Recent tips, videos, articles and more update V2010.1

Realizing that some prefer blogs to webs to twitter to other venues, here are some recent links to articles, tips, videos, webcasts and other content that have appeared in different venues since August 2009.

  • i365 Guest Interview: Experts Corner: Q&A with Greg Schulz December 2009
  • SearchCIO Midmarket: Remote-location disaster recovery risks and solutions December 2009
  • BizTech Magazine: High Availability: A Delicate Balancing Act November 2009
  • ESJ: What Comprises a Green, Efficient and Effective Virtual Data Center? November 2009
  • SearchSMBStorage: Determining what server to use for SMB November 2009
  • SearchStorage: Performance metrics: Evaluating your data storage efficiency October 2009
  • SearchStorage: Optimizing capacity and performance to reduce data footprint October 2009
  • SearchSMBStorage: How often should I conduct a disaster recovery (DR) test? October 2009
  • SearchStorage: Addressing storage performance bottlenecks in storage September 2009
  • SearchStorage AU: Is tape the right backup medium for smaller businesses? August 2009
  • ITworld: The new green data center: From energy avoidance to energy efficiency August 2009
  • Video and podcasts include:
    December 2009 Video: Green Storage: Metrics and measurement for management insight
    Discussion between Greg Schulz and Mark Lewis of TechTarget the importance of metrics and measurement to gauge productivity and efficiency for Green IT and enabling virtual information factories. Click here to watch the Video.

    December 2009 Podcast: iSCSI SANs can be a good fit for SMB storage
    Discussion between Greg Schulz and Andrew Burton of TechTarget about iSCSI and other related technologies for SMB storage. Click here to listen to the podcast.

    December 2009 Podcast: RAID Data Protection Discussion
    Discussion between Greg Schulz and Andrew Burton of TechTarget about RAID data proteciton, techniques and technologies. Click here to listen to the podcast.

    December 2009 Podcast: Green IT, Effiency and Productivity Discussion
    Discussion between Greg Schulz and Jon Flower of Adaptec about data Green IT, energy effiency, inteligent power management (IPM) also known as MAID 2.0 and other forms of optimization techniques including SSD. Click here to listen to the podcast sponsored by Adaptec.

    November 2009 Podcast: Reducing your data footprint impact
    Even though many enterprise data storage environments are coping with tightened budgets and reduced spending, overall net storage capacity is increasing. In this interview, Greg Schulz, founder and senior analyst at StorageIO Group, discusses how storage managers can reduce their data footprint. Schulz touches on the importance of managing your data footprint on both online and offline storage, as well as the various tools for doing so, including data archiving, thin provisioning and data deduplication. Click here to listen to the podcast.

    October 2009 Podcast: Enterprise data storage technologies rise from the dead
    In this interview, Greg Schulz, founder and senior analyst of the Storage I/O group, classifies popular technologies such as solid-state drives (SSDs), RAID and Fibre Channel (FC) as “zombie” technologies. Why? These are already set to become part of standard storage infrastructures, says Schulz, and are too old to be considered fresh. But while some consider these technologies to be stale, users should expect to see them in their everyday lives. Click here to listen to the podcast.

    Check out the Tips, Tools and White Papers, and News pages for additional commentary, coverage and related content or events.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press, 2011), The Green and Virtual Data Center (CRC Press, 2009), and Resilient Storage Networks (Elsevier, 2004)

    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2012 StorageIO and UnlimitedIO All Rights Reserved

    Is MAID Storage Dead? I Dont Think So!

    Some vendors are doing better than others and first generation MAID (Massive or monolithic Array of Idle Disks) might be dead or about to be deceased, spun down or put into a long term sleep mode, it is safe to say that second generation MAID (e.g. MAID 2.0) also known as intelligent power management (IPM) is alive and doing well.

    In fact, IPM is not unique to disk storage or disk drives as it is also a technique found in current generation of processors such as those from Intel (e.g. Nehalem) and others.

