Why upgrade your hardware when migrating to SAP ERP 6.0?  Because it makes simple, practical, business sense that is all.  SAP has identified several key reasons why customers are concerned about migration and several among them are as follows:

·         Cost, Cost, Cost

o   HW infrastructure cost is highlighted as one of the key barriers of migration

·         Business Justification

o   Is there a compelling business reason to upgrade the hardware?

·         Additional risk of business disruption

o   Migration of ERP environment is complex enough…how much more risk is there when upgrading your hardware?

From a cost perspective, the perception that hardware is a barrier to migration can be easily overcome.  Based on research, the hardware cost as a percentage of the overall migration cost is only about 7%.  That means 93% of the cost is in licensing, consulting, etc, etc.  HW costs are only the “tip of the iceberg” and the real $ investment lies elsewhere in the equation.

Is there a compelling business reason to upgrade your hardware? Well…frankly, it does not make sense not to do it.   One, we showed above that the hardware investment is minimal compared to SW licensing, consulting, service, etc.  Two, the hardware requirements of ERP 6.0 are significantly higher than previous versions. ERP 6.0 requires up to 2.5x more CPU performance, 2.5x more memory and 1.5x more I/O!  You will need the increased performance and scalability that Intel provides in our microprocessors.  While the ERP performance requirements have increased 2.5x, Intel performance with SAP has increased 10X!  Oh, btw…energy efficiency does matter and in your new ERP environment you will be able to consolidate servers and save on power and cooling costs.  TCO will be significantly reduced and from hardware investment standpoint, you are likely going to recover the cost of the servers in a very reasonable timeframe.

From my discussions with the IT community, their major concern and number one focus area is to prevent business disruption and downtime.  This costs companies real and significant money.  The fact is that an ERP migration is a complex enough project managing the strategic, functional and technical portions.  Adding a server infrastructure change increases fundamental risk.  But, the key here is that it is done often and done successfully.  Intel IT has published several whitepapers on the subject and communicated “Best Known Methods” to minimize that risk.    A quick summary is inserted here:

Challenge:

•         Convert Intel’s Worldwide Warehouse Management Software

•         Upgrade from SAP* ERP version 4.7 to 6.0, change the DBMS, and perform a Unicode* conversion as well as a hardware upgrade

•         Minimize downtime

Benefit to Intel IT:

•         SAP ERP 6.0 improves Intel supportability

•         Increases ease of integration to SAP NetWeaver* 7.1 Suite

•         Provides access to Enhancement Packs and Enterprise Services

•         Intel^® Itanium^®-based servers provide access to 128 GB of memory for database and SAP operations and significantly increased performance from true 64-bit processing

Key Results:

•         Reduced downtime of upgrade by 50% by using Intel Architecture

In summary,  upgrading your server infrastructure when migrating your ERP environment is a very, very complex task, but form a business perspective, it should be fairly easy to see the true benefits from combining the ERP migration and hardware upgrade at the same time.

“Imagination is everything. It is the preview of life's coming attractions.” Albert Einstein

Today’s workstation can provide you with a magnificent digital canvas to create tomorrow today.

With workstations powered by two Intel® Xeon® 5500 series processors, engineers have the opportunity to create, shape, test and modify products before they become real. Engineers can now design, visualize and simulate products from the conceptual design phase through the entire manufacturing process. This is done virtually before any investments are made in a prototype.

“Experiment fearlessly.” “Innovation is bloody random.” Tom Peters

Peters, a world renowned author and management consultant, recognized that innovation is more art than science.

Consider this example: Taking innovation to an entirely new level, Boeing, in the late 1990s, employed a process known as algorithmic design to see what designs might be viable to meet a specified hypersonic aircraft design criteria. The algorithmic design process enabled computers to create and test new ideas against the specified design criteria without human intervention. As a result, more models were evaluated in less time, and a vehicle that was counterintuitive to what many engineers may have thought possible was evaluated. Innovation just accelerated.

Intel technology has seen dramatic changes since Boeing first tested the idea of algorithmic design in the last decade. Workstation performance has gone up Dual-processor workstations have yielded to workstations with two processors, eight cores and 16 computational threads. Science or simulation that was never tractable on a workstation before is now standard, and it is getting faster.

