← Volver a resultados
Ficha bibliográfica · Consulta y acceso
Artículo

Inverse design of organic light-emitting diode structure based on deep neural networks

Kim Sanmun et al · Wiley · 2021

Acceso abierto disponible
Lectura rápida. Revisá los datos básicos del recurso y luego accedé al contenido desde el botón principal. En esta ficha solo se muestra la información necesaria para identificar la obra, citarla y abrirla.
Publicación seriada

3-D near-field imaging of guided modes in nanophotonic waveguides

Esta publicación seriada contiene 146 contenidos relacionados.

Acceso al recurso

Entrá al contenido desde la opción principal o elegí otra fuente disponible.

Acceso principal

Acceso abierto disponible

Recurso identificado como acceso abierto, sin confirmar automáticamente si es texto completo directo.
Abrir recurso

Resumen

Descripción general del contenido del recurso.

The optical properties of thin-film light emitting diodes (LEDs) are strongly dependent on their structures due to light interference inside the devices. However, the complexity of the design space grows exponentially with the number of design parameters, making it challenging to optimize the optical properties of multilayer LEDs with rigorous electromagnetic simulations. In this work, we demonstrate an artificial neural network that can predict the light extraction efficiency of an organic LED structure in 30 ms, which is ∼103 times faster than the rigorous simulation in a single-treaded execution with root-mean-squared error of 1.86 × 10−3. The effective inference time per structure is brought down to ∼0.6 μs with unaltered error rate with parallelization. We also show that our neural networks can efficiently solve the inverse problem – finding a device design that exhibits the desired light extraction spectrum – within the similar time scale. We investigate the one-to-many mapping issue of the inverse problem and find that the degeneracy can be lifted by incorporating additional emission spectra at different observing angles. Furthermore, the forward neural network is combined with a conventional genetic algorithm to address additional large-scale optimization problems including maximization of light extraction efficiency and minimization of angle dependent color shift. Our approach establishes a platform for tackling computation-heavy optimization tasks with one-time computational cost.

Cómo citar

Elegí el formato que necesitás y copiá la referencia al portapapeles.

APA 7

al, K. S. E. (2021). Inverse design of organic light-emitting diode structure based on deep neural networks. https://doi.org/10.1515/nanoph-2021-0434

MLA

al, Kim Sanmun et. "Inverse design of organic light-emitting diode structure based on deep neural networks." 2021. https://doi.org/10.1515/nanoph-2021-0434.

Chicago

al, Kim Sanmun et. 2021. "Inverse design of organic light-emitting diode structure based on deep neural networks.". https://doi.org/10.1515/nanoph-2021-0434.

Harvard

al, K. S. E. 2021, Inverse design of organic light-emitting diode structure based on deep neural networks, Wiley, available at: https://doi.org/10.1515/nanoph-2021-0434 [Accessed 2 Jul. 2026].

Compartir e imprimir

Guardá la ficha, copiá su enlace permanente o imprimila como PDF.

Exportar referencia

Si usás un gestor bibliográfico, podés exportar el registro en los formatos más comunes.

Detalles del recurso

Información bibliográfica útil para confirmar que se trata del material correcto.

Título
Inverse design of organic light-emitting diode structure based on deep neural networks
Autor / colaboradores
Kim Sanmun et al
Editorial
Wiley
Año de publicación
2021
ISSN
2192-8614
ISSN
2192-8614
Idioma
eng

Materias

Explorá otros recursos relacionados a partir de estas materias.

Copiado