A Look at 2013

We grew!

We moved!

We’ve had a heck of a year!

In 2013 alone, we reduced (and avoided the generation of) more than 85 thousand tons of carbon emissions from the atmosphere.

This is a statistic of which I am very, very proud and one that clearly demonstrates the double bottom line impact of the Vigilent solution.

We have directly impacted the planet by reducing energy requirements and CO2 emissions, even as the demands of our digital lifestyles increase.  We have impacted individual quality of life by increasing uptime reliability and contributing to the safety of treasured documents and photos, as well as helping to ensure the uninterrupted transmission of information that makes our world operate.  We are honored and privileged to contribute so directly to the well-being of our world and our customers.

While analysts have cited a DCIM market contraction in 2013, Vigilent has thrived.   We attracted new customers and engendered even deeper loyalty among existing customers – evidenced by our organic growth as one deployment turns into 3, then ten, then dozens across the United States when actual energy savings and thermal condition insights are realized.

I am pleased to share some of the milestones we achieved in 2013:

We moved to terrific new facilities in uptown Oakland.  Not only does our new facility (within a literally green building)  provide us with space for in-house product commissioning and expanded R&D,  it provides a vibrant collaborative atmosphere for employees.  The new location is adjacent to public transportation, honoring our commitment to a green corporate culture, and offers dozens of great restaurants, coffee shops and diverse entertainment options for employees.

We grew – in revenues, in customer base, into new markets and with staff.  With growth comes responsibility to provide more directed  leadership in business functions and market focus.  With this in mind, we expanded our executive management staff, hiring  Dave Hudson to oversee sales and operations worldwide, and  Alex Fielding to introduce Vigilent to federal markets and many new field engineers, software engineers, QA and support staff.

We expanded our product offering with new functionality including out-of-the-box reports that help with energy savings, SLA adherence, maintenance and capacity planning.  We continued to refine our trademark intelligence and control functionality enhancing both usability and energy savings in ever more complex data center environments – achieving an additional 30% savings in some cases.

Ultimately, all of this helps our customers succeed not only in direct bottom line impact, but with large-scale sustainability efforts that are widely recognized.  Avnet used the Vigilent system in corporate sustainability initiatives that garnered the company the Uptime Institute GEIT award, as well as recognition by InfoWorld as a top Green IT award winner.    Our sales partner, NTT Facilities, continues to roll out  Vigilent deployments in Japan.

Our ability to contribute to the Federal Government’s initiative to consolidate data centers and reduce overall energy savings is significant indeed.  Watch this space.

With a great year behind us, we recognize that there is much to do, as the data center industry – at last – is realizing how significantly data and analytics can improve day to day operations and efficiency endeavors.

The Emerson-Poneman Institute recently issued a study on Data Center outages that states accidental human error remains in the top-3 cited reasons for downtime and that 52% of survey respondents believe these accidents could have been prevented.

Intelligent software control and analytics will help operators make better,  more informed decisions and reduce such human errors.   These tools will increasingly help data centers proactively avoid trouble, while at the same time helping them diagnose and resolve actual issues more quickly.

This will be the year of analytics for data centers.  Vigilent is equipped and prepared to lead this charge, leveraging years of institutional knowledge we have gleaned  from hundreds of deployments in every conceivable configuration in mission critical facilities on four continents.  This mass of data influences the analytics we use to engage individual control decisions at every site, and also, more recently, places the benefit of this accumulated knowledge into the hands and minds of data center managers for more informed process management.

Happy New Year.

The Value of Efficiency-Aware Decision Making

My Chevy Volt displays my gas mileage.  In fact, I knew what the mileage performance would be before I bought the car. It was a factor in my purchase choice.

In addition to cars, most large appliances display power use along with Energy-Star certification. Residential air conditioners display standard energy efficiency ratings (SEER).   Even large commercial building air conditioners have to meet standard rating conditions for efficiency.