    Other names for IPM include adaptive voltage scaling (AVS), adaptive voltage scaling optimized (AVSO) and adaptive power management (APM) among others.

    The basic concept is to vary the amount of power being used to the amount of work and service level needed at a point in time and on a granular basis.

    For example, first generation MAID or drive spin down as deployed by vendors such as Copan, which is rumored to be in the process of being spun down as a company (see blog post by a former Copan employee) were binary. That is, a disk drive was either on or off, and, that the granularity was the entire storage system. In the case of Copan, the granularly was that a maximum of 25% of the disks could ever be spun up at any point in time. As a point of reference, when I ask IT customers why they dont use MAID or IPM enabled technology they commonly site concerns about performance, or more importantly, the perception of bad performance.

    CPU chips have been taking the lead with the ability to vary the voltage and clock speed, enabling or disabling electronic circuitry to align with amount of work needing to be done at a point in time. This more granular approach allows the CPU to run at faster rates when needed, slower rates when possible to conserve energy (here, here and here).

    A common example is a laptop with technology such as speed step, or battery stretch saving modes. Disk drives have been following this approach by being able to vary their power usage by adjusting to different spin speeds along with enabling or disabling electronic circuitry.

    On a granular basis, second generation MAID with IPM enabled technology can be done on a LUN or volume group basis across different RAID levels and types of disk drives depending on specific vendor implementation. Some examples of vendors implementing various forms of IPM for second generation MAID to name a few include Adaptec, EMC, Fujitsu Eternus, HDS (AMS), HGST (disk drives), Nexsan and Xyratex among many others.

    Something else that is taking place in the industry seems to be vendors shying away from using the term MAID as there is some stigma associated with performance issues of some first generation products.

    This is not all that different than what took place about 15 years ago or so when the first purpose built monolithic RAID arrays appeared on the market. Products such as the SF2 aka South San Francisco Forklift company product called Failsafe (here and here) which was bought by MTI with patents later sold to EMC.

    Failsafe, or what many at DEC referred to as Fail Some was a large refrigerator sized device with 5.25” disk drives configured as RAID5 with dedicated hot spare disk drives. Thus its performance was ok for the time doing random reads, however writes in the pre write back cache RAID5 days was less than spectacular.

    Failsafe and other early RAID (and here) implementations received a black eye from some due to performance, availability and other issues until best practices and additional enhancements such as multiple RAID levels appeared along with cache in follow on products.

    What that trip down memory (or nightmare) lane has to do with MAID and particularly first generation products that did their part to help establish new technology is that they also gave way to second, third, fourth, fifth, sixth and beyond generations of RAID products.

    The same can be expected as we are seeing with more vendors jumping in on the second generation of MAID also known as drive spin down with more in the wings.

    Consequently, dont judge MAID based solely on the first generation products which could be thought of as advanced technology production proof of concept solutions that will have paved the way for follow up future solutions.

    Just like RAID has become so ubiquitous it has been declared dead making it another zombie technology (dead however still being developed, produced, bought and put to use), follow on IPM enabled generations of technology will be more transparent. That is, similar to finding multiple RAID levels in most storage, look for IPM features including variable drive speeds, power setting and performance options on a go forward basis. These newer solutions may not carry the MAID name, however the sprit and function of intelligent power management without performance compromise does live on.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved

    Optimize Data Storage for Performance and Capacity Efficiency

    This post builds on a recent article I did that can be read here.

    Even with tough economic times, there is no such thing as a data recession! Thus the importance of optimizing data storage efficiency addressing both performance and capacity without impacting availability in a cost effective way to do more with what you have.

    What this means is that even though budgets are tight or have been cut resulting in reduced spending, overall net storage capacity is up year over year by double digits if not higher in some environments.

    Consequently, there is continued focus on stretching available IT and storage related resources or footprints further while eliminating barriers or constraints. IT footprint constraints can be physical in a cabinet or rack as well as floorspace, power or cooling thresholds and budget among others.

