Multilayer Ceramic Capacitors (MLCCs)

著者 Ashley Awalt

Digi-Key Electronics の提供


This document will cover the basics of multilayer ceramic capacitors, the proper procedure to test them, and a description of the aging/de-aging process.


MLCC (multilayer ceramic capacitors) are the most prevalent capacitors utilized in the electronics industry. Class I ceramic capacitors (ex. NP0, C0G) offer high stability and low losses in resonant circuits, but low volumetric efficiency. These do not require any aging corrections. Class II and Class III (X7R, X5R, etc.) offer high volumetric efficiency, but a lower stability than Class I dielectrics. These can sometimes require aging correction if they are outside of the manufacturer’s referee time. The referee time is the timeframe the manufacturer deems the capacitor to be within the specified tolerance range.

Image of typical MLCC

Figure 1:Typical MLCC


Most LCR meters are unable to test high value (1 µF and higher) MLCCs due to their internal impedance. The impedance is so low at 1 KHz that it virtually drains the current supplied by the meter, ultimately dropping the specified voltage to 0, never allowing the capacitor to be exposed to the required voltage for testing. To verify, measure the voltage across a capacitor under test with a true RMS meter. If the voltage is less than 0.4 VRMS, the capacitance reading will be low. Select LCR meters have an impedance matching capability function called Automatic Level Control (ALC). These meters will decrease their own impedance until it’s lower than the device being tested. More often than not, this is still not enough and an amplifier unit is necessary to increase the current through the capacitor until the voltage across it reaches a pre-set level from 0.5 VRMS-1 VRMS.


Capacitors classified as having a high dielectric constant will decrease in capacitance over time. This is typically noted as a percentage drop per decade of time. Temperature compensating capacitors (Class I) don’t have aging characteristics.


If aging has affected a capacitor, it can be reversed by heating it above its Curie temperature. The Curie temperature for most manufacturer specifications is approximately 125°C or higher, and is often achieved during the soldering process. Be sure to check the manufacturer’s specs before attempting this. Heating the capacitor above the Curie temperature will realign the molecular structure of the dielectric material, restoring the MLCCs capacitance. The capacitance will often measure high at this point, and one should wait until the referee time has passed so the capacitor will be within the spec tolerance again. After the capacitor has cooled, the aging process will restart.


  1. Kemet Measure Capacitance of Class-II and Class-III Ceramic Capacitors PDF
  2. Murata Ceramic Capacitors FAQ
  3. TDK Corporation Ceramic Capacitors FAQ PDF
  4. Digi-Key Testing High Capacitance MLCCs Forum

免責条項:このウェブサイト上で、さまざまな著者および/またはフォーラム参加者によって表明された意見、信念や視点は、Digi-Key Electronicsの意見、信念および視点またはDigi-Key Electronicsの公式な方針を必ずしも反映するものではありません。


Ashley Awalt

Ashley Awalt氏はアプリケーションエンジニアリング技術者で、2011年からDigi-Key Electronicsに携わっています。彼女は、Digi-Key奨学金プログラムを通じて、ノースランドコミュニティ&テクニカルカレッジのエレクトロニクステクノロジ&自動化システムで応用科学の準学士号を取得しました。彼女の現在の役割は、独自の技術プロジェクトを作成し、プロセスを文書化し、最終的にはプロジェクトのビデオメディアカバレッジの制作に参加することです。アシュリーの余暇には、好きなことと言えば - ああ、待って、お母さんにとって暇な時があるでしょうか?


Digi-Key Electronics

ミネソタ州シーフリバーフォールズに拠点を置くDigi-Key Electronicsは、試作および設計段階、量産段階のいずれにおいても、電子部品を卓越したサービスとともにグローバルに提供し、Digi-Keyでは、750社以上の一流メーカーから提供される600万点以上の製品を取り扱っている。