How do Common Mode Chokes Work?
In normal or differential mode (single choke), current travels on one line in one direction from the source to the load, and in the opposite direction on the return line that completes the circuit. In common mode, the noise current travels on both lines in the same direction
In common mode, the current in a group of lines travels in the same direction so the combined magnetic flux adds to create an opposing field to block the noise, as illustrated by the red and green arrows in the toroid core shown in Figure 1. In differential mode, the current travels in opposite directions and the flux subtracts or cancels out so that the field does not oppose the normal mode signal.
How do I Choose a Common Mode Choke?
The main criteria for selecting a common mode choke are:
- Required impedance: How much attenuation of noise is needed?
- Required frequency range: Over what frequency bandwidth is the noise?
- Required current-handling: How much differential mode current must it handle?
What Types of Common Mode Chokes does Coilcraft Manufacture?
Coilcraft designs and manufactures a variety of common mode chokes for many applications. Choose a category below or use one of our tools to find the right common mode choke for your application.
High-Speed and Super-Speed Data Line EMI Chokes
Coilcraft USB, RA6870, and CM1394 high-speed and Super-Speed data line common mode chokes effectively reduce common mode noise in high-speed interfaces like USB 2.0, USB 3.1 Gen 1, HDMI, IEEE 1394, LVDS, HDBaseTTM, MOST® bus, etc. They maintain excellent signal integrity for high-speed communications with -3 dB differential mode cutoff frequencies up to 6.5 GHz. Most provide greater than 30 dB common mode attenuation at 500 MHz and 25 dB in the GHz band.
Data Line Common Mode EMI Chokes
Coilcraft CJ5100, CQ7584, and CR7856 surface mount data line common mode chokes are designed to attenuate common mode noise up to 100 MHz. The PDLF Series can reduce noise by a factor of 32 from 15 MHz to 300 MHz and are available in 2, 3 and 4 line versions. The PTRF Series is optimized for FCC and ITU-T (formerly CCITT) requirements. These parts provide 15 to 25 dB attenuation, greater than 1000 Ohms impedance and 1500 V isolation between windings. M2022 can suppress common mode noise up to 500 MHz in a compact 1812 package.
Data/Power Line Common Mode EMI Chokes
Coilcraft LPD, MSD and PFD Families are low profile, miniature footprint common mode chokes that can be used to attenuate common mode noise or differential mode noise in both data and power line applications.
Surface Mount Power Line Common Mode EMI Chokes
Coilcraft low-cost, high performance surface mount power line common mode chokes come in a variety of sizes and packages. They are designed to eliminate AC line-conducted common mode noise across a broad range of frequencies, with up to 1500 Vrms isolation. These common mode chokes can operate over a wide range of current from 0.06 Amps to 15 Amps, providing attenuation where line filtering is needed, such as in switch-mode power supplies.
Through-Hole Power Line Common Mode EMI Chokes
Coilcraft low-cost through-hole BU Series high efficiency choke coils are designed to eliminate line conducted common mode noise across a broad range of frequencies. The BU9S and BU9HS are ideal for signal line applications; the other BUs can be used in switching power supplies and power supply circuits. For low profile applications, the BU9 and BU9S filters are available in a horizontal configuration that reduces their height to under half an inch (12.5 mm).
CMT Common Mode EMI Chokes
Coilcraft CMT toroid style common mode chokes are designed to provide the highest common mode impedance over the widest frequency range. These parts are ideal for any application requiring a high DC current bias and are well suited for use in switch-mode power supplies. These common mode chokes are most effective in filtering supply and return conductors with in-phase signals of equal amplitude. Differential mode inductors are available for filtering out-ofphase or uneven amplitude signals.
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