Why a Mobile Workstation?

Technical white paper | Building reliability into HP Workstations

System reliability is essential for workstation users. At HP, we recognize that professionals can’t settle for anything

less than the highest levels of reliability. System crashes, component breakdowns, and sluggish performance can bring

work to a halt and result in several hours or days of lost productivity. That’s why we design our workstations to meet the

challenges of the most demanding workloads and duty cycles— an HP focus for the past 30 years. Three decades of

workstation engineering innovation has created a level of reliability that is widely recognized in the industry.

Here are some of the things we do to make the HP Workstation name synonymous with rock-solid reliability.

A strenuous design standard

We design our systems based on workstation application demands, a rigorous customer use model and a design

standard that goes beyond just the warranty period. Our design model is based on “Class 2” electronics

—a level reserved

for highly reliable systems with demanding workloads. Class 2 electronics assumes a use model well beyond the normal

limited work cycle of a typical home computer or consumer electronic device, which are usually specied as Class 3.

HP Workstations are designed and built for mission-critical workloads and always-on environments. As such, they

employ many of the same types of components used in servers. These components include Intel® Xeon® processors,

error correcting code (ECC) memory, and enterprise-class storage technologies, such as 15K Serial-Attached SCSI (SAS)

and solid-state drives (SSDs).

We oer power supplies with high standards for hold-up time, capacitor life, and operating temperature. Long hold-up can

help sustain reliable power delivery in spite of poor AC power conditions. Capacitors are chosen to provide long lifetimes

at elevated temperatures. Every new aluminum electrolytic “can” capacitor must pass a rigorous set of reliability tests

before it can be considered in our designs. We work closely with processor suppliers such as Intel to ensure our power

delivery and cooling solutions meet or exceed all of the suppliers’ specications for both steady state and transient

workloads. We design for high operating temperatures to meet the demanding workloads of workstation customers.

Even the smallest and most common electronic components, like resistors and capacitors, are carefully chosen based

on quality, reliability, and top performance. A dedicated team in the HP Workstation Research and Development

organization performs a thorough assessment of every critical component and tracks even the smallest manufacturing

changes to these components during the lifetime of the product.

Brutal three-axis testing

In choosing workstation components, we don’t stop at the specications in the manufacturer’s data sheet. In our

workstations test lab in Fort Collins, Colorado, we subject components to rigorous testing to verify their performance

under extreme conditions. In brutal three-axis testing—where frequency, voltage, and temperature are varied—our

engineers push the limits of processors, memory, and other system parts.

This testing goes far beyond the boundaries of typical use models. Inspired by a long history of workstation technologies

development, including HP-designed processors and chipset or graphics chips, this three-axis testing uses proprietary

tools and techniques, and stresses components in ways that help detect potential design or component weaknesses that

would otherwise go unnoticed. Various memory DIMM modules, for example, often fail our three-axis testing, and are

disqualied by HP despite being used by other workstation manufacturers. Memory suppliers, in turn, often look to HP to

identify design and silicon issues in their products.

Ultimately, this aggressive testing program yields extremely reliable end-products. It allows us to design and ship

workstations with robust functional margins and components that can easily handle the conditions and workloads of

professional environments from car test tracks to oil elds, from manufacturing oors to construction trailers and other

rugged environments.