Electronic devices power our world and allow us to communicate. In all applications requiring signal integrity and accurate power amplification, blocking capacitors are used to provide clean waveforms and correctly amplified voltages.
Generally, waveform systems can be broadly defined into power-related alternating current (AC) and communications-related radio frequency (RF) applications. Both employ waveforms to provide power or information. All of these devices require a blocking capacitor to ensure the waveform conforms to the desired specifications. Some standard electronic devices requiring blocking capacitors are:
In AC and RF waveforms, the desire is to have the waveform highs and lows navigate around a known base voltage. Typically, this is designed to be a waveform centered around zero volts. Some designs, like audio amplifiers, require the waveform to circulate a known direct current (DC) voltage.
However, this desire to achieve a known center level can be thwarted by the unwanted injection of a DC voltage onto the line. Some sources of DC pollution may include the following:
When any of these sources are added to (or subtracted from) the desired waveform, the center voltage is shifted into a range that corrupts or prevents data processing in RF applications or alters power amplification into unusable or dangerous ranges.
A capacitor is a passive electronic device comprised of two plates separated by a dielectric. When power is applied, the plates accumulate their respective positive and negative charge until the capacitor reaches equilibrium with the supplied voltage. See Figure 1.
Figure 1. Capacitor physical diagram. Source.
In the case of blocking capacitors, this device is placed in series with the load. Blocking an unwanted DC voltage occurs because the capacitor acts as an open to the DC voltage, not allowing it to pass through the dielectric. In Figure 2 below, capacitor C2 acts as a blocking capacitor in this voltage divider design with the output waveform around zero volts.
Any waveform on the line produces electromagnetic waves that transit the dielectric in inverse polarity to the originating wave. Thus, the DC voltage is blocked, and the wave, with a properly valued capacitor, circulates about zero volts, as desired.
Figure 2. Voltage divider with blocking capacitor C2. Source.
In the communication world, RF signals can be transmitted over lines that require blocking capacitors to ensure the correct level is transmitted or received. For example, in coaxial lines with an inner core and outer sheath, the capacitor can be applied as an inner DC block or an outer DC block, or a capacitor can be applied as both an inner and outer DC block.
To better understand how a capacitor acts in a DC-blocking (otherwise known as AC-coupling) application, and how to select the correct blocking capacitor, let’s think about the behavior of an RC high pass filter. In Figure 3a, you can see the RC high pass filter consists of a capacitor in series and a resistor in parallel. To find the 3dB frequency cutoff of this filter, you can use the formula in Figure 3b. When we plot the power that gets through this filter on a Bode plot (Figure 3c) we can see that the frequency has dropped by -3dB at the frequency cutoff we get in the formula and it drops off further at frequencies lower than the frequency cutoff, showing us how different capacitance values can attenuate low frequencies.
Figure 3. An example of a passive RC high pass filter.
In practice, the above formula assumes ideal conditions. Real-world manufacturing processes introduce parasitic inductance that moves the equation to an approximation. But using this we can get a sense of the capacitance value required to pass frequencies we are interested in and to block frequencies we do not want. Any capacitance can block DC, but a designer should consider the minimum frequency they want to pass when selecting a capacitor value.
Finding blocking capacitor solutions for complex real-world electronic systems requires a deep understanding of current flows. Figure 4 below shows a blocking capacitor system added to each side of a DC-DC step-down converter used in an electronic vehicle charging device. Our engineering team uses sophisticated modeling tools to arrive at this solution, ensuring quality fast-charging levels.
Figure 4. DC-DC converter bypass capacitor configuration Source.
Our multilayer ceramic capacitors (MLCCs) offer various DC-blocking solutions that can be tailored to your design needs. We provide surface mount packages with very low equivalent series resistance (ESR) and equivalent series inductance (ESL). Our rigorous testing process ensures products that meet various regulatory specifications, such as the requirements of AEC-Q200, and our engineers can assist you with finding the right capacitor for your application.
Whether you’re designing for communications with frequencies from hertz to gigahertz, power and signal amplification systems, or ultra-sensitive sensors, we can provide MLCCs that remove unwanted DC levels from your design. Our engineers can also assist you in designing the optimum solution when you encounter complex challenges that a catalog component won’t work for.
Learn more about using our AEC-Q200-certified capacitors for critical DC-blocking capacitor roles including C0G and X7R options as well as our StackiCap range. Or, read this blog post to see other ways our parts are used in DC-blocking applications.