SoftAir: A Software-Defined Networking Architecture for 5G Wireless Systems

Descripción

SoftAir is a new wireless software-defined architecture with network function virtualization (NFV) solutions for 5G wireless systems. The concept of SDN has been proposed to efficiently create centralized network abstraction with the provisioning of programmability over the entire network. Moreover, the complementary concept of NFV has been further proposed to effectively separate the abstraction of functionalities from the hardware, such as decoupling the data forwarding plane from the control plane.

SoftAir: A Software-Defined Networking Architecture for 5G Wireless Systems

Descripción

SoftAir is a new wireless software-defined architecture with network function virtualization (NFV) solutions for 5G wireless systems. The concept of SDN has been proposed to efficiently create centralized network abstraction with the provisioning of programmability over the entire network. Moreover, the complementary concept of NFV has been further proposed to effectively separate the abstraction of functionalities from the hardware, such as decoupling the data forwarding plane from the control plane.

SoftAir: A Software-Defined Networking Architecture for 5G Wireless Systems

Descripción

SoftAir is a new wireless software-defined architecture with network function virtualization (NFV) solutions for 5G wireless systems. The concept of SDN has been proposed to efficiently create centralized network abstraction with the provisioning of programmability over the entire network. Moreover, the complementary concept of NFV has been further proposed to effectively separate the abstraction of functionalities from the hardware, such as decoupling the data forwarding plane from the control plane.

SoftAir: A Software-Defined Networking Architecture for 5G Wireless Systems

Descripción

SoftAir is a new wireless software-defined architecture with network function virtualization (NFV) solutions for 5G wireless systems. The concept of SDN has been proposed to efficiently create centralized network abstraction with the provisioning of programmability over the entire network. Moreover, the complementary concept of NFV has been further proposed to effectively separate the abstraction of functionalities from the hardware, such as decoupling the data forwarding plane from the control plane.

SoftAir: A Software-Defined Networking Architecture for 5G Wireless Systems

Descripción

SoftAir is a new wireless software-defined architecture with network function virtualization (NFV) solutions for 5G wireless systems. The concept of SDN has been proposed to efficiently create centralized network abstraction with the provisioning of programmability over the entire network. Moreover, the complementary concept of NFV has been further proposed to effectively separate the abstraction of functionalities from the hardware, such as decoupling the data forwarding plane from the control plane.

Filamento de wolframio. / Mauricio Romero Mendoza (FLICKR)

Un aislante topológico con potencial en espintrónica

12.07.2017
El investigador de <a href="https://www.nanogune.eu/en" title="CIC nanoGUNE" alt="CIC nanoGUNE" target="_blank">Nanoscience Cooperative Resarch Center</a> (CIC nanoGUNE), Miguel M. Ugeda, del grupo Nanoimagen, ha participado en un estudio internacional, junto con investigadores de la <a href="https://www.stanford.edu/" title="Universidad de Stanford" alt="Universidad de Stanford" target="_blank">Universidad de Stanford</a> y de la <a href="https://www.berkeley.edu/" title="Universidad de California en Berkeley" alt="Universidad de California en Berkeley" target="_blank">Universidad de California en Berkeley</a> (EE.UU.), en el que han demostrado experimentalmente el efecto llamado 'hall cuántico de spin' en un material bidimensional.
Filamento de wolframio. / Mauricio Romero Mendoza (FLICKR)

Un aislante topológico con potencial en espintrónica

12.07.2017
El investigador de <a href="https://www.nanogune.eu/en" title="CIC nanoGUNE" alt="CIC nanoGUNE" target="_blank">Nanoscience Cooperative Resarch Center</a> (CIC nanoGUNE), Miguel M. Ugeda, del grupo Nanoimagen, ha participado en un estudio internacional, junto con investigadores de la <a href="https://www.stanford.edu/" title="Universidad de Stanford" alt="Universidad de Stanford" target="_blank">Universidad de Stanford</a> y de la <a href="https://www.berkeley.edu/" title="Universidad de California en Berkeley" alt="Universidad de California en Berkeley" target="_blank">Universidad de California en Berkeley</a> (EE.UU.), en el que han demostrado experimentalmente el efecto llamado 'hall cuántico de spin' en un material bidimensional.