Software-defined data center

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Software-defined data center (SDDC; also: virtual data center, VDC) is a marketing term that extends virtualization concepts such as abstraction, pooling, and automation to all data center resources and services to achieve IT as a service (ITaaS).[1] In a software-defined data center, "all elements of the infrastructure — networking,[2] storage, CPU and security – are virtualized and delivered as a service."[3] While ITaaS may represent an outcome of SDDC, SDDC is differently cast[by whom?] toward integrators and datacenter builders rather than toward tenants. Software awareness in the infrastructure is not visible to tenants.

SDDC support can be claimed by a wide variety of approaches. Critics see the software-defined data center as a marketing tool and "software-defined hype," noting this variability.[4]

In 2013, an analyst[which?] projected that at least some software-defined data center components would experience market growth. The software-defined networking market is expected to be valued at about USD $3.7 billion by 2016, compared to USD $360 million in 2013.[4] IDC estimates that the software-defined storage market is poised to expand faster than any other storage market.[4]

Description and core components

The software-defined data center encompasses a variety of concepts and data-center infrastructure components, with each component potentially provisioned, operated, and managed through an application programming interface (API).[5] Core architectural components that comprise the software-defined data center[6] include the following:

A software-defined data center differs from a private cloud, since a private cloud only has to offer virtual-machine self-service[9],[citation needed] beneath which it could use traditional provisioning and management. Instead, SDDC concepts imagine a data center that can encompass private, public, and hybrid clouds.[10]

Origins and development

Data centers traditionally lacked the capacity to accommodate total virtualization.[11]

By 2013, companies began laying the foundation for software-defined data centers with virtualization.[4] Ben Cherian of Midokura considers Amazon Web Services as a catalyst for the move toward software-defined data centers because it

convinced the world that the data center could be abstracted into much smaller units and could be treated as disposable pieces of technology, which in turn could be priced as a utility. Vendors watched Amazon closely and saw how this could apply to the data center of the future.[5]

Potential impact

In 2013, the software-defined data center term was promoted as a paradigm shift.[5][12] The promise of the software-defined data center was that companies would no longer need to rely on specialized hardware or hire consultants to install and program hardware in its specialized language.[13] Rather, IT will define applications and all of the resources they require—including compute, storage, networking, security, and availability—and group all of the required components to create a “logical application.”[13]

Commonly cited benefits of software-defined data centers include improved efficiency[14] from extending virtualization throughout the data center; increased agility[15] from provisioning applications quickly; improved control[15] over application availability and security through policy-based governance; and the flexibility[14][15] to run new and existing applications in multiple platforms and clouds.

In addition, a software-defined data center implementation could reduce a company’s energy usage by enabling servers and other data center hardware to run at decreased power levels or be turned off.[15] Some believe that software-defined data centers improve security by giving organizations more control over their hosted data and security levels, compared to security provided by hosted-cloud providers.[15]

The software-defined data center was marketed to drive down prices for data center hardware and challenge traditional hardware vendors to develop new ways to differentiate their products through software and services.[16]

Challenges

The concepts of software-defined in general, and software-defined data centers in particular, have been dismissed by some as “nonsense,” “marketecture,” and “software-defined hype.”[4] Some critics believe that only a minority of companies with “completely homogeneous IT systems’” already in place, such as Yahoo! and Google, can transition to software-defined data centers.[4]

According to some observers, software-defined data centers won’t necessarily eliminate challenges that relate to handling the differences between development and production environments; managing a mix of legacy and new applications; or delivering service-level agreements (SLAs).[4]

Software-defined networking was seen as essential to the software-defined data center, but it is also considered to be the “least mature technology” required to enable the software-defined data center.[11] However, companies, including VMware, Juniper Networks, Arista Networks, FatPipe Networks, Cisco, and Microsoft, market products to enable virtual networks that are provisioned, extended, and moved across existing physical networks.[11]

Several competing network virtualization standards already existed by 2012.[11] Neutron, the networking component of the open-source software OpenStack project, provides an application-level abstraction of network resources and includes an interface for configuring virtual switches.[11][17]

The software-defined data center approach will force IT organizations to adapt. Software-defined environments require rethinking many IT processes—including automation, metering, and billing—and executing service delivery, service activation, and service assurance.[15] A widespread transition to the SDDC could take years.[6]

