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How to Migrate VAX Workloads Without Expensive Rewrites?VAX servers were introduced in the late 1970s. They revolutionized minicomputing with its exceptional virtual memory capabilities. DEC VAX has powered critical applications and workloads across various industries like finance, manufacturing, and energy for decades. But now maintaining this obsolete hardware is becoming challenging due to hardware failures, high energy costs, security vulnerabilities, and scarce expertise.
Businesses are now struggling to run their critical workloads like OpenVMS and other legacy VAX applications without any expensive replacements or rewrites. Stromasys introduces Charon VAX, a hardware emulation solution that uses a lift and shift migration strategy without disrupting the operations, cost-effectively. It extends the life of legacy VAX applications without any modifications and is available for both on-premises and cloud ecosystems.
ArticlesVAX servers were among the first to bring virtual memory to minicomputers. They were widely used throughout the 1980s and early 1990s, powering legacy applications across many industries.
It evokes nostalgia for those who worked with its powerful minicomputing systems. But, for businesses running their critical applications on this obsolete hardware, it can be nothing short of a nightmare.
In this detailed article, we will delve deeper into VAX servers, their use cases, key models and what the future holds for.
VAX stands for Virtual Address eXtension. VAX Servers are a series of 32-bit minicomputers developed by Digital Equipment Corporation (DEC) in the late 70s. The supported operating system for VAX computers was VAX/VMS (renamed OpenVMS in 1991).
These servers ran the VAX instruction set architecture (ISA), which had advanced virtual memory management capabilities. The hardware was highly configurable to meet specific operational needs. It became widely adopted across many industries like government, telecom, education, and others.
VAX systems supported concurrent users and were initially isolated from networks. Later it connected to a wider network via DECnet and used “set host” to access other systems.
These systems were network-oriented variants of standard VAX computers. They were configured with firmware and CPU modules to run operating systems exclusively optimized for server tasks (rather than time-shared environments).
Research and development over almost two decades led to the development of several models, from VAXserver 3000 to VAXserver 9000. Each model was designed to meet specific workloads and budgets.
The following are examples of how organizations commonly use DEC VAX servers to run their legacy workloads.
Energy companies relied on VAX servers for 24/7 real-time monitoring, ensuring continuity and safety standards. Their stable operating system made them ideal for critical infrastructure.
With their multitasking abilities, VAX servers powered inventory systems, logistics planning, and operational analytics for supply chains.
From automating production to managing supply orders, VAX servers were widely used in factories producing machinery, doors, electrical components and a lot more.
Banks and financial institutions used DEC VAX servers to support transactions and manage databases. Technology providers for financial institutions also used VAX servers.
Universities and research labs leveraged VAX systems for computational modelling and data-heavy experiments. Their versatility made them crucial tools for innovation in science.
Despite their historical significance, VAX servers are now a liability for enterprises keeping them. Here’s why:
System failures are costly. Not only that, but it also hampers productivity and brings reputational damage.
VAX hardware has reached its end-of-life, and finding its replacement is difficult as it is no longer manufactured.
Aging VAX servers consume a lot of power and significantly increases operating costs.
Specialized knowledge for maintaining these VAX servers is dwindling as experienced professionals retire.
Mostly, there is a lack of support from vendors, with no more operating systems and firmware patches for these systems. This is making the legacy application susceptible to cybersecurity risks.
In the era of AI and cloud computing, businesses should focus more on innovation. But with legacy hardware, they are spending most of their time and IT budget on things from the past.
It is not possible for these systems to meet the evolving demands of today’s enterprises.
Even though VAX servers appear to be working at the moment, they could fail anytime soon. But the operating system (OpenVMS) and applications are working fine.
In fact, these applications support business-critical workloads and are so deeply integrated into your business that changing them is risky. And sometimes, VAX server replacement is not possible.
Relying on scarce spare parts for VAX server replacement is not a long-term solution.
Hardware emulation (lift and shift) is a quick, frictionless, and cost-effective method for extending the lifespan of legacy applications without the need for DEC VAX servers. It uses the lift-and-shift migration strategy to move critical applications from obsolete VAX hardware to modern platforms like x86 servers or cloud environments.
Best part? The application’s functionalities and the environment in which it runs remain unchanged. By moving to the cloud, enterprises can also enjoy added flexibility such as the pay-as-you-go model. With both on-premises and cloud environments available, businesses can choose the platform that best suits their requirements and transform their legacy infrastructure.
WorkflowOne, one of the largest providers of managed print and promotional marketing services in the US was struggling with its VAX VMS servers. There was a lack of performance. Power consumption was exorbitant. In addition, these giant computers were taking up a lot of space. This prompted the company to search for a solution that would address these issues while improving the efficiency of their critical processes.
One of Stromasys’ partners introduced them to Charon-VAX, and everything changed thereafter. Once the emulator was installed, they found transformative results:
If eliminating legacy hardware risk is on your mind, there is nothing better than hardware emulation. That too when you have a leader in this field at your disposal. The above success story is not one-of-a-kind. Over the years, Stromasys has helped hundreds of brands eliminate legacy hardware risk. Would you like the same support our clients receive?
Extend the life of your legacy
VAX workloads with Charon VAX without modifying the original code.
The full form for DEC VAX is Digital Equipment Corporation Virtual Address eXtension.
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