Hola,
Are you new here?

I have an account

¿Te ayudamos?

Ejemplos de búsqueda

Vídeos Explicativos

DIRECTS

financed

Closed

Direct Temporal Synthesis of Terahertz Light Fields Enabling Novel Computational...

Direct Temporal Synthesis of Terahertz Light Fields Enabling Novel Computational Imaging The terahertz (THz) frequency range is widely considered as the most challenging and under-developed frequency range due to the lack of technologies to effectively bridge the transition region between microwaves (below 100 GHz) an... see more

30/09/2026

BUW

2M€

Project Budget: 2M€

Project leader

BERGISCHE UNIVERSITAET WUPPERTAL No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

PARTICIPATION DEPralty Sin fecha límite de participación.

Ver 2 Participantes

Financing granted El organismo H2020 notifico la concesión del proyecto The day 2021-07-21

ERC-2020-ADG: ERC ADVANCED GRANT Specific Challenge:Objectives

I+D

Cerrada does 4 years

0% 100% 100%

characteristics of the participant

Este proyecto no cuenta con búsquedas de partenariado abiertas en este momento.

Private Information

No hay información privada compartida para este proyecto. Habla con el coordinador.

2 Participantes

BUW

2.48M€ | Leader

GALOL

147.00K€ | participant

Conecta tu I+D

¿Tienes un proyecto y buscas un partner? Gracias a nuestro motor inteligente podemos recomendarte los mejores socios y ponerte en contacto con ellos. Te lo explicamos en este video

Project duration: 62 months Date Start: 2021-07-21
End date: 2026-09-30

Project leader

BERGISCHE UNIVERSITAET WUPPERTAL No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

Project Budget 2M€

participation deadline Sin fecha límite de participación.

Project description The terahertz (THz) frequency range is widely considered as the most challenging and under-developed frequency range due to the lack of technologies to effectively bridge the transition region between microwaves (below 100 GHz) and optics (above 10,000 GHz). Although THz radiation would be perfect for material identification and as a safe alternative to X-rays for producing high resolution images of the interior of opaque objects, first a fundamentally new approach is needed to establish novel devices and techniques. Rarely considered for its complexity, the so-called light field consists of all light rays in 3-D space, flowing through every point and in every direction. Thus a light field camera not only records color and brightness like a 2-D imaging sensor does, but also the direction/angle of all the light rays arriving at the sensor. The beauty of this spatio-directional information is that one can localize hidden objects and calculate their covered three-dimensional shape. So what’s the catch? For any practical means, the natural ambient THz radiation is by far too weak, and THz light-fields need to be created artificially. Here I propose an innovative pathway empowered by massively scaled THz source and detector arrays, which will bring forth the science of computational light-fields to THz 3-D see-through imaging. Starting with newfangled THz source-arrays, I create the missing temporal modulated light-fields directly at the source and investigate a diffraction inclusive THz light-field system theory, architecture and algorithms. This is combined with innovative THz integrated circuits to research real-time THz light-field components. Although the far-reaching objectives incorporate a high risk due to the complexity of the approach connecting physical, computational, and optical sciences with engineering approaches, this is offset by the promise of major breakthroughs to create substantial value for both science and the global economy.

Conecta tu I+D

Entra hoy

Forgot your password?

Financing

Companies

CTIs/Universidades

Projects

researchers