Hi there..

Is your source by any chance a Buffalo containing a 100MHz clock ?

Thanks for the replies,
I don't have a buffalo. My source is an apogee rosetta 200 with a 20kohm stepped attenuator before the ventus ez.
I can't use a 10kohm input impedance (using 5kohm resistors as in schematic) with the attenuator I have.

My power supply is just a 7812, 7912 hooked up to a full bridge rectifier on a 60hz CT transformer, with capacitors.

I don't believe this to be a scope probe issue. I measured this signal on headphone output, after the 10uH inductor at about 4mv and with 32ohm headphones attached. The capacitance of the headphone cable should be more than the probe at this point. Measuring before the inductor, or with the headphones disconnected, I see an increase to 600mv - (-43db) what I expect with the LR filter response.
I can use a high speed active probe and see if I get different results.




What do you mean by no means ideal. What is not ideal, is the higher feedback resistor making this too unstable?

What do you mean by set up as a normal non-inverting amplifier? If I removed all filter capacitors, I would have a normal non-inverting amplifier, with a current buffer, and balanced to unbalanced converter.

Thanks,

Edited by user Tuesday, September 3, 2013 8:50:24 AM(UTC)  | Reason: Not specified

If you want to use it as BAL/SE converter you should try to keep the input impedance <= ~5K to get decent performance.

Also grounding the inputs will tell you if its truly an oscillation or an actual signal coming from the source (or via EMI).

If your case where you have a stepped attenuator, just increase the gain rather than worrying over the input impedance.

Edited by user Tuesday, September 3, 2013 1:25:50 PM(UTC)  | Reason: Not specified

Your attenuator has 20K output impedance? That is awfully high... Sounds like you may wish to use an instrumentation amplifier front end, or two buffers.

CC1 should be omitted in this configuration. It is an optional part used only if the buffer is omitted.

Looking at the Legato 3.1 (with buffer) schematics does this also applies to c5 / c6 ?

Sorry for 'jacking the threat.

I re-examined the board, with a <1pF Mohm probe on a very high speed scope. This time I saw the oscillation occurring between 600khz and 1.4mhz. It seemed to fluctuate with how I oriented the headphone cable. Shorting the input pins did not remove the oscillation. After removing cc1, it appears the oscillation has completely stopped.

It should actually be just fine either way. :) Try both ways and see which you like better.

I finally got the thing in my chassis, but now I have this annoying ~420hz squeal coming through any headphones. I'm having trouble locating it with a scope, it's not an obvious oscillation anymore. I'm using a star grounding approach. The only ground connection to each board is with one wire back to a single point, I am omitting the ground pins on the signal side of the board and using the ground via between V- and V+.
I can sometimes modulate the frequency by touching the opamp, and I can change the intensity by fiddling with additional grounding.
Any suggestions?
I'm concerned this may be an issue with the layout of ventus EZ. I'm considering cutting traces to give the recommended separate .1 uF and 10 uF for the opamp and buffer (as seen here http://www.ti.com/lit/ds/symlink/lme49600.pdf).

Thanks!

I have torn apart the thing trying to fix the issue, so I don't have a picture of how it was.

Here are two drawings of the ways I have tried that should have worked.





Note I have two headphone connectors (1/4" and 1/8") that are connected to chassis ground.

Both ways have the noise. Interestingly, the noise changes volume in certain ground configurations. In certain rare cases I can turn on the power and not have the noise, it seems the oscillation takes some excitement to start- switching power or toggling ground can do this.

The power supply looks basically like: http://www.paia.com/KRUKits/K83-5/k83-5_schem.jpg
I use the lm7812 tab to ground the chassis in grounding scheme 2.