Vendors

VMware acquired Pune-based software-defined data center security and operations firm Arkin, in 2016.[18] Other vendors are developed components and standards that enable a software-defined data center. The OpenDaylight Project attracted support from vendors including Avaya, H3C, 6Wind,[19] Arista Networks, Big Switch Networks, Brocade, Cisco, Citrix, Dell, Ericsson, FatPipe Networks, Fujitsu, Hewlett Packard Enterprise (HPE), IBM, Intel, Juniper Networks, Microsoft, NEC, Nuage Networks, Plexxi, PLUMgrid, Red Hat and Yottabyte.[20]

Large-scale service providers such as Amazon and Savvis, which could potentially benefit from improved efficiencies through automation, are considered to be the organizations that are most likely to deploy full-scale software-defined data center implementations.[16]

For companies that have already deployed a SDN in the data center many are now looking to expand those benefits to the WAN. A buzzword "software defined WAN" was used by vendors like FatPipe Networks, CloudGenix,[21] VeloCloud and Viptela.

References

  1. ^ Davidson, Emily A. "The Software-Defined-Data-Center (SDDC): Concept Or Reality? [VMware]". Softchoice Advisor Article. Softchoice Advisor. Retrieved 28 June 2013.
  2. ^ Noormohammadpour, Mohammad; Raghavendra, Cauligi (16 July 2018). "Datacenter Traffic Control: Understanding Techniques and Tradeoffs". Communications Surveys & Tutorials, IEEE. 20 (2): 1492-1525.
  3. ^ Rouse, Margaret. "Definition: Software Defined Datacenter". Retrieved 25 February 2014.
  4. ^ a b c d e f g Kovar, Joseph F. (13 May 2013). "Software-Defined Data Centers: Should You Jump On The Bandwagon?". CRN. Retrieved 10 February 2014.
  5. ^ a b c Cherian, Ben. "What Is the Software Defined Data Center and Why Is It Important?". All Things D post. All Things D. Retrieved 28 June 2013.
  6. ^ a b c Volk, Torsten. "The Software-Defined Datacenter: Part 2 of 4 – Core Components". EMA Blogs. EMA. Retrieved 28 June 2013.
  7. ^ "The software defined data center - part 2: compute". CohesiveFT Blog post. CohesiveFT Blog. Retrieved 28 June 2013.
  8. ^ Marshall, David. "VMware's software-defined data center will include NSX network virtualization". InfoWorld article. InfoWorld. Retrieved 28 June 2013.
  9. ^ Inc., FatPipe Networks. "Multi-Line WAN Load Balancing | SD-WAN | Link Load Balancing | WAN Optimization | WAN Security". FatPipe Networks. Retrieved 2018-01-22. {{cite web}}: |last= has generic name (help)
  10. ^ Otey, Michael (29 May 2013). "Moving Toward the Software-Defined Datacenter". WindowsITPro. Retrieved 28 June 2013.
  11. ^ a b c d e Knorr, Eric (13 August 2012). "What the software-defined data center really means". InfoWorld. Retrieved 28 June 2013.
  12. ^ Paul Shread (25 July 2013). "Software-Defined Data Centers Could Change the IT Landscape". Datamation. Retrieved 22 August 2016.
  13. ^ a b Herrod, Steve. "Interop and the Software-Defined Datacenter". VMware blog post. VMware. Retrieved 28 June 2013.
  14. ^ a b Earls, Alan. "Is the software-defined data center ready for the mainstream?". SearchDataCenter article. SearchDataCenter. Retrieved 28 June 2013.
  15. ^ a b c d e f Venkatraman, Archana. "Software-defined datacentres demystified". ComputerWeekly.com. ComputerWeekly.com. Retrieved 28 June 2013.
  16. ^ a b Manca, Pete (29 May 2013). "Software-Defined Data Centers: What's the Buzz All About?". Wired. Retrieved 28 June 2013.
  17. ^ "Neutron's developer documentation". OpenStack. Retrieved 22 August 2016.
  18. ^ "VMWare to acquire Arkin net". Economic Times. 13 June 2016. Retrieved 15 June 2016.
  19. ^ Jeffrey Burt (2 May 2014). "Avaya, H3C, 6Wind Join OpenDaylight SDN Effort". eWeek. eWeek. Retrieved 1 Feb 2015.
  20. ^ Knorr, Eric (8 April 2013). "OpenDaylight: A big step toward the software-defined data center". InfoWorld. Retrieved 28 June 2013.
  21. ^ "Startup CloudGenix Aims to Bring SDN to WAN". eWeek. 2014-05-01. Retrieved 2014-05-01.,