Simulating Power Transients and Noise
1 Hour | Webcast - enregistré | Where & When
What is the webcast about:
DC powered Shipboard, ground vehicle, aircraft, and space bound electronic circuits and assemblies employ a robust input power supply design to withstand non-ideal input power states. These non-ideal states arise from operating conditions such as large load changes on the main power source, harsh operating environments, and sudden switches from one main power source to another. These non-ideal states take the form of transients on the DC supply level or as noise signals coupled onto the DC supply level. During design these non-ideal power supply states must be simulated to test the input power supply design’s robustness against these conditions.
In this webcast we will look how easy it is to create arbitrary power waveforms on modern programmable power supplies for simulating supply transients and noise. We will also look at the technology hurdles that limit the arbitrary waveform bandwidth on modern supplies. Finally we will look at low cost methods for simulating fast power supply transients and high frequency noise beyond the bandwidth limitations of modern power supplies.
Who should attend:
R&D and design validation engineers working with DC power distribution designs for defense electronic systems for aircraft, shipboard, satellite, and battle field vehicles.
Neil Forcier, Application Engineer
Neil Forcier served in the US Navy as an Electronic Test Equipment Calibration Technician on board the USS Harry S Truman CVN-75. Neil earned his bachelors degree in engineering from the Pennsylvania State University, University Park campus. He is currently working as an Application Engineer for the System Products Division at Agilent Technologies. His areas of focus includes instrument control software, data analysis, and advanced power applications.
Where & When
|Price||Location||Pour plus d'information|
|call for price||At Your PC||Enroll for the Jun 21, 2012 recorded broadcast|
Prix susceptibles de modification sans préavis.