“I confess that in 1901 I said to my brother Orville that man would not fly for fifty years.” Wilbur Wright

You think all you need is an entry-level workstation with a single Intel® Xeon® processor.                       After all , you only do CAD—right?

However, as you begin to adopt modern workflows and realize the dramatic impact that simulation-based engineering or digital prototyping can have on your product development cost and schedules, you realize that the cost of the second processor and additional memory necessary to support digital prototyping was far less expensive than the cost of multiple physical prototypes and the associated time to produce them. Instead of investigating hundreds of digital prototypes, you only have time to look at a single physical prototype and ask: What if I …?

Those “what ifs” could have been played out on a dual-processor Intel Xeon processor 5500 series-based digital workbench faster, and your time and cost of physical prototypes could have been significantly reduced.

Are your “stuck at the desktop?”   A May 2008 study from the Council on Competitiveness and IDC identifies the barriers large and small firms face in moving from desktop computers to High Performance Computing (HPC) servers.  

Among the study findings¹, most firms:

-          Reveal that they have important problems they cannot solve on their desktop systems

-          Face three major barriers to adoption:  lack of application software, lack of sufficient talent, and cost constraints

As a scientist, an engineer, or an analyst: Have you outgrown your desktop?  What kind of new innovation or capabilities would the use of a HPC cluster give you?  Imagine the capability to analyze data and gain more insight faster, or the ability to virtually prototype your ideas product more efficiently and cost effectively, or perhaps analyze, model, or simulate larger problems.

Few OEM products aimed at the personal or “desk-side” segment are making easier for end users to adopt HPC and help to overcome some of the barriers to adoption:  the Cray* CX1*, SGI* Octane* III, and HP’s  CP Workgroup System.  These products are aimed at addressing the needs of the entry level HPC market and the workstation users that have outgrown their desktops.  Both the Cray CX1 and SGI Octane III systems are Intel® Cluster Ready (ICR) program certified which means that Intel has worked with the hardware, system, and application vendors to ensure your configuration has been pre-tested for interoperability, so you can deploy with confidence.  ICR helps to reduce TCO by making sure the components keep working together over the cluster’s lifetime, to increase availability and save time for IT departments.

So if your IT department cannot buy you full blown super computer, ask them for a personal super computer.

¹ Source: Reveal.  Council on Competitiveness and USC-ISI Broad Study of Desktop Technical Computing End Users and HPC, May 2008 (http://www.compete.org/publications/detail/420/reveal/)

*Other names and brands may be claimed as the property of others

A virtual workstation uses both virtualization hardware and software technologies that, when combined, provides end users with an uncompromised workstation experience.  It gives engineers and IT user’s concurrent access to key workstation hardware functions previously not available with traditional virtualization technologies. Through this approach, you get near native access to key workstation services, such as those delivered by graphics cards or NICS, needed to run multiple high-performance applications regardless of the operating system they run on. . Best of all, with Intel® Virtualization technology for directed I/O, delivered by Parallels Workstation Extreme, you will be able to leverage this new virtual workstation capability in ways that improve workflows across operating systems while reducing IT management requirements.  This is a win/win for both you and IT.

Ok we have segregated compute resources between IT and the user. 

What can you get with Intel’s VT/d technology? 

How many times have you been faced with a need to run an application that runs on a prehistoric OS, or that runs 32 bit OS when your entire environment is running on 64 bit? Or maybe you need run two different graphics-intensive workloads in a LINUX and Microsoft Windows® environment.  With Intel VT-d and Parallels™ Workstation Extreme software you may be able to do just that at near-native speeds.

What else can you do with a virtualized workstation?

Have you ever been in a situation where one application requires version X and another application you use daily requires version Y of the same OS.  With Intel VT/d and Parallels™ Extreme® software you may be able run both at near native performance at the same time.  No rebooting, no dual booting or emulation required.  Just fast, seamless answers to complex problems – across multiple segments like Oil & Gas, DCC, Manufacturing, and Research.

Ever hear of a digital workbench?