Yet, it is only recently that efficiency ratings have been specified for data center cooling.  The primary reason is that for years, manufacturers of cooling units for mission critical facilities avoided efficiency ratings requirements claiming that, because their products were used for process cooling versus comfort cooling, efficiency standards shouldn’t apply.  Fortunately, ASHRAE took up the charge and updated Standard 90.1 so that equipment covered by ASHRAE Standard 127 is required to meet minimum efficiency standards.  Standard 90.1 has been adopted by the Department of Energy as a federal energy standard and is now referenced by many code authorities.

While useful and certainly progress, the choice enabled by these two standards is just a start.  Certainly new equipment can and should be compared based on energy efficiency ratings.  However we all know that equipment efficiency will vary considerably through use. It would also be useful to be able to  view and compare the operational efficiency of existing equipment in order  to evaluate which machines are working well, which should be replaced (using the new equipment efficiency ratings as a baseline of comparison) –  and how much efficiency could be gained (and calculated from an ROI perspective) through replacement.

Some HVAC manufacturers have taken up this challenge. NTT, for example, provides the coefficient of performance for its computer room air conditioners in real time, viewable on the front panel of each unit and through a communications interface.  We commend them.

The ability to compare initial purchase energy efficiency ratings against actual performance over time for a particular machine, gives data center managers the ability to not only track and evaluate a machine for individual performance durability, and compare its performance with that of similar machines.  Mechanisms and procedures can be put in place for maintenance as degradation is spotted.   Inefficient machines can be used less, fixed or phased out.

We challenge mission critical cooling system manufacturers to pull back the veil of secrecy on energy efficiency.  The time for transparency is at hand because this information is knowable.  The combination of smart sensors and analytics technology can already report dynamic machine-to-machine efficiency as this information is required to drive cooling optimization.  The smart decision is for HVAC manufacturers to get out ahead of this data, and use efficiency reporting as a differentiator and means of driving continual improvement.

Just as mandatory EPA mileage ratings and rising gas prices changed consumer buying decisions – and drove car manufacturers to offer cars with better gas mileage, more granular energy performance ratings will improve the efficiency of cooling equipment.  And this benefits all of us.

DCIM & ERP

Yes, DCIM Systems ARE like ERP Systems, Critical for Both Cost and Risk Management

Technology and manufacturing companies nearly all use sophisticated ERP systems for oversight on the myriad functions that contribute to a company’s operation.  Service companies use SAP. 

Data center managers more typically use their own experience.   With all due respect to this experience, the complexity of today’s data center has long surpassed the ability of any human or even group of humans, to manage it for maximum safety and efficiency.

As data centers have come to acknowledge this fact, they are increasingly adopting DCIM, the data center’s answer to ERP.   The similarities between ERP systems and DCIM are striking.

Just as manufacturing and technology firms needed a system to manage the complexity of operations, data center operations have grown and matured to the state that such systems are now required as well.

 Data Center Knowledge’s  Jason Verge says that “… [DCIM] is being touted as the ERP for the data center; it is addressing a complicated challenge.  When a device is introduced changes or fails, it changes the make-up of these complex facilities.”

Mark Harris of Nlyte said in a related Data Center Journal article: “DCIM was envisioned to become the ERP for IT.  It was to become the enabler for the IT organization to extend and manage their span of control, much like all other organizations (Sales, Engineering, manufacturing, Finance, etc.) had adopted over the years.”

Just like ERP systems, DCIM attempts to de-silo and shed light, along with management control, on cost and waste, while also addressing risk concerns.   In initial DCIM deployments the focus has understandably been on asset management.  Understanding the equipment you have and if this equipment is appropriate for your challenges was the right place to start. However, DCIM vendors and users quickly realized that elimination of energy waste, particularly energy wasted by unused IT assets, was another useful area of focus.  Cooling as a resource or even area of waste, was a tertiary concern.  Business managers no longer have this luxury.  The cost of cooling and the risk of a cooling/heating-related data center failure is too high.  As Michelle Bailey, VP of 451 Datacenter Initiatives and Digital Infrastructure said in a recent webinar on Next Generation Data Centers, Data centers have become too big to fail.  She also said that data centers are still using imprecise measurements of accountability – which don’t match up to business goals.  Processes must be made more transparent to business managers, and that metrics must be established and tie directly back to business goals.