    Constraints can be due to lack of performance (bandwidth, IOPS or transactions), poor response time or lack of availability for some environments. Yet for other environments, constraints can be lack of capacity, limited primary or standby power or cooling constraints. Other constraints include budget, staffing or lack of infrastructure resource management (IRM) tools and time for routine tasks.

    Look before you leap
    Before jumping into an optimization effort, gain insight if you do not already have it as to where the bottlenecks exist, along with the cause and effect of moving or reconfiguring storage resources. For example, boosting capacity use to more fully use storage resources can result in a performance issue or data center bottlenecks for other environments.

    An alternative scenario is that in the quest to boost performance, storage is seen as being under-utilized, yet when capacity use is increased, low and behold, response time deteriorates. The result can be a vicious cycle hence the need to address the issue as opposed to moving problems by using tools to gain insight on resource usage, both space and activity or performance.

    Gaining insight means looking at capacity use along with performance and availability activity and how they use power, cooling and floor-space. Consequently an important tool is to gain insight and knowledge of how your resources are being used to deliver various levels of service.

    Tools include storage or system resource management (SRM) tools that report on storage space capacity usage, performance and availability with some tools now adding energy usage metrics along with storage or system resource analysis (SRA) tools.

    Cooling Off
    Power and cooling are commonly talked about as constraints, either from a cost standpoint, or availability of primary or secondary (e.g. standby) energy and cooling capacity to support growth. Electricity is essential for powering IT equipment including storage enabling devices to do their specific tasks of storing data, moving data, processing data or a combination of these attributes.

    Thus, power gets consumed, some work or effort to move and store data takes place and the by product is heat that needs to be removed. In a typical IT data center, cooling on average can account for about 50% of energy used with some sites using less.

    With cooling being a large consumer of electricity, a small percentage change to how cooling consumes energy can yield large results. Addressing cooling energy consumption can be to discuss budget or cost issues, or to enable cooling capacity to be freed up to support installation of extra storage or other IT equipment.

    Keep in mind that effective cooling relies on removing heat from as close to the source as possible to avoid over cooling which requires more energy. If you have not done so, have a facilities review or assessment performed that can range from a quick walk around, to a more in-depth review and thermal airflow analysis. A means of removing heat close to the sort are techniques such as intelligent, precision or smart cooling also known by other marketing names.

    Powering Up, or, Powering Down
    Speaking of energy or power, in addition to addressing cooling, there are a couple of ways of addressing power consumption by storage equipment (Figure 1). The most popular discussed approach towards efficiency is energy avoidance involving powering down storage when not used such as first generation MAID at the cost of performance.

    For off-line storage, tape and other removable media give low-cost capacity per watt with low to no energy needed when not in use. Second generation (e.g. MAID 2.0) solutions with intelligent power management (IPM) capabilities have become more prevalent enabling performance or energy savings on a more granular or selective basis often as a standard feature in common storage systems.

    GreenOptionsBalance
    Figure 1:  How various RAID levels and configuration impact or benefit footprint constraints

    Another approach to energy efficiency is seen in figure 1 which is doing more work for active applications per watt of energy to boost productivity. This can be done by using same amount of energy however doing more work, or, same amount of work with less energy.

    For example instead of using larger capacity disks to improve capacity per watt metrics, active or performance sensitive storage should be looked at on an activity basis such as IOP, transactions, videos, emails or throughput per watt. Hence, a fast disk drive doing work can be more energy-efficient in terms of productivity than a higher capacity slower disk drive for active workloads, where for idle or inactive, the inverse should hold true.

    On a go forward basis the trend already being seen with some servers and storage systems is to do both more work, while using less energy. Thus a larger gap between useful work (for active or non idle storage) and amount of energy consumed yields a better efficiency rating, or, take the inverse if that is your preference for smaller numbers.

