Elementary Mr. Watson: Navigating RF—A Glide Path Approach to Design Success
Designers Notebook: Layer Stackup Planning for RF Circuit Boards
Connect the Dots: Involving Manufacturers Earlier Prevents Downstream Issues
Quiet Power: Dynamic Models for Passive Components
May 11, 2016 | Istvan Novak, OracleEstimated reading time: 1 minute
A year ago, my Quiet Power column described the possible large loss of capacitance in multilayer ceramic capacitors (MLCC) when DC bias voltage is applied. However, DC bias effect is not the only way we can lose capacitance. Temperature, aging, and the magnitude of the AC voltage across the ceramic capacitor also can change its capacitance.
Finally, the initial tolerance needs to be considered as well. In the worst case, we may lose up to 90% of the capacitance for an X5R capacitor, and even for an X7R capacitor. This column will show you the details and also how the most advanced manufacturers are helping the users with new simulation models to take these effects into account.
As an actual example, let us look at one of the capacitors that was extensively tested, where 1uF 0603-size 16V capacitors were tested from various vendors. We further assume that we want to use the part on a 12V supply rail, where the AC noise is low (this will be important later when we take the AC bias dependence into account). Some of the samples were chosen with X5R, some with X7R temperature characteristics. As showed with actual test data , X7R capacitors are sometimes worse for DC bias sensitivity than X5R parts.
If we take the part from Vendor B (labeled B7) in Figure 1, we see that at 12V DC bias we can lose 60% or 70% of the capacitance, dependent on which way the DC bias changes. But when we need to consider the worst-case capacitance loss, we have to consider the cumulative effect of all of the following factors:
- Initial tolerance
- Temperature effect
- DC bias effect
- AC bias effect
- Aging
The sample had +-10% initial tolerance. The X7R temperature characteristics comes with an additional +-15% tolerance window for the temperature variation.
To read this entire article, which appeared in the March issue of The PCB Design Magazine, click here.
Share on:
Suggested Items
DARPA Selects Cerebras to Deliver Next Generation, Real-Time Compute Platform for Advanced Military and Commercial Applications
04/08/2025 | RanovusCerebras Systems, the pioneer in accelerating generative AI, has been awarded a new contract from the Defense Advanced Research Projects Agency (DARPA), for the development of a state-of-the-art high-performance computing system. The Cerebras system will combine the power of Cerebras’ wafer scale technology and Ranovus’ wafer scale co-packaged optics to deliver several orders of magnitude better compute performance at a fraction of the power draw.
Altair, JetZero Join Forces to Propel Aerospace Innovation
03/26/2025 | AltairAltair, a global leader in computational intelligence, and JetZero, a company dedicated to developing the world’s first commercial blended wing airplane, have joined forces to drive next-generation aerospace innovation.
RTX's Raytheon Receives Follow-on Contract from U.S. Army for Advanced Defense Analysis Solution
03/25/2025 | RTXRaytheon, an RTX business, has been awarded a follow-on contract from the U.S. Army Futures Command, Futures and Concepts Center to continue to utilize its Rapid Campaign Analysis and Demonstration Environment, or RCADE, modeling and simulation capability.
Ansys to Integrate NVIDIA Omniverse
03/20/2025 | ANSYSAnsys announced it will offer advanced data processing and visualization capabilities, powered by integrations with NVIDIA Omniverse within select products, starting with Fluent and AVxcelerate Sensors.
Altair Releases Altair HyperWorks 2025
02/19/2025 | AltairAltair, a global leader in computational intelligence, is thrilled to announce the release of Altair® HyperWorks® 2025, a best-in-class design and simulation platform for solving the world's most complex engineering challenges.