OPA4192: Output noise from , PSRR graph

Mukuno-san,

Kai has very nicely summarized the switcher noise problem and it is the issue that needs to be addressed in the application.

22 dB of PSRR at 1 MHz fundamental frequency provides only about 1/100th reduction of the noise amplitude. However, a switching waveform contains many higher frequency harmonics, and the op amp PSRR falls off further with each successive harmonic. After a few harmonics there is no PSRR remaining and the noise couples directly through the op amp output without any attenuation. 

Regards, Thomas

Precision Amplifiers Applications Engineering

Hi Yusuke,

the OPA4192 is much faster than the OPA4387 and it does not have the PSRR specified at frequencies above 1MHz. So we do not know whether both OPAmp suppress the ripple at frequencies above 1MHz equally good. Thomas already mentioned that the harmonics of the 1MHz ripple can be the issue here.

For a better understanding we would need to see a scope plot of the ripple and analyze whether there are far reaching harmonics. If this is the case then the slower OPA4387 may better "seem" to suppress the supply voltage ripple.

But again, only because you see a lower supply voltage ripple at the output of OPA4387 doesn't mean that the supply voltage ripple is less harmful with the OPA4387. As I already told, the supply voltage must be clean, stable and noise-free. Supply voltage noise can cause many unwanted issues which can totally ruin the precision of a circuit. Why? Because at very high frequencies the ripple seen at the supply voltage pins is no longer treated linearily by the OPAmp but very unwanted things can happen, like demodulation of supply voltage ripple or intermodulation effects. Demodulation and intermodulation can generate low frequency artefacts like unwanted and unexplainable, slowly changing offset voltages. Believe me, you don't want to have this in a precision circuit.

So, as I already told, the issue here is not the OPAmp but the supply voltage ripple. If you see supply voltage ripple at the output of an OPAmp in a precision application, you urgently need to suppress the supply voltage ripple appearing at the supply voltage pins of OPAmp by the help of LRC low pass filtering, best by the help of Pi-filters which are mounted directly at the output of supply oltage source.

Changing the OPAmp will usually not cure the situation but only hide the impact of supply voltage ripple.

Kai

Mukuno-san,

Attempting to use the op amp PSRR is not the solution to this issue because of its limited effective frequency range, and the wide frequency content of the switcher noise. The solution needs to be external to the op amp used.

There are two external approaches that can be considered. One is adding an RF choke in series with each supply line to the op amp supply pins. The RF choke is added right at the op amp power supply pins. The choke in conjunction with the op amp power supply decoupling capacitor creates a second-order LC low-pass filter. The lower its cutoff frequency is made, the higher the attenuation of the power supply noise will be.

Alternately, low-noise three-terminal linear voltage regulators can be added to each supply pin. Three-terminal linear voltage regulators can exhibit high PSRR at higher frequencies than that of the op amp being used used. Linear voltage regulators do require a higher input voltage than the output voltage and must be selected for minimum drop out voltage characteristics in addition to best PSRR performance. The Linear Voltage Regulator e2e forum could help you with the best suited product for the application.

Regards, Thomas

Precision Amplifiers Applications Engineering

Mukuno-san,

Yes, PSRR.

Precision Amplifiers uses a large supply voltage change when production testing our op amp PSRR. Using a large voltage change is a more rigorous test than when a small voltage change is used. It is essentially a DC test and that is what the datasheet PSRR specification is based upon. 

Regards, Thomas

Precision Amplifiers Applications Engineering