    Reducing Data Footprint Impact
    Data footprint impact reduction tools or techniques for both on-line as well as off-line storage include archiving, data management, compression, deduplication, space-saving snapshots, thin provisioning along with different RAID levels among other approaches. From a storage access standpoint, you can also include bandwidth optimization, data replication optimization, protocol optimizers along with other network technologies including WAFS/WAAS/WADM to help improve efficiency of data movement or access.

    Thin provisioning for capacity centric environments can be used to achieving a higher effective storage use level by essentially over booking storage similar to how airlines oversell seats on a flight. If you have good historical information and insight into how storage capacity is used and over allocated, thin provisioning enables improved effective storage use to occur for some applications.

    However, with thin provisioning, avoid introducing performance bottlenecks by leveraging solutions that work closely with tools that providing historical trending information (capacity and performance).

    For a technology that some have tried to declare as being dead to prop other new or emerging solutions, RAID remains relevant given its widespread deployment and transparent reliance in organizations of all size. RAID also plays a role in storage performance, availability, capacity and energy constraints as well as a relief tool.

    The trick is to align the applicable RAID configuration to the task at hand meeting specific performance, availability, capacity or energy along with economic requirements. For some environments a one size fits all approach may be used while others may configure storage using different RAID levels along with number of drives in RAID sets to meet specific requirements.


    Figure 2:  How various RAID levels and configuration impact or benefit footprint constraints

    Figure 2 shows a summary and tradeoffs of various RAID levels. In addition to the RAID levels, how many disks can also have an impact on performance or capacity, such as, by creating a larger RAID 5 or RAID 6 group, the parity overhead can be spread out, however there is a tradeoff. Tradeoffs can be performance bottlenecks on writes or during drive rebuilds along with potential exposure to drive failures.

    All of this comes back to a balancing act to align to your specific needs as some will go with a RAID 10 stripe and mirror to avoid risks, even going so far as to do triple mirroring along with replication. On the other hand, some will go with RAID 5 or RAID 6 to meet cost or availability requirements, or, some I have talked with even run RAID 0 for data and applications that need the raw speed, yet can be restored rapidly from some other medium.

    Lets bring it all together with an example
    Figure 3 shows a generic example of a before and after optimization for a mixed workload environment, granted you can increase or decrease the applicable capacity and performance to meet your specific needs. In figure 3, the storage configuration consists of one storage system setup for high performance (left) and another for high-capacity secondary (right), disk to disk backup and other near-line needs, again, you can scale the approach up or down to your specific need.

    For the performance side (left), 192 x 146GB 15K RPM (28TB raw) disks provide good performance, however with low capacity use. This translates into a low capacity per watt value however with reasonable IOPs per watt and some performance hot spots.

    On the capacity centric side (right), there are 192 x 1TB disks (192TB raw) with good space utilization, however some performance hot spots or bottlenecks, constrained growth not to mention low IOPS per watt with reasonable capacity per watt. In the before scenario, the joint energy use (both arrays) is about 15 kWh or 15,000 watts which translates to about $16,000 annual energy costs (cooling excluded) assuming energy cost of 12 cents per kWh.

    Note, your specific performance, availability, capacity and energy mileage will vary based on particular vendor solution, configuration along with your application characteristics.


    Figure 3: Baseline before and after storage optimization (raw hardware) example

    Building on the example in figure 3, a combination of techniques along with technologies yields a net performance, capacity and perhaps feature functionality (depends on specific solution) increase. In addition, floor-space, power, cooling and associated footprints are also reduced. For example, the resulting solution shown (middle) comprises 4 x 250GB flash SSD devices, along with 32 x 450GB 15.5K RPM and 124 x 2TB 7200RPM enabling an 53TB (raw) capacity increase along with performance boost.

    The previous example are based on raw or baseline capacity metrics meaning that further optimization techniques should yield improved benefits. These examples should also help to discuss the question or myth that it costs more to power storage than to buy it which the answer should be it depends.

