Inside Frequency Control

What's the best way to solve a problem? Preventing the problem from occurring in the first place (or knowing exactly how to tackle an inevitable problem whenever it occurs). In this post, we're going to cover 8 of the most common RF engineering problems that impact RF engineers on the regular. Making yourself more aware of these frequent RF engineering problems will allow you to be more prepared with a solution (or even prevent them from happening in the first place). Less problems = better engineering productivity & happier RF engineers!

Ahh the mysterious OCXO. What the heck is an OCXO anyway? What's it good for? When should you use one in your electronic system design? These questions and more will all be answered in this post.

Precise timing across a variety of networks and industries is becoming a necessity. Both operationally and legally.  It's actually pretty amazing to see the evolution of timing & frequency control throughout different industries. There's been significant timing innovations over the past 5-10 years alone.

RF engineering is a branch of Electrical Engineering involving the use of electrical magnetic frequency properties to produce products that will transmit or receive these frequencies.

RF engineers can face a lot of challenges and frustration. This frustration can be caused from all the discrepancies and complex maps of components used in RF circuits.

In order to be a successful RF engineer, a few habits and processes can be formed. Here are 10 critical tips to be an efficient RF engineer.

Businesses now have more of an incentive than ever before to invest in robotics and other automated systems. Thanks to continued advances in technology, such systems let buyers achieve higher levels of efficiency and precision than they would if they spent the same sums on purely human capital.

The benefits don’t end there, though. Automation can also generate solutions to persistent safety challenges. In this article, we will describe several types of automated safety solutions and examine their use in real-world manufacturing, machining, and construction environments.

A Modular Open Systems Approach (MOSA) is becoming critical in Department of Defense (DoD) systems. If you're unfamiliar with this critical system design approach (or need a little brush-up) you're in the right place (and should totally keep on reading to discover the 5 core principles).

But first, a few quick basics. MOSA is a business and technical strategy for easily developing new defense systems or modernizing existing ones. This will help the Department of Defense provide joint combat capabilities required for 21st century warfare.

MOSA also provides the ability to support and evolve these 21st century capabilities over their total life-cycle.

ERIE, PA — TBD

Bliley Technologies, leader in the design and manufacturing of Precision Oscillators and Timing Solutions for Communication, Industrial, Military, and Space applications, today announced they have entered into an agreement with AccuBeat to be their exclusive partner in North America.

The development of crystal oscillators has literally changed the world. Technically that can (and is) said about many things. But think about it! Without crystal oscillators, we may have never seen precision timing in clocks, wide and clear radio broadcasts, or important communication methods within military and space programs.

Imagine how different our world might be without these now commonplace technologies.