It is a tool that designers and engineers use to perform what many call digital prototyping or simulation based engineering.  It is usually a set of tools that combine needs for LINUX and Microsoft Window® based applications to create and test their ideas.  Think of a virtual wind tunnel where simulations are performed in a LINUX environment and the design and visualization is performed in a friendly Microsoft Windows® environment.  With Intel VT-d and Parallels Workstation Extreme you can do both at near native speed.  That means interactive product development and engineering, and that leads to potentially better deigns in less time.

Do you need a virtualized workstation?

If you have a need to run applications in different OSes, diverse OS levels or types, or you need to visualize in different OSes, then answer is probably yes.

To learn more about Intel Virtualization Technology please visit www.intel.com/go/workstation.

To see an online demo of Parallels™ Workstation Extreme software please visit http://www.parallels.com/products/extreme

Hi All,

You found the Intel XEON Workstation Sweepstakes!

Click HERE to start the quiz and submit your entry today !

Good Luck to all.

Your most valuable employee is the one that creates tomorrow’s successes.  Providing them tools that help them do that faster will help your organization create new products or optimize old ones more rapidly.  The benefit to the organization is increased opportunities to win the customer’s attention via new products or your responsiveness to their request; the employee gets to brag on what he or she just helped bring to market.

Before we get too far let’s look at Intel’s mission with respect to workstations.  We are laser focused on supplying technology that provides users with an uncompromised experience in transforming their ideas into reality.  With that in mind we look at how users create; we try understanding their obstacles and work with the ecosystem of hardware and software providers to deliver solutions to real problems that may be inhibiting their opportunity to innovate.  

One technology that is helping users innovate faster is virtualization. 

No, we are not looking to remove the workstation from the user’s desk or share his or her workstation with peers, who also need a workstation.  We are using virtualization to deliver the performance they need to innovate faster.

The Observation

We saw workstation user’s innovation slow as they multitasked between tasks – some of them not even theirs.  The involuntary tasks included deploying IT security patches, updates, and system backups to name a few.  We also saw that users were no longer just doing Computer Aided Design (CAD) alone, but they were doing CAD, using productivity tools, meshing, web surfing for supporting facts, collaborating via video and Instant Messaging (IM) tools, digital white boarding and trying to do analysis-driven design.  They were very busy people who can’t afford any downtime or slow time.

In some cases we noticed that some users actually had not one, but two or more workstations running in completely different environments, many times with different OSs.

The Problem

What the above really lead to is a conclusion that too many tasks were going after too few resources and that the experience we had hoped the user would encounter was not happening.  In fact the reverse was happening – interactive creative tasks were slowing, system sluggishness was at an all time high.  The “uncompromised experience in transforming their ideas into reality” we wanted for a workstation user was not there and any innovation that was possible was slowed down to a crawl.

A Potential Solution

Intel® Virtualization Technology for Directed I/O (Intel VT-d), once just thought of for servers actually has a place in the workstation market. 

This technology provides an important step toward enabling a significant set of emerging usage models in the workstation. VT-d support on Intel platforms provides the capability to ensure improved isolation of I/O resources for greater reliability, security, and availability.  That is a mouth full let’s see it in action.

There are two key requirements that are common across workstation usage models.

1.       The first requirement is protected access to I/O resources from a given virtual machine (VM), such that it cannot interfere with the operation of another VM on the same platform. This isolation between VMs is essential for achieving availability, reliability, and trust. This helps you get the performance you want from your workstation.

2.       The second major requirement is the ability to share I/O resources among multiple VMs. In many cases, it is not practical or cost-effective to replicate I/O resources (such as storage or network controllers) for each VM on a given platform.

In the case of the workstation, virtualization can be used to create a self-contained operating environment, or "virtual software appliance[RC1] ," that is dedicated to capabilities such as manageability or security. These capabilities generally need protected and secure access to a network device to communicate with down-the-wire management agents and to monitor network traffic for security threats. For example, a security agent within a VM requires protected access to the actual network controller hardware. This agent can then intelligently examine network traffic for malicious payloads or suspected intrusion attempts before the network packets are passed to the guest OS, where user applications might be affected. Workstations can also use this technique for management, security, content protection, and a wide variety of other dedicated services. The type of service deployed may dictate that various types of I/O resources, graphics, network, and storage devices, be isolated from the OS where the user's applications are running.

