Fog computing
Fog computing[1] or fog networking, also known as fogging,[2][3] is an architecture that uses one or more collaborative multitude of end-user clients or near-user edge devices to carry out a substantial amount of storage (rather than stored primarily in cloud data centers), communication (rather than routed over the internet backbone), control, configuration, measurement and management (rather than controlled primarily by network gateways such as those in the LTE core network).
Concept
Fog computing can be perceived both in large cloud systems and big data structures, making reference to the growing difficulties in accessing information objectively. This results in a lack of quality of the obtained content. The effects of fog computing on cloud computing and big data systems may vary; yet, a common aspect that can be extracted is a limitation in accurate content distribution, an issue that has been tackled with the creation of metrics that attempt to improve accuracy.[4]
Fog networking consists of a control plane and a data plane. For example, on the data plane, fog computing enables computing services to reside at the edge of the network as opposed to servers in a data-center. Compared to cloud computing, fog computing emphasizes proximity to end-users and client objectives, dense geographical distribution and local resource pooling, latency reduction for quality of service (QoS) and edge analytics/stream mining, resulting in superior user-experience[5] and redundancy in case of failure.[6][7][8][9]
Fog networking supports the Internet of Everything (IoE) concept, in which most of the devices used by humans on a daily basis will be connected to each other. Examples include phones, wearable health monitoring devices, connected vehicle and augmented reality using devices such as the Google Glass.[10][11][12][13][14]
ISO/IEC 20248 provides a method whereby the data of objects identified by edge computing using Automated Identification Data Carriers [AIDC], a barcode and/or RFID tag, can be read, interpreted, verified and made available into the "Fog" and on the "Edge" even when the AIDC tag has moved on.
History
On November 19, 2015, Cisco Systems, ARM Holdings, Dell, Intel, Microsoft, and Princeton University, founded the OpenFog Consortium, to promote interests and development in fog computing.[15] Cisco Sr. Managing-Director Helder Antunes became the consortium's first chairman and Intel's Chief IoT Strategist Jeff Faders became its first president.[16]
References
- ^ Bar-Magen Numhauser, Jonathan (2013). Fog Computing introduction to a New Cloud Evolution. Escrituras silenciadas: paisaje como historiografía. Spain: University of Alcala. pp. 111–126. ISBN 978-84-15595-84-7.
- ^ IoT, from Cloud to Fog Computing: [1]
- ^ fog-computing: [2]
- ^ Bar-Magen Numhauser, Jonathan (August 25, 2013). "XMPP Distributed Topology as a Potential Solution for Fog Computing". MESH 2013 The Sixth International Conference on Advances in Mesh Networks.
- ^ Cisco RFP-2013-078. Fog Computing, Ecosystem, Architecture and Applications: [3] Also available from the Internet Archive: [4].
- ^ What Comes After the Cloud? How About the Fog?: [5].
- ^ Is There a Buzz Over Fog Computing?: [6].
- ^ New Solutions on the Horizon—“Fog” or “Edge” Computing?: [7].
- ^ Cloud Evolution: Back to the Future?: [8].
- ^ Bonomi, F., Milito, R., Zhu, J., and Addepalli,S. Fog Computing and its Role in the Internet of Things. In Proc of MCC (2012), pp. 13-16.[9].
- ^ Cisco-Delivers-Vision-of-Fog-Computing-to-Accelerate-Value-from-Billions-of-Connected-Devices: [10].
- ^ IoT: Out Of The Cloud & Into The Fog: [11].
- ^ Distributed intelligence and IoT fog: [12].
- ^ Fog Computing Keeps Data Right Where the Internet of Things Needs It: [13].
- ^ Janakiram, MSV (18 April 2016). "Is Fog Computing the Next Big Thing in the Internet of Things". Forbes Magazine. Retrieved 18 April 2016.
- ^ OpenFog Consortium - About Us: Governance