Ferrite bead position

I'm researching information on decoupling capacitors and came across some information about ferrite beads from TI:

Ferrite beads are very handy tools to have in your circuit design arsenal. They are, however, not a good idea for all circuit power rails. Ferrite beads effectively absorb high frequency transients by raising their resistance at higher frequencies. This makes them very good at preventing power supply noise from getitng to sensitive circuit sections, however, it also makes them a very bad idea for main digital power.

When to use them:

Use them on power traces in series with analog circuit sections like composite video or PLLs. These beads effectively shut down power flow in times of high noise transients, allowing the power to be drawn only from the decoupling capacitors that are downstream. This cuts noise to sensitive circuit sections considerably.

How to use them:

Ferrite beads should be used in between two capacitors to ground. This forms a Pi filter and reduces the amount of noise to the supply considerably. In practice, the capacitor on the chip side should be placed as close to the chip supply ball as possible. The ferrite bead placement and input capacitor placement is not as crucial.

If there is not room for two capacitors to form a Pi filter, the next best thing is to delete the input capacitor. The chip side capacitor should always be there. This is very important. Otherwise the ferrite beads increased high frequency resistance may make things worse instead of better since there will be local power storage on the chip side, and therefore no way to get the high peak power pulses to the chip that it so desparately needs.

When not to use them:

The above ferrite traits are very handy for those circuit sections that draw power evenly and consistently, but the same traits make them unsuitable for digital power sections. Digital processors need high peak current, because most internal transistors that switch are switching on each clock edge, all the demand occurs at once. Ferrite beads (by definition) will not allow power to flow through them with the high ramp rates required by digital processor logic. This is what makes them perfect for noise filtering on analog (like PLL) supplies.

Since all the power demand in digital system is instant (high frequency), instead of being a slow and steady demand, ferrite beads will block the digital supply during the peaks. Theoretically, the bypass capacitors on the processor side of the bead would supply the peak current, filling in the gaps caused by the ferrites until they were charged after the peak was over, but in reality, the impedance of even the best capacitors is too high above about 200 MHz to supply enough peak power for the processor. In systems without ferrites, the planar capacitance can help to fill in this gap, but if a ferrite is used, it's inserted between the planes and the power pin, so the benefits of planar capacitance are lost. This will cause a big instantaneous voltage drop during the period the processor needs it most, causing logic errors and strange behavior if not immediate crashing. This can be avoided by proper design if required for your system (for EMI reduction, for example), however this is beyond the scope of this note.

I believe you should examine what your switching current spectrum looks like. If your digital circuits require large current transients, you should not use a ferrite bead on them.

I am currently of the mindset that the ferrite bead is useful in certain, very specific applications, but it is mostly used liberally as a band-aid when issues arise that should be solved by examining the power delivery network.

While it would be nice to see some graphs or other data, what I read here from TI sounds plausible. What do you guys think about it?


My board will include voltage doublers/inverters such as ADM660 and a microcontroller, which will generate two out-of-phase 5kHz 5V TTls to drive the EM mirror. When my headphones wire touches the board, I can hear the ringing in my headphones. So, I think such noises will affect other ADCs, DACs, OpAmps, CPLDs that are on the board. I thought putting a ferrite bead on each power supply line would do good. Also, what type of ferrite bead would work best for 10MHz square wave TTL?

I would urge you to read this document. Some of the salient points I have noted below: -

enter image description here

Summary - probably best not to use ferrite beads because they only really start to come into their own above 30 MHz.

Basically I think some of the problems you might be trying to solve are best left in the "inductor" arena whilst maybe the 10MHz sq wave (and more importantly its harmonics) may be dealt with by using ferrite beads.

However, my advise generally is - use ground planes followed by very good capacitor decoupling on all chip power supplies and if you can use small resistors feeding power to vulnerable places (maybe 1 ohm to 10 ohm). If this doesn't prove successful I would want to know why and possibly improve grounding and decoupling before inserting inductors and certainly before considering ferrite beads.


I disagree with Spehro -- the right image is much better, ie less resonant. The circuit on the left will see "antiresonance" -- At a certain frequency in the 100MHz range, the 10uF cap will start to look like an inductor, while the .1uF capacitor will still look like a capacitor, making the pair of them behave like an LC tank circuit. Around that frequency, this tank circuit will not sink or source any current, but rather just swish it back and forth like so much mouthwash, and so the two caps together will have very high impedance, making them lousy for decoupling.

As a very broad rule of thumb, it is a bad idea to have two ceramic caps on the same rail that are widely different in capacitance, without some other in-between values on there too. (For example, you can put a .1uF, and .68uF, 2.2uF, and 10uF all on the same rail, but if you just have .1uF and 10uF you might have problems.)

The figure on the right has a ferrite between the mismatched capacitors, dampening the LC tank circuit with a resistance (because ferrites are resistive above 100MHz, not inductive) and this prevents the caps from interfering with each other.

Another solution would be to use a tantalum or electrolytic cap for the 10uF, because its built-in ESR resistance would dampen the tank circuit too (but such a cap would be useless for filtering high frequency noise).

I am getting all of this from a really useful application note by Murata.

Lots of nifty combinations of ferrites, inductors and caps used for decoupling can be found there.