I used to work at Maxim, but my dealings with those RF guys dealt more with coffee and the quality thereof.
I looked at the Maxim chip. The filter is relatively steep but not complex. Looks like two or three poles maximum. I don't know specifically about that chip, but that group had SiGe technology, so I'm leaning towards variable transconductance to do the tuning. You quickly learn just how bad google is at doing a search for this technology. The buzz phrase you need is continuous time, so I suggest "variable continuous time baseband filter". Sadly OTA gets links to "over the air." (And yet, they claim artificial intelligence will take over the world.) The thing to note in any highly integrated analog chip is that you don't see the sausage being made. Once you have a system on a chip, the metric is the system performance, not the performance per se of any individual block. So those filters may not be as great as you think. Note the Maxim part shows a tempco on the corner frequency, which could imply variable transconductance. One you have bipolar elements in the process, variable transconductance is just a matter of tail current. (SCF performance was relatively temperature independent.) Getting back to seeing the sausage, take the old analog modem market. Initially the SCF tech was used to make the official Bell 212 filters. Once the modem was fully integrated, the on-board filters were simplified for a number of really good engineering reasons, not just cost. One was the harmonic distortion of the band split filters. The harmonics of the in-band signal were far greater than the out-band signal that you were trying to reduce. Getting back to these baseband filters, if you use a ladder design, the filter is relatively immune to component error, well as opposed (contrasted) to a chain of biquads. If you go full differential, the variable transconductance amp are reasonably linear. But probably they limit the number of poles for the same harmonic distortion problem. Filters should subtract, not add. Most of the transconductance based filter designs probably are derivatives of integrated video filters. Plenty of papers online for those designs. If your goal is to roll together your own filter, TI has app notes on how to make analog tracking filters. On Sun, 20 May 2018 21:19:47 -0400 "Marcus D. Leech" <[email protected]> wrote: > On 05/20/2018 09:13 PM, [email protected] wrote: > > > > Can you be more specific about the corner frequency? > Corner frequencies step-tunable from perhaps 20Mhz down to perhaps > 2MHz. > > Many chips, like the R820T2, the MAX2112, and the higher-integration > devices like the AD9361 and LMS7002M have > programmable analog low-pass corner frequencies, for bandwidth > tailoring of the complex baseband. > > Just not sure how its done. The chips have very low external parts > count, so whatever it is, it's got to be done > internally... > > > > > > Cell phones use chips that have switchable banks of capacitors for > > antenna tuning. st.com IIRC is a source. > > > > I used to design switched capacitor filter chips in the 80/90s. The > > technology was killed by oversampled converters and DSP. The SCF > > players went into continuous time video filters using > > transconductance amps and such. > > > > > > _______________________________________________ > > Discuss-gnuradio mailing list > > [email protected] > > https://lists.gnu.org/mailman/listinfo/discuss-gnuradio > > > _______________________________________________ > Discuss-gnuradio mailing list > [email protected] > https://lists.gnu.org/mailman/listinfo/discuss-gnuradio _______________________________________________ Discuss-gnuradio mailing list [email protected] https://lists.gnu.org/mailman/listinfo/discuss-gnuradio