    If you can buy the above solution for say under $50,000 (cost to power), or, let alone, $100,000 (power and cool) for three years which would also be a good acquisition, then the myth of buying is more expensive than powering holds true. However, if a solution as described above costs more, than the story changes along with other variables include energy costs for your particular location re-enforcing the notion that your mileage will vary.

    Another tip is that more is not always better.

    That is, more disks, ports, processors, controllers or cache do not always equate into better performance. Performance is the sum of how those and other pieces working together in a demonstrable way, ideally your specific application workload compared to what is on a product data sheet.

    Additional general tips include:

    • Align the applicable tool, technique or technology to task at hand
    • Look to optimize for both performance and capacity, active and idle storage
    • Consolidated applications and servers need fast servers
    • Fast servers need fast I/O and storage devices to avoid bottlenecks
    • For active storage use an activity per watt metric such as IOP or transaction per watt
    • For in-active or idle storage, a capacity per watt per footprint metric would apply
    • Gain insight and control of how storage resources are used to meet service requirements

    It should go without saying, however sometimes what is understood needs to be restated.

    In the quest to become more efficient and optimized, avoid introducing performance, quality of service or availability issues by moving problems.

    Likewise, look beyond storage space capacity also considering performance as applicable to become efficient.

    Finally, it is all relative in that what might be applicable to one environment or application need may not apply to another.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved

    StorageIO aka Greg Schulz appears on Infosmack

    If you are in the IT industry, and specifically have any interest or tie to data infrastructures from servers, to storage and networking including hardware, software, services not to mention virtualization and clouds, InfoSmack and Storage Monkeys should be on your read or listen list.

    Recently I was invited to be a guest on the InfoSmack podcast which is about a 50 some minute talk show format around storage, networking, virtualization and related topics.

    The topics discussed include Sun and Oracle from a storage standpoint, Solid State Disk (SSD) among others.

    Now, a word of caution, InfoSmack is not your typical prim and proper venue, nor is it a low class trash talking production.

    Its fun and informative where the hosts and attendees are not afraid of poking fun at them selves while exploring topics and the story behind the story in a candid non scripted manner.

    Check it out.

    Cheers – gs

    Greg Schulz – StorageIOblog, twitter @storageio Author “The Green and Virtual Data Center” (CRC)

    RAID data protection remains relevant

    Storage I/O trends

    RAID (Redundant Array of Idle/Independent Disks) has evolved significantly since the original RAID white paper from the University of California Berkeley (Patterson, Gibson & Katz) was published 20 some years ago and in many cases is taken for granted today. There is also debate as to whether RAID is still relevant and practical given the continued increase amounts of data that needs to be protected.

    RAID Examples from www.thegreenandvirtualdatacenter.com
    Sample of some common RAID levels, general characteristics, caveat and benefits

    RAID remains relevant today, granted, RAID continues to evolve as do the many variations including distributed and hybrid data protection schemes. Dave Raffo over at SearchStorage has a nice article on "The evolution of RAID data protection" with comments from me. Have a look at the Dave’s article (as well as here) along with some of the comments and thoughts from myself and others.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved

    Server Storage I/O Network Virtualization Whats Next?

    Server Storage I/O Network Virtualization Whats Next?
    Server Storage I/O Network Virtualization Whats Next?
    Updated 9/28/18

    There are many faces and thus functionalities of virtualization beyond the one most commonly discussed which is consolidation or aggregation. Other common forms of virtualization include emulation (which is part of enabling consolidation) which can be in the form of a virtual tape library for storage to bridge new disk technology to old software technology, processes, procedures and skill sets. Other forms of virtualization functionality for life beyond consolidation include abstraction for transparent movement of applications or operating systems on servers, or data on storage to support planned and un-planned maintenance, upgrades, BC/DR and other activities.

    So the gist is that there are many forms of virtualization technologies and techniques for servers, storage and even I/O networks to address different issues including life beyond consolidation. However the next wave of consolidation could and should be that of reducing the number of logical images, or, the impact of the multiple operating systems and application images, along with their associated management costs.