The Result

In collaborating with virtualization and automation leader, Parallels, on its Parallels Workstation Extreme solution,  we identified two impediments to workstation user productivity.  The first was the issue around general resource overhead that afflict a traditional virtualized workstation system due to  insufficient resources to address the overload of requests. The second issue explored includes the more complex problem of a single workstation with the need to support multiple OSs and display visualization programs at near- or full-performance within virtualized machines.

The first issue was more straightforward - create VMs, partition resources and now the user has a very resilient workstation that is capable of delivering the intended experience.  IT can have their VMs and the user has his or her workstation back and the concept of digital prototyping to create and explore a complete product before it is built is a reality.  The creative innovator in the company can now iterate through more ideas in less time and your company created more opportunities to catch the customer’s attention just went through the roof.

The second issue offered a more complex challenge.  We identified certain industries such as the oil and gas exploration space where users actually had two or more physical workstations - one running Windows, the other running Linux. Both workstations had visual display requirements by the end user and both computers acted on the same reservoir data with applications that while similar in many ways, were still different in their functionalities and purpose.  In oil drilling projects that typically involve millions of dollars in capital investment, the confirmation of expected end results is an asset that far outweigh the costs of a few workstations. Nevertheless, in today’s economic setting, the ability to get the same functionalities at a lower cost is one of many key drivers in helping companies achieve healthy bottom lines.

The Proof Point For Virtualization In A Workstation Engineers from Schlumberger, a leading oil field service provider, run performance-demanding applications such as GeoFrame* and Petrel*.  These applications serve to analyze complex geological and geophysical data and determine the viability of potential reservoirs, or to optimize production at existing sites. With GeoFrame running on Linux* and Petrel on Microsoft Windows*, Schlumberger engineers have been using these applications on two separate physical workstations, driving IT spending higher, pushing down user productivity and increasing both power consumption and IT maintenance costs.

A New Paradigm For A New Day

With the availability of Intel Xeon processor 5500 series-based workstations, game-changing workstation virtualization software such as Parallels Workstation Extreme has opened up new horizons with breakthrough graphics performance with Intel’s latest processor technology. Parallels Workstation Extreme is built on top of the Parallels FastLane Architecture that effectively leverages the full potential of hardware resources such as graphics and networking cards to offer optimal workstation performance.

In comparison testing, Schlumberger compared the concurrent performance of applications running side-by-side on a virtualized Intel Xeon processor 5400 series-based workstation with the same setup on the newer Intel Xeon processor 5500-based machine. The results were astounding. The first machine with the older processor without Intel-VT-d support ran Petrel on the host OS at full native speed, but performance for GeoFrame in a VM slowed enormously. While Petrel refreshed its graphics at a rate of 30 frames per second, GeoFrame crawled along at a graphics refresh rate of JUST one frame every 19 seconds, an agonizingly slow performance on an older workstation without Intel VT-d support.

When the group tested the same applications on the newer Xeon 5500 series workstation with Intel VT-d support, the results were striking: Both applications – Petrel running on the host OS and GeoFrame in a guest OS in a VM - ran at full native speed, and both were able to refresh graphics at near 30 frames per second—a 570 times improvement over the first workstation.

Russ Sagert, Schlumberger’s Geoscience Technical Advisor for North America said “our engineers were blown away by the performance. We hammered these machines with extreme workloads that stressed every aspect of the system. Amazingly, the new workstation based on the Intel Xeon processor 5500 series provided performance enabling this multiple OS, multiple application environment for the first time.”

The key element in Schlumberger’s new environment is Intel Xeon processor 5500 series-based workstations with Intel® Virtualization Technology (Intel® VT) for Directed I/O (Intel® VT-d).  Together, these technologies enable direct assignment of graphics and network cards to virtual machines, enabling the machine to circumvent the interrupt and exit loop and clearing the previous performance problems.