Data center managers can and do make extremely expensive energy-related decisions from a cost perspective in order to reduce risk.  These may not even be bad decisions.  But the issue is that, without site visibility and the transparency that Michelle suggests above, business managers don’t realize that these decisions are being made at all, or that there may be options available which, with more analysis, make more sense from a business cost and risk trade-off perspective. And, while cost is one driver of the need for management oversight, waste (and its obvious effect on cost), is another.

As an example, a facility manager may turn his chiller plant down a degree to manage his cost function and perception of risk control.  This action has the cost equivalent of expensing a Tesla, but likely has no visibility to management.  Nor, typically, does the facility manager realize that he has less expensive and even less risky alternatives, because he/she has never had to consider them.   Facility managers are not traditionally accountable to energy savings.  They are accountable to uptime.  This thinking is outdated.  The two are no longer mutually exclusive.  In fact they are inextricably tied.  Proactive and intelligently managed energy saves money and reduces downtime risk by reducing the possibility of cooling failures.  If DCIM, like an ERP system, is used to understand and manage where cost – and waste- is being generated, it must specifically address and incorporate cooling infrastructure.

DCIM systems, offering granular data center information, aggregated and analyzed for business case analysis enables such oversight and with this, improved operational management.

 

 

Intelligent Efficiency

Intelligent Efficiency, The Next New Thing.

Greentech Media’s senior editor Stephen Lacey reported that the convergence of the internet and distributed energy are contributing to a new economic paradigm for the 21st century.

Intelligent efficiency is the next new thing enabled by that paradigm, he says, in a special report  of the same name.  He also notes that this isn’t the “stale, conservation-based energy efficiency Americans often think about.”  He says that the new thinking around energy efficiency is information-driven.  It is granular. And it empowers consumers and businesses to turn energy from a cost into an asset.

I couldn’t agree more.

Consider how this contrast in thinking alone generates possibilities for resources that have been hidden or economically unavailable until now.

Conservation-based thinking or, as I think about it in data centers, “efficiency by design or replacement,” is capital intensive.  To date, this thinking has been focused on new construction, physical infrastructure change, or equipment swap-outs.  These efforts are slow and can’t take advantage of operational variations such as the time-varying costs of energy.

Intelligent energy efficiency thinking, on the other hand, leverages newly available information enabled by networked devices and wireless sensors  to make changes primarily through software.  Intelligent energy management is non-disruptive and easier to implement.  It reduces risk by offering greater transparency.   And, most importantly, it is fast.  Obstacles to the speed of implementation – and the welcome results of improved efficiency – have been removed by technology.

Intelligence is the key factor here.  You can have an efficient system, an efficient design, but if it isn’t operated effectively, it is inherently inefficient.  For example, you may deploy one perfectly efficient machine right next to another perfectly efficient machine believing that you have installed a state-of-the-art solution.  In reality, it’s more likely that these two machines are interacting and fighting with each other – at significant energy cost.   You also need to factor in and be able to track equipment degradation as well as the risks incurred by equipment swap-outs.

You need the third element – intelligence – working in tandem with efficient equipment, to make sure that the whole system works at peak level and continues to work at peak level, regardless of the operating conditions.  This information flow must be constant.  Even the newest, most perfectly optimized data centers will inevitably change.

Kudos to Greentech Media for this outstanding white paper and for highlighting how this new thinking and the” blending of real-time communications with physical systems”  is changing the game for energy efficiency.

Cooling Doesn’t Manage Itself

Cooling Doesn’t Manage Itself

Of the primary components driving data center operations – IT assets, power, space and cooling – the first three command the lion’s share of attention.  Schneider Electric (StruxureWare), Panduit (PIM), ABB (Decathalon), Nlyte, Emerson (Trellis) and others have created superb asset and power tracking systems.   Using systems like these and others, companies can get a good idea as to where their assets are located, how to get power to them and even how to optimally manage them under changing conditions.

Less well understood and, I would argue, not understood at all, is how to get all the IT-generated heat out of the data center, and as efficiently as possible.

