinating feature of our device lies in its ability to achieve a wide angle (FOV) of 152° enabled by the spherical geometry across the longitudinal axis [25,26], as demonstrated in Figure 6c The FOV measurement started with the sequential illumination of our device placed on a fixed stage at the center of the circular rotating breadboard (RBB12, Thorlabs) by a He-Ne laser mounted on the circumference (see Figure 5b for the system set-up). Three focused line images captured from three different angles, −76° (left), 0° (center), and 76° (right), in one dynamic scan were selected to represent the total 152° viewing angle.…”

Section: Resultsmentioning

confidence: 99%

Bio-Inspired Wide-Angle Broad-Spectrum Cylindrical Lens Based on Reflections from Micro-Mirror Array on a Cylindrical Elastomeric Membrane

Huang

Jiang

2014

Micromachines

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Abstract:We present a wide-angle, broad-spectrum cylindrical lens based on reflections from an array of three-dimensional, high-aspect-ratio micro-mirrors fabricated on a cylindrical elastomeric substrate, functionally inspired by natural reflecting superposition compound eyes. Our device can perform one-dimensional focusing and beam-shaping comparable to conventional refraction-based cylindrical lenses, while avoiding chromatic aberration. The focal length of our cylindrical lens is 1.035 mm, suitable for micro-optical systems. Moreover, it demonstrates a wide field of view of 152° without distortion, as well as modest spherical aberrations. Our work could be applied to diverse applications including laser diode collimation, barcode scanning, holography, digital projection display, microlens arrays, and optical microscopy.

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“…Compared with simple vertebrate eyes, compound eyes are compact and lightweight, providing a wide field of view with high temporal resolution, given their tiny packaging [25]. Mimicking these properties in cameras and sensors is giving way to a new generation of imaging technology.…”

Section: (A) Cameras and Sensorsmentioning

confidence: 99%

“…Mimicking these properties in cameras and sensors is giving way to a new generation of imaging technology. Recently, we have seen the invention of a 'bee-eye' camera with a 280-degree field of view (figure 1c,d; [26]), a miniature curved artificial compound eye [25], a digital camera covered with 180 artificial ommatidia, inspired by eyes of fire ants Solenopsis fugax and bark beetles Hylastes nigrinus [27], and the development of hyperacute visual sensors based on retinal micro-movements in flies [28]. This new fleet of imaging technology has important consequences for surveillance, medical endoscopy, smart clothing, robotics and drones [24,25,29].…”

Section: (A) Cameras and Sensorsmentioning

confidence: 99%

Animal coloration research: why it matters

Caro

Stoddard

Stuart‐Fox

2017

Phil. Trans. R. Soc. B

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While basic research on animal coloration is the theme of this special edition, here we highlight its applied significance for industry, innovation and society. Both the nanophotonic structures producing stunning optical effects and the colour perception mechanisms in animals are extremely diverse, having been honed over millions of years of evolution for many different purposes. Consequently, there is a wealth of opportunity for biomimetic and bioinspired applications of animal coloration research, spanning colour production, perception and function. Fundamental research on the production and perception of animal coloration is contributing to breakthroughs in the design of new materials (cosmetics, textiles, paints, optical coatings, security labels) and new technologies (cameras, sensors, optical devices, robots, biomedical implants). In addition, discoveries about the function of animal colour are influencing sport, fashion, the military and conservation. Understanding and applying knowledge of animal coloration is now a multidisciplinary exercise. Our goal here is to provide a catalyst for new ideas and collaborations between biologists studying animal coloration and researchers in other disciplines.

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Miniature curved artificial compound eyes

Cited by 297 publications

References 42 publications

Science, technology and the future of small autonomous drones

Science, technology and the future of small autonomous drones

Bio-Inspired Wide-Angle Broad-Spectrum Cylindrical Lens Based on Reflections from Micro-Mirror Array on a Cylindrical Elastomeric Membrane

Animal coloration research: why it matters

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