← Volver a resultados
Ficha bibliográfica · Consulta y acceso
Artículo

Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation

Xiaomin Jin et al · Springer · 2026

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.

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.

Abstract While multi-access edge computing (MEC) enables flexible task offloading, the inherent dynamism and complexity of real-world environments, accompanied by various uncertainties, exacerbate the challenges in offloading optimization. However, the limitation of existing approaches generally lies in their reliance on idealized assumptions or their inability to balance efficiency with uncertainty adaptability, which restricts their practical applicability. In this paper, we study the task offloading problem for MEC under uncertainties with joint consideration of multi-network collaboration and privacy preservation. Firstly, we establish a fuzzy optimization model to formulate the task offloading problem under uncertainties and prove its NP-hardness. The established model leverages multiple wireless networks for collaborative task data transmission and incorporates fuzzy privacy entropy to guarantee task privacy preservation. To address the inherent uncertainties in the task offloading model, we transform it into a fuzzy chance-constrained optimization formulation with predefined confidence levels. Secondly, to derive the offloading and allocation strategies from the transformed optimization model, we propose a hybrid task offloading algorithm that combines an improved adaptive genetic algorithm, Monte Carlo simulation, and neural networks. Our algorithm adopts a hybrid optimization architecture in which the adaptive genetic algorithm enhances strategy exploration through improved genetic operations, whereby the neural networks are embedded as fast proxies within evolutionary iterations to replace computationally intensive Monte Carlo simulations for solution evaluation. Finally, experimental results demonstrate that the proposed hybrid offloading algorithm surpasses existing algorithms and attains an average reduction of at least 23.24% in the objective value.

Cómo citar

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

APA 7

al, X. J. E. (2026). Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation. https://doi.org/10.1007/s44443-026-00567-z

MLA

al, Xiaomin Jin et. "Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation." 2026. https://doi.org/10.1007/s44443-026-00567-z.

Chicago

al, Xiaomin Jin et. 2026. "Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation.". https://doi.org/10.1007/s44443-026-00567-z.

Harvard

al, X. J. E. 2026, Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation, Springer, available at: https://doi.org/10.1007/s44443-026-00567-z [Accessed 29 Jun. 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
Fuzzy chance constraint-based task offloading for MEC under uncertainties with joint multi-network collaboration and privacy preservation
Autor / colaboradores
Xiaomin Jin et al
Editorial
Springer
Año de publicación
2026
ISSN
1319-1578
ISSN
1319-1578
Idioma
eng

Materias

Explorá otros recursos relacionados a partir de estas materias.

Copiado