Some believe that efficient cooling can be “designed in,” as opposed to operationally managed, and that this is good enough.

On the day a new data center goes live the cooling will, no doubt, operate superbly.  That is, right up until something changes – which could happen the next day, weeks or months later.  Even the most efficiently designed data centers eventually operate inefficiently. At that point, your assets are at risk and you probably won’t even know it.  Changes and follow-in inefficiencies are inevitable.

As well, efficiency by design only applies to new data centers.  The vast majority of data centers operating today are aging. All of them have degraded with incremental cooling issues over time.   IT changes, infrastructure updates, failures, essentially any and all physical data center changes or incidents, affect cooling in ways that may not be detected through traditional operations or “walk around” management.

Data center managers must manage their cooling infrastructure as dynamically and closely as they do their IT assets.  The health of the cooling system directly impacts the health of those very same IT assets.

Further, cooling must be managed operationally.  Beyond the cost savings of continually optimized efficiency, cooling management systems provide clearer insight into where to add capacity, redundancy, potential thermal problems, and areas of risk.

Data centers have grown beyond the point where they can be managed manually.  It’s time stop treating cooling as the red-headed step-child of data centers.  Cooling requires the same attention and sophisticated management systems that are in common use for IT assets.  There’s no time to lose.

Machine Learning

Why Machine Learning-based DCIM Systems Are Becoming Best Practice.

Here’s a conundrum.  While data center IT equipment has a lifespan of about three years, data center cooling equipment will endure about 15 years. In other words,  your data center will likely  undergo five complete IT refreshes within the lifetime of your cooling equipment – at the very least.  In reality, refreshes happen much more frequently. Racks and servers come and go, floor tiles are moved, maintenance is performed, density is changed based on containment operations – any one of which will affect the ability of the cooling system to work efficiently and effectively.

If nothing is done to re-configure cooling operations as IT changes are made, and this is typically the case, the data center develops hot and cold spots, stranded cooling capacity and wasted energy consumption.  There is also risk with every equipment refresh – particularly if the work is done manually.

There’s a better way. The ubiquitous availability of low cost sensors, in tandem with the emerging availability of machine learning technology, is leading to development of new best practices for data center cooling management. Sensor-driven machine learning software enables the impact of IT changes on cooling performance to be anticipated and more safely managed.

Data centers instrumented with sensors gather real-time data which can inform software of minute-by-minute cooling capacity changes.  Machine learning software uses this information to understand the influence of each and every cooling unit, on each and every rack, in real-time as IT loads change.  And when loads or IT infrastructure changes, the software re-learns accordingly and updates itself, ensuring that the accuracy of its influence predictions remains current and accurate.   This ability to understand cooling influence at a granular level also enables the software to learn which cooling units are working effectively – and at expected performance levels  – and which aren’t.

This understanding also illuminates, in a data-supported way, the need for targeted corrective maintenance. With a clearer understanding and visualization of cooling unit health, operators can justify the right budget to maintain equipment effectively thereby improving the overall health and reducing risk in the data center.

In one recent experience at a large US data center, machine learning software revealed that 40% of the cooling units were consuming power but not cooling.  The data center operator was aware of the problem, but couldn’t convince senior management to expend budget because he couldn’t quantify the problem nor prove the value/need for a specific expenditure to resolve the issue.  With new and clear data in hand, the operator was able to identify the failed CRACs and present the appropriate budget required to fix and replace them accordingly.

This ability to more clearly see the impact of IT changes on cooling equipment enables personnel to keep up with cooling capacity adjustment and, in most cases, eliminate the need for manual control.  A reduction of the corresponding “on-the-fly, floor time corrections” also frees up operators to focus on problems that require more creativity and to more effectively manage physical changes such floor tile adjustments, etc.

There’s no replacement for experience-based human expertise. However, why not leverage your staff  to do what they do best, and eliminate those tasks which are better served by software control.  Data centers using machine learning software are undeniably more efficient and more robust.  Operators can more confidently future proof themselves against inefficiency or adverse capacity impact as conditions change.  For these reasons alone, use of machine learning-based software should be considered an emerging best practice.