Search is your friend. Foghorn had a good post about using the LC-1 with the powertuner.
Here are my notes on the matter that I copied from his post.

The formula 'out of the box' for an LC-1 with stock parameters is;

(N0/51) * 3.008 + 7.35

Where does 3.008 come from? Simple, it's an expression of the range. Stock the LC-1 provides for an AFR range of 7.35 to 22.39 over a voltage range of 5 v, so.. (22.39-7.35)/5=3.008.

If, as you must, check for voltage offsets then you may have to change the values. The LC-1 can be programmed to output a specific Voltage which you can then measure with a voltmeter. In my case I had only 4.9 volts as opposed to 5 so this leaves me with (22.39-7.35)/4.9=3.069

Where does the 7.35 come from? Simple, at 0 volts the AFR would be 7.35. In the case where the AFR is richer (lower numerically), the LC-1 in stock form will not read lower, but in all cases the minimum AFR value must be added to formula to show the correct value.

If you can adjust the sampling rate of the O2 sensor then I would suggest you make it as slow as possible. The LC-1 is capable of 'infinite' sampling rates but typically can be 300 samples per second or more. At that rate it's capable of reading variances from cylinder to cylinder and in fact the guage would be constantly changing. If you can slow it to 1/3 rd of a second or thereabouts that's what I would suggest.

I have simultaneously run the PT with the LC-1 connected while I also ran the Innovate Logworks program just to compare the results. Why would I do that? Because the serial output from the LC-1 does not suffer from any ground offsets, meaning what you see is what you get in the Logworks so you can compare to the 'adjusted' value displayed in the PT.

I can tell you, and Jerry has seen it too, that there can be a substantial difference between the PT and Logworks, up to 0.6 AFR or more in some cases. There are a couple of things you can do to correct that, both include manipulating the formula used in the PT.

The first method is to compensate differently in the formula for the ground offset. Some suggest measuring the maximum voltage output of the LC-1 (free air or AFR22.39), in my case it was 4.9V, then adjusting the formula like so;

((N0/51)+0.1) * 3.008 + 7.35

I don't like this method because the ground offset is only compensated for perfectly at very lean conditions. Alternatively you can just program the LC-1 to output 2.5V, which is the middle of the scale and equal to 14.7 AFR, and then read the voltage on the analog output and then use that value in the example above.

The second method, and the one I prefer, is to manually manipulate the formula range value in order to a result that closely matches the readout in Logworks. This can best be done with a co-pilot and a lot of trail and error.

In my case, from memory, I think I ended up with;

(N0/51) * 3.039 + 7.35

I found this method to be most acurate over the range that interested me most, 9.5 to 15 AFR.