    This may be easier said than done, however, for those looking to cut costs even further than from what can be realized by reducing physical footprints (e.g. going from 10 to 1 or from 250 to 25 physical servers), there could be upside however it will come at a cost. The cost is like that of reducing data and storage footprint impacts with such as data management and archiving.

    Savings can be realized by archiving and deleting data via data management however that is easier said than done given the cost in terms of people time and ability to decide what to archive, even for non-compliance data along with associated business rules and policies to be defined (for automation) along with hardware, software and services (managed services, consulting and/or cloud and SaaS).

    Where To Learn More

    View additional NAS, NVMe, SSD, NVM, SCM, Data Infrastructure and HDD related topics via the following links.

    Additional learning experiences along with common questions (and answers), as well as tips can be found in Software Defined Data Infrastructure Essentials book.

    Software Defined Data Infrastructure Essentials Book SDDC

    What This All Means

    Ok, nuff said, for now.

    Gs

    Greg Schulz – Microsoft MVP Cloud and Data Center Management, VMware vExpert 2010-2018. Author of Software Defined Data Infrastructure Essentials (CRC Press), as well as Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press), Resilient Storage Networks (Elsevier) and twitter @storageio. Courteous comments are welcome for consideration. First published on https://storageioblog.com any reproduction in whole, in part, with changes to content, without source attribution under title or without permission is forbidden.

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO. All Rights Reserved. StorageIO is a registered Trade Mark (TM) of Server StorageIO.

    Intelligent Power Management (IPM) and second generation MAID 2.0 on the rise

    Storage I/O trends

    In case you missed it today, Adaptec announced that they are the 1st vendor “This Week” to add support for Intelligent Power Management (IPM) to their storage systems. Adaptec joins a growing list of vendors who are deploying, or, who are program announcing some variation of IPM and second generation MAID 2.0 ability including support for different types of tiered disk drives including various combinations of Fibre Channel and SAS as well as SATA.

    As a quick refresh, Massive or Monolithic Arrays of Idle or Inactive Disks (MAID) was popularized by 1st generation MAID vendor Copan who spins down disk drives to avoid energy usage. One of the challenges with 1st generation MAID is the poor performance by being able to only have at most 25% of the disk drives spinning at any time to transfer data when needed.

    This is a balancing act between achieving energy avoidance and associated benefits vs. maintaining performance to move data when needed particularly for large restoration to support BC/DR or other purposes. Granted, 1st generation MAID systems like those from Copan while positioned as alternatives to high-performance disk storage systems to amplify potential energy savings on one hand, or, to put as an alternative to magnetic tape by providing random restore capability. The reality is that 1st generation MAID systems are finding their niche not for on-line primary or even on-line secondary storage, nor as a direct replacement for tape or even disk based libraries to support large-scale BC/DR, rather, in a sweet spot between secondary and near-line disk libraries and virtual tape libraries with a target application of very infrequently accessed of data.

    Second generation MAID, aka MAID 2.0 is an evolution of the general technologies and capabilities extending functionality and flexibility while addressing quality of service (QoS), performance, availability, capacity and energy consumption using IPM also known as Adaptive Power Management (APM), dynamic bandwidth switching or scaling (DBS) among other names. The basic premise is to add flexibility building on 1st generation characteristics including data protection, resiliency and pro-active part or drive monitoring. Another basic premise of IPM. and MAID 2.0. solutions is to allow the performance and subsequent energy usage to vary, which is to cut the amount of performance and energy usage during in-active times, yet, when data needs to be accessed, to allow full performance without penalties for energy savings.

    Second generation MAID solutions can be characterized by multiple power saving modes as well as flexible performance to adjust to changing workload and application needs. Another characteristic is the ability to work across different types of disk drives including Fibre Channel, SAS and SATA as opposed to only SATA drives found in 1st generation solutions as well as for the IPM or MAID 2.0 functionality to exist in a standard storage system or array instead of in a purpose-built dedicated storage system. Other capabilities include support for more granular power settings down to a RAID group or LUN level instead of across an entire array or storage system as well as support for different RAID levels among other features.