Running in conjunction with Parallels Workstation Extreme, which effectively leverages Intel Virtualization Technology, including VT-d, the solution revolutionizes virtualization for high-end users. “High-performance virtualization on Intel Xeon processor 5500 series-based workstations is a game-changing capability,” says Sagert. “We can allocate multiple cores, up to 64 GB of memory and a dedicated graphics card to each machine. The results are spectacular.”

In the final analysis, moving to the Intel Xeon Processor 5500 series of next-generation workstations does far more than cut costs. It impacts the way that work gets done. If you have clients running the kind of resource-intensive, graphics-rich applications that traditionally slow to a crawl in a virtualized environment, consider the benefits of finally moving beyond the I/O barrier.

A fully configured Intel Xeon Processor 5500 series-based workstation running Parallels Workstation Extreme delivers the performance level that makes a virtualized workstation a leading contender for users with multi-workstation requirements. A streamlined work interface, reduced office noise and clutter, access to the same data repository and significant performance gains works on the user side. But the IT organization also gains benefits by lowering capital, management, support, provisioning, data protection, space, and energy and cooling costs.

Moreover, the IT team can now standardize on a single OS image while addressing alternative requirements.

Learn More

Intel Workstation Processors http://www.intel.com/products/workstation/processors/index.htm

Parallels Workstation Extreme

http://www.parallels.com/products/extreme

Are you a developer writing applications to run on the Solaris operating system?. Are you looking for ways to optimize your Solaris solution on industry standard architecture based on Intel microprocessor? If you answer yes to either of these questions then please read on.

Intel and SUN have been working closely together to optimize the Solaris operating system on the Intel Xeon 5500 processor. Most of you probably know the Xeon 5500 better by its product codename Nehalem. The Xeon 5500 is the the product that fits into 2 socket platforms.

SUN have just published a very compelling quick reference guidethat will assist both Developers and System Administrators looking to optimize Solaris solutions on Xeon based processors. The guide talks about the work that Intel and SUN are doing together, technical descriptions of specific features and capabilities that can be implemented in the Solaris OS to optimize the capabilities of the Xeon.

I have just finished reading this and it is a very compelling paper covering topics such as

- How Solaris takes advantage of Intel Turbo Boost Technology to use available power headroom to deliver higher performance based on workload demand

- How Solaris can take advantage of new Intel Quickpath Interconnect (better known as QPI) and other innovations in the OS to reduce memory latency

- How Solaris performance counters help to better manage workloads

- How Solaris takes advantage of many of the power efficiency capabilities in the processor. Things like Power Aware Dispatched in Solaris enable the processor to stay longer in idle states. In non tech talk this saves power.

Solaris has been a tried and tested operating system for along time for companies running their most business critical workloads. This paper talks about the combination of Solaris and Xeon to deliver improved reliability and availability for these critical workloads. Detail information on predictive self healing, fault management, leveraging Intel Machine Check Architecture and more all included in this paper.

Probably my favourite section is around the developer tools optimizations and the different tools available for developers that want to run and optimize their applications on Solaris and Xeon.

Ok, I'll stop waxing lyrical now. This is a very compelling paper and it does certainly construe that Solaris and Xeon 5500 could be the perfect combination for your Solaris solution. What do you think?

What do Jack Welch, Henry Ford and Albert Einstein have in common?

In their day they were innovators and they all accepted the need to adopt and change. 

Einstein once said “The definition of insanity is doing the same thing over and over again and expecting different results.” He obviously had no interest in repeating history over and over again.

Ford was heard to say “I am looking for a lot of men who have an infinite capacity to NOT know what can't be done.” He obviously was looking for people who asked “why” as opposed “why not.”  He sought thinkers and tinkerers.

Jack Welch had the shortest, but the most interesting quote.  “Change before you have to.”  As we all know he embraced change and created it too.

Technology gives us an opportunity to look at what we are doing now and find a better way to do it.  Used correctly, it can help you do more in less time with higher quality results.  Take the digital workbench (aka dual processor Intel® Xeon processor 5500 series based workstation) as an example.  While it can do CAD, it is really capable of much more.  It can help users model more what if’s than ever.  It can help users create and test ideas digitally long before they are made into physical prototypes.  While these new workstations can do this many continue to do just CAD.

What new workflows can you think of that will radically change the rate of your innovation?