VMware Software-Defined Storage. Martin Hosken

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Figure 1.4 Hard disk drive cost per gigabyte

Alongside the falling cost of storage, as you might expect, in terms of raw disk capacity per drive, this has aligned with the falling cost per gigabyte charged by cloud service providers. This is illustrated in Figure 1.5, where the increasing capacity available on physical disks pretty much aligns with that falling cost.

Figure 1.5 Hard disk drive capacity improvements

      Despite these falling costs in raw disk storage capacity, the chassis, the disk shelves used to create disk arrays, and the storage controllers tasked with organizing disks into large RAID (redundant array of independent disks) or JBOD (just a bunch of disks) sets, vendor prices for their technologies continue to increase year after year, regardless of this growing commoditization of the components used by them.

      The reason for this is the ongoing development and sophistication of vendor software. For instance, an array made up of commoditized components, including 300 2 TB disks stacked in commodity shelves, may have a hardware cost totaling approximately $4,000. However, the end array vendor might assign a manufacturer’s suggested retail price tag of $400,000. This price is based on the vendor adding their secret source software, enabling the commodity hardware to include features such as manageability and availability and to provide the performance aspects required by its customers, while also allowing the vendor to differentiate their product from that of their competitors. It is this aspect of storage that often adds the most significant cost component to storage technologies, regardless of the actual value added by the vendor’s software, or which of those added features are actually used by their customers.

      So whether you are buying or leasing, storage costs and other factors all contribute to the acquisition of storage resources, which is why IT organizations are increasingly trying to extend the useful life expectancy of their storage hardware. A decade ago, IT organizations were purchasing hardware with an expected life expectancy of three years. Today the same IT organizations are routinely acquiring hardware with the aim of achieving a five-to-seven-year useful life expectancy. One of the challenges is that most hardware and software ships with a three-year support contract and warranty, and renewing that agreement when it reaches end-of-life can sometimes cost as much as purchasing an entirely new array.

      The next significant aspect of storage ownership to consider is that hardware acquisition accounts for approximately only one-fifth of the estimated annual total cost of ownership (TCO). This clearly outweighs the cost to acquire or capital expenditures (CapEx), and makes operational and management costs (OpEx) a far greater factor than many IT organizations account for in their initial design and planning cost estimations.

      Calculating the Total Cost of Ownership for Storage Resources

As illustrated in Figure 1.6, the operational management, disaster recovery, and environmental costs are the real drivers behind the total cost of ownership calculations for storage devices.

Figure 1.6 Breakdown of total cost of ownership of storage hardware

      One of the factors that contributes to these operational costs is the heterogeneity of enterprise storage infrastructure. This significantly increases the challenges associated with providing a unified management approach, and as such, increases costs. Some IT organizations use this as a driver for the replacement of their heterogeneous storage platform, in favor of a more homogeneous approach. But typically, the replacement environment results from a deliberate attempt to procure the latest, best-of-breed technologies, or an attempt to facilitate storage tiering through a combination of hardware from a variety of vendors. Storage vendors often are unable to offer a varying portfolio of products for different types of workloads and data use cases. Furthermore, this problem is exacerbated by vendors who offer a wide range of products but can’t typically offer a common management platform across all storage offerings. This is especially true when vendors have acquired the technology through a business acquisition.

The simplified formula in Figure 1.7 can be used to estimate the annual total cost of ownership of storage resources over the hardware’s life expectancy.

Figure 1.7 Simplifi ed annual total cost of ownership

      The next aspect of calculating storage costs relates to how efficiently storage capacity is allocated to the appropriate storage tier. Utilization efficiency, provides a measure of how effectively storage capacity is allocated to the correct storage type, based on factors such as frequency of access, availability requirements of the data, or required response time.

      IT organizations often do not use storage capacity efficiently. They often use tier-1 storage to host data for workloads and applications that do not require the expensive, high-performance attributes that the hardware is capable of delivering. Tiered storage is supposed to enable the placement of data based on cost-appropriate requirements for performance and capacity, as defined by the business. However, a growing movement to flatten storage via strategies such as those offered up by Hadoop (among others) in leveraging the hyper-converged storage model is, in itself, eliminating the requirement for tiered storage altogether.

      IT organizations are typically charged with identifying the tiers of storage, the storage technologies employed, and the optimal percentage of business data that should represent each category of storage. Failing to do so undoubtedly leads to a significant increase in the per gigabyte cost of storage, which in turn results in an inflated total cost of ownership for the storage platform.

Figure 1.8 shows a tiered storage example. A business’s IT organization uses this cost per gigabyte model to determine cost-appropriate storage for a specific workload type. For instance, if the IT organization requires a 100 TB storage estate, employing only two tiers of storage (tier 1 and tier 2 in this example), the total disk cost would be approximately $765,000. However, meeting the same storage requirements through the four tiers shown, segregated using the ratios illustrated, would cost approximately $482,250, and therefore represent a savings of $282,750, or a 37 percent reduction to the original cost.1

Figure 1.8 Storage cost per gigabyte example

      As you can see, an enterprise IT organization that fails to use this type of tiered storage strategy – which moves data across the storage estate based on its access frequency and other criteria – will suffer from poor utilization efficiency, as well as a significantly increased total cost of ownership of storage resources, within their storage platform.

      Information Lifecycle Management

      Information Lifecycle Management (ILM) is the primary approach used by businesses to ensure availability, capacity, and performance of data throughout its existence. When designing a storage solution for business systems, one of the key business requirements that you must understand is the ILM strategy being used by the customer for their business data.

      Modern businesses and organizations must address the challenges associated with information

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