    Examples of vendors who have either announced product or made statements of direction with regard to MAID 2.0 and IPM enabled storage systems include:

    Adaptec (Today), Datadirect, EMC, Fujitsu, HDS, HGST (Hitachi Disk Drives), NEC, Nexsan, and Xyratex among others on a growing list of solutions.

    For applications and data storage needs that need good performance and QoS over a range of changing usage conditions to balance good performance when needed to efficiently get work done to boost productivity, while saving or avoiding energy when little or no work needs to be done, take a look at current and emerging IPM and MAID 2.0 enabled storage systems as part of a tiered storage strategy to discuss power, cooling, floor-space and EHS (PCFE) related issues.

    To learn more, check out the StorageIO Industry Trends and Perspective white paper Intelligent Power Management (IPM) and MAID 2.0 and visit www.thegreenandvirtualdatacenter.com well as www.storageio.com.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved

    Many different Implementations of RAID

    Processor Magazine has a new article looking at different flavors and implementations of RAID technology called Moving Toward Software-Based RAID: Tapping In To Fast Multicore CPUs For Performance & Flexibility. The exact number of categories is up for debate as you could make it as simple as either hardware or software RAID similar to all the variations of RAID levels in hybrid configurations. You could further break it down to different types and locations of implementations of software based RAID such as in a volume manager or file system, operating system, software driver stack, or standalone software stack to transform a general purpose processor into a RAID controller, or, software to leverage RAID off-load capabilities in hardware.

    Speaking of hardware, one could debate that some off the shelf processor chips have some amount of RAID capabilities or primitives while other specialized off-load chips do more. There are dedicated RAID on a Chip known as ROCs that may include a RAID6 or other special purpose functionality or rely on external chips for parity rebuilds or other functions. ROCs can be embedded on a processor mother board in the form of RAID on Mother Board (aka ROMB), ROCs can be found on RAID adapter cards that plug into a PCI, PCIx or PCIe I/O slot with a SCSI, SAS or SATA I/O port for disk attachment. Then there are RAID controllers external to a computer that resides in external storage system of various size and shapes.

    What does this all mean is that there are many different implementations and vendor packaged solutions and approaches to delivering RAID technologies to different market and price band segments, some are software based, some are external hardware based, some include various combinations. The bottom line is that RAID after 20 years is still relevant enough to warrant discussion of new and varying implementations schemes and packaging approaches. See additional links to articles, tips, presentations, webcasts and commentary pertaining to RAID and related topics on the portfolio and portfolio archive pages on the StorageIO website.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved

    Continuing Education and Refresher Time (RAID and LUNs)

    Storage I/O trends

    TechTarget is currently running a refresher and primer series on RAID technology at www.searchstorage.com combining several tips pertaining to RAID basics, what RAID level to use for different applications and more. RAID is around 20 years old depending on how you view it and define it and some are now decrying RAID as being dead which for some implementations may be the case, however the underlying premises still hold, its just time for some new implementation and evolutionary changes. In the meantime, back at planet reality and today-land, check it out for a primer, refresh, or to see if RAID is even still relevant.

    Another Primer and refresh series that is appearing on TechTarget is about LUNs. For those of you new to data storage, or, for those who need a refresh, these are a good source of primer or back ground material. Check out the LUN series here.

    Ok, nuff said.

    Cheers gs

    Greg Schulz – Author Cloud and Virtual Data Storage Networking (CRC Press), The Green and Virtual Data Center (CRC Press) and Resilient Storage Networks (Elsevier)
    twitter @storageio

    All Comments, (C) and (TM) belong to their owners/posters, Other content (C) Copyright 2006-2024 Server StorageIO and UnlimitedIO LLC All Rights Reserved