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PhotUntangle

Financiado

Rendering the opaque transparent Untangling light with bespoke optical transfor...

Rendering the opaque transparent Untangling light with bespoke optical transforms to see through scattering environments When light propagates through an opaque material, such as living tissue or a multi-mode optical fibre, it fragments and scatters multiple times. The emergent wavefront no longer forms an image because the spatial information it ca... ver más

31/10/2024

UNEXE

2M€

Presupuesto del proyecto: 2M€

Líder del proyecto

THE UNIVERSITY OF EXETER No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

Ver 2 Participantes

Financiación concedida El organismo H2020 notifico la concesión del proyecto el día 2024-10-31

Línea de financiación objetivo El proyecto se financió a través de la siguiente ayuda:

ERC-2018-STG: ERC Starting Grant

I+D

Cerrada hace 7 años

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2 Participantes

UNEXE

1.79M€ | Lider

PINTURAS VILLADA SKC

401.19K€ | Participante

Últimas noticias

29-11-2024: IDAE En las últimas 48 horas el Organismo IDAE ha otorgado 4 concesiones

29-11-2024: ECE En las últimas 48 horas el Organismo ECE ha otorgado 2 concesiones

29-11-2024: CMVAMADRID En las últimas 48 horas el Organismo CMVAMADRID ha otorgado 37 concesiones

Duración del proyecto: 73 meses Fecha Inicio: 2018-09-21
Fecha Fin: 2024-10-31

Líder del proyecto

THE UNIVERSITY OF EXETER

TRL 4-5

Presupuesto del proyecto 2M€

Descripción del proyecto When light propagates through an opaque material, such as living tissue or a multi-mode optical fibre, it fragments and scatters multiple times. The emergent wavefront no longer forms an image because the spatial information it carries has been scrambled. Reversing this scattering offers the prospect of using visible light for high-resolution imaging of structures deep inside the human body in a safe, non-ionising way. It has recently been shown that this light scattering can be characterised and inverted. Yet arbitrary spatial mode inverters that can unscramble hundreds of light modes simultaneously to efficiently reform an image do not currently exist. The aim of this project is to understand how to design and build them. I will pioneer the use of focused lasers to write intricate nano-structures directly into glass. The key advancement will be to overcome extreme fabrication tolerances by employing a fluid design approach, whereby the design will be modified during the fabrication process. In parallel, I will develop dynamic transformers, capable of rapidly reprogrammable optical transformations. Further, I will create new computational techniques to overcome residual levels of crosstalk, and develop new ultra-fast scattering characterisation methods based on compressed sensing. This project will advance our fundamental understanding of how to control optical scattering in complex media. Key aims are to: - Understand how to design a new class of optical elements that can perform efficient spatial mode transforms on demand. - Build both passive spatial mode transformers to manipulate hundreds of modes simultaneously, and active transformers that can perform dynamically reconfigurable transformations at video-rates. - Apply this technology to unscramble light that has propagated through a moving multi-mode optical fibre in real-time, pushing towards ultra-thin micro-endoscopy, and explore an array of applications to next generation imaging systems and beyond.

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