When engineers tackle a project that uses ZigBee communications they may get a surprise. Unlike point-to-point communications, ZigBee involves a network that can establish nodes, repeaters and complex mesh topologies. The proper test tools--often called "sniffers"--help engineers diagnose ZigBee-network problems that could otherwise turn into nightmares.
On June 2, 2008, the Environmental Protection Agency (last seen as the supervillains in “The Simpsons” movie) released a “technical amendment,” version 4.2, to the Energy Star residential light fixture specification. Remember when Nintendo introduced the ubiquitous “Seal of Quality?” The great crash of 1983 was caused by a number of factors, not the least of which was lousy software...
The recent cries over shoddy manufacturing performance have put electronic product designers in a tough spot – and frankly, left them baffled. Time after time, their design concepts that had the makings of a sure bet evolved into a product with deficiencies reported from thousands of customers – leaving many unanswered questions.
Networks Take High Performance Motion Control to the Next Level Networks simplify software development, axis coordination, code updates, and system characteristics.
What are the most important factors to consider when developing a new product?
Power has the essential role in the operation of a factory since no machinery can run without it, but power isn’t a guarantee. Companies performing industrial automation lose up to millions of dollars and hours of production time annually due to power anomalies. There are two types of power anomalies: natural phenomena which are harder to control and internal anomalies which are easier to control.
“Can you stand another ZigBee presentation?” was the greeting I received from one of the many exhibitors I met at the 2008 Sensors Expo in Rosemont, IL. Indeed, wireless industrial networking devices were in abundance at this year’s show, along with what seemed like an increasing amount of companies presenting MEMS-based devices.
Many designs require a small amount of high-speed, instant-on programmable logic. These designs drive the thriving market for Complex Programmable Logic Devices (CPLDs). This article examines the definition of CPLDs, their applications, design methodologies and which factors to consider when selecting a CPLD.
Developing Comprehensive, Cost-Effective Hardware and Software Solutions for the Cardiac Device MarketAugust 6, 2008 10:46 am | by Jose Villasenor Fernandez, M.D., Global Medical Applications Specialist, Freescale Semiconductor and David Niewolny, Medical Product Marketing Manager, Freescale Semiconductor | Comments
According to the World Health Organization, cardiovascular disease is the leading cause of death globally. An estimated 17.5 million people died from cardiovascular disease in 2005, representing 30 percent of all global deaths. Of these deaths, 7.6 million were due to heart attacks, and 5.7 million were due to stroke. By 2015, an estimated 20 million people will die from cardiovascular disease every year, primarily from heart attacks and strokes. Many of these deaths may occur with no previous symptoms of cardiovascular disease.
At one time, the gulf between 16- and 32-bit processors seemed wide and deep, so engineers had a difficult time making the transition from one realm to the other. Many processor manufacturers have helped eliminate that gulf and many development boards and tools simplify the migration between those realms.
Multi-processor computers have existed for some time, but only within the last few years have engineers had the opportunity to buy off-the-shelf chips with more than one processor or "core." These devices come in two varieties; symmetrical and asymmetrical. The first group provides multiple "clones" of the same core CPU, thus the term symmetrical. The second group includes devices that put different types of CPUs, DSPs, and accelerators in a system on a chip. I'll concentrate on the former multi-core technologies.
Traditionally, precision full wave rectifiers1 used in a range of instrumentation applications have employed between 7 and 9 discrete circuit components. These are typically 2 op-amps, 2 diodes and 3 to 5 resistors. This article will show that an alternative approach, using a standard current monitor IC, reduces the component count to just five and greatly simplifies circuit configuration and produces a more elegant overall solution.
The electronics distributor plays an important role in the electronic components industry, selling engineers the components and subsystems they need to use in their designs. A growing number of distributors also provide value-added services such as design support to their customers. With the combined pressure of the shrinking design cycle and expanded technology availability, it’s important for engineers to be able to talk to someone who can help them throughout the design process. We recently cold-called a number of major distributors without identifying ourselves as press and simply asked what design services they perform.
Change is a key word in our industry. Technology has progressed so far so fast it is amazing to see how far we have come in such a relatively short time. We are swept downstream in the relentless river of development, buffeted by currents from so many quarters the pattern seems random. Disruptive technologies shove us in one direction as convergence tips us in another...
Failures of semiconductor ICs are typically due to overvoltage or overcurrent for a given junction temperature. This overvoltage can be caused by an external factor or an uncontrolled switching inductance. The overcurrent failure can be caused by excess junction temperature due to excessive power losses and a poor thermal path or an abnormal load current. It is typical for a failure report to state Electrical Over Stress(EOS).