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TLC2252: Noise Issues on the Output

JP
Expert 3491 points
Part Number: TLC2252
Other Parts Discussed in Thread: OPA320

Hello Team,

I am currently evaluating the TLC2252, and ran into some noise issues on the output. 

To provide a little background on the design, the op amp will be used as a Sallen Key Low Pass Filter, with an input signal that is a 25kHz square wave that goes from 0V to 5V. Also, the TLC has a single 5V supply. Below is the setup of the LPF: 

When R1, and R2 are set to 15.8kΩ,  the cutoff frequency is around 215Hz and the output is  centered at 2.5V as expected. (Simulation shown below)

When R1, and R2 are set to 3.4kΩ, the cutoff frequency is around 1kHz and the output is generating a significant amount of noise as seen in the output below.

After reviewing the datasheet I am not sure what is causing the noise levels to increase when the cutoff is changed to 1kHz. It looks like we are operating within the common mode range, and I can't seem to identify where we went wrong here. Any ideas as to when could be causing this?

Best Regards, 

Javier Palomo

  • 0
    TI__Expert 5830 points

    Hello Javier,

    I will look into this for you.  

    Best,

    Errol Leon

    Texas Instruments 

    Precision Op Amp Applications

  • 0 in reply to Errol Leon6
    TI__Expert 3491 points

    Hello Errol,

    Thanks, and I attached the Tina model I forgot to include in the initial post. TLC2252.TSC

    Yeah, I am not sure what I am missing here but hopefully you can provide some clarity. Hope you have a great weekend!

    Best Regards,

    Javier Palomo

  • 0 in reply to JP
    TI__Guru 63700 points

    Javier,

    TLC2252 input common-mode voltage range is specified 1V below positive rail and not rail-to-rail, thus for 5V single supply operation you may only apply input signal from 0V to 4V.  Also, no linear op amp may swing on the output all the way to either rail - with unloaded output TLC2252 can only get within 20mV to positive and 10mV to negative rail.  

    All in all, the problem you see is caused by the non-linear operation of the input stage close to positive rail.

  • 0 in reply to Marek Lis
    TI__Expert 3491 points

    Hello Marek,

    Assuming we are able to increase the rail to 6V to allow for a input signal I am still curious as to why the output has low noise at 215Hz cutoff (15.8kOhm), and not at a 1kHz cutoff (3.4kOhm)?

    The actual input signal is not a 50% duty cycle square waveform, rather it is a 25kHz square wave with a duty cycle that varies dependent on a peripheral reading. The TLC2252 is used to track the DC component of the 25kHz square wave in a band from 0 to 215Hz, or optionally from 0 to 1kHz. 

    I am open to evaluating another op amp, however, would like to use the TLC2252 for this application. 

    Best Regards, 

    Javier Palomo

  • 0 in reply to JP
    TI__Mastermind 31355 points

    Hey Javier,

    It seems Errol is helping you and figuring out more details (load, sensor output singal, etc.) in order to optimize your part choice.

    I would note though that increasing your filter's cutoff frequency from 215Hz to 1kHz will reduce the filter's effectiveness in generating a DC voltage since you're passing through more frequency information. You can also view the method for converting a PWM signal to a DC level here with this:

    Peter Iliya

  • 0 in reply to JP
    TI__Mastermind 31355 points

    Hey Javier,

    I think I figured out the root of the problem here. The reason you see the "noise" you mentioned when the filter's fc is increased from 215Hz to 1kHz is the interaction of the RC network of R2 and C1 with the closed-loop output impedance (Zout) of the TLC2252.

    According to Figure 30 in the datasheet the closed-loop output impedance (Zout) is rising at 20dB/dec and thus Zout is acting like an inductor. Note the datasheet says “Zo”, but this plot is the closed-loop output impedance which I am referring to as Zout.

    This problem can be determined by perfectly isolating the Zout of the op amp from the feedback capacitor C1 using a voltage-controlled voltage source (VCVS) at a gain of 1 in TINA. The asymmetry is removed when you run the simulation.

    It is difficult to say where and what values of Zout are causing the overall asymmetry in your output because the sudden rising and falling of the square wave is causing the capacitors to momentarily short, but there are some simple solutions.

    According to Figure 30 TLC2252 has Zout = 20 Ohms at 25 kHz and if you simulate the closed-loop bandwidth of your circuit you see the gain comes back up around 25 kHz. Meaning those higher frequencies of the square wave during the rise and fall won’t be as attenuated as much. See the closed-loop bandwidth gain below.

    One solution is to add an RC filter externally to the output of the amp with R = 20 Ohms and fc = 25 kHz, thus C = 397.9 nF. This will attenuate down frequencies > 25 kHz that the amp is not as effective at attenuating. Additionally you’re matching the resistive Zout with the 20 Ohms. Of course you have to make sure this does not destabilize the overall filter. See solution and simulation below.

    Another option is to use an amplifier with a larger bandwidth. This will prevent the Zout from rising too early and thus begin loading down C1. You want to make sure that the amplifier’s open-loop output impedance Zo is purely resistive as this will help for stability. I chose the OPA320 (20MHz GBW) and simulated this below.

    Some other things to note are that the TLC2252 macromodel does not use the most up to date simulation modeling methods and some aspects could cause problems in your simulation. Either way you want to verify this is the real world. OPA320 will more accurately reflect the Zout and Zo characteristics in simulation. Although there are methods to verify Aol, Zout, and Zo in simulation compared to datasheet plots which I could help explain more if desired.

    Also note that you are stretching the amplifier inputs pretty significantly so you will want to make sure the input stage of the amplifier does not have back-to-back input diodes. You could run the signal through a simple RC low-pass filter before the amplifier to reduce the intensity. Or just replace the entire filter with multiple RC filters as seen in the PDF I attached previously in this thread.

    Best,

    Peter Iliya

    Precision Amplifiers Applications

  • 0 in reply to Peter Iliya
    TI__Expert 3491 points
    Hello Peter,

    This looks to be a correct assessment on what is causing some of the oscillations on the output.

    The engineer working on this was able to create their own AC model for the op amp with an output stage that generates a similar output to Figure 30 in the datasheet.

    Thank you for your help!

    Javier Palomo