Early on Jon did some great testing of the SM v2 mainly by wave form comparisons on his DAW. And in the early days the SM v1 operation was documented by quadscope demonstrations. Except for Involve I don't think anyone on the forum has run a numbers game on the SM v2, that is separation crosstalk.
I finally was able to pull my SM v2 out of my system for a bit (that was hard. I listen to it every day) to do some testing. I just wanted to satisfy my own curiosity & see if I could learn anything about how better set it up or optimize performance. As you see in the attached it was mainly about checking levels & separation for 8 different directions, QS, SQ, 4.0 & 5.1.
On my PC I made eight test signals corresponding to corner & center positions. I used a 1kHz sine wave that fitted in pretty nicely to the 300Hz>3kHz of the SM. I didn’t do any other frequencies as I had confidence what I tested here would be mirrored. The things that would make a difference would be attack/decay times & over all flatness through the audio spectrum because of the filters, & I couldn’t measure that.
My test signals were at 1V input to the SM. It makes it easier to figure voltage change to dB ratios. The input level clip light comes on about .548 V with the level set to max. Setting the input level to 12:00 with 1 V input put it just a bit below the max LED clip level. With the output level controls set straight up, it is unity gain. It is very close probably with in the tolerance of the individual pots. Now my Oppo has a max analog output level in the unbalanced mode of 2V. So if you plug a disc player like this into the SM you will definetly need to back off on the input level. For myself the Oppo plugs into a Chase RLC1 control unit before going to the SM so it's very easy to control the input level with out having to adjust the Oppo.
I started by sending corner signals to the unit & & adjusted output gain to read 1.0 V on my meter. After doing that I used a center front signal & in the 5.1 mode I adjusted center front out put to 1 V.
I went back to the 4.0 mode & repeated the QS corner signals & this time I measured the cross talk on the other chs. I repeated with center left, right, front, back. In the attachment I normalized everything relative to 1.0 V & just calculated the dB attenuation. For example a left front only (or right front only) might output 1.0V but measuring them with center front each ch drops down to .70 V. As it should be! I don’t think any vintage decoder could do this. I also noticed it on center left, right, & back.
https://www.dropbox.com/s/77psu5spg7mi7h2/INVOLVE QS.pdf?dl=0
I learned that the SM is very accurate & predictable & if I use test noise & an SPL meter to fine tune, I’m adjusting to account for speaker & room acoustics not the decoder.
About the only oddity I found in both the QS & SQ modes is that 5.1 center front does not have as hard a center front output as I expected. The front L/R outputs are only about 6dB down. I sent these test results to Chucky as I wanted validation that my testing method wasn't full of gaping holes. He rplied in part:
So the measurement was correct. Interestingly when I was using DPL II a lot I came to the same conclusion. Adjusting the width between hard center front & phantom center I chose in between where the center front was dominate but front L/R down by about 6dB.
I did some SQ test tones & checked that out but not with as many positions. Mainly I was curious about all the stuff regarding center front to back leakage in SQ. The front to back separation in SQ is not as high as QS but at about -16dB that’s still plenty good. I guess the only other way to reduce the leakage is to blend the rear output a bit & that reduces the rear ch width. Who wants to do that?
Over all I am just so delighted that the SM decodes that precise even after over a year of frequent use. I’d expect all analog to need to trim pot adjusting by now. And really with a clean digital source instead of LP & phono cartridge, with the Surround Master decoder and the encoder at the front end, this is better than we old quaddies could have ever dreamed of from 2 chs.
I finally was able to pull my SM v2 out of my system for a bit (that was hard. I listen to it every day) to do some testing. I just wanted to satisfy my own curiosity & see if I could learn anything about how better set it up or optimize performance. As you see in the attached it was mainly about checking levels & separation for 8 different directions, QS, SQ, 4.0 & 5.1.
On my PC I made eight test signals corresponding to corner & center positions. I used a 1kHz sine wave that fitted in pretty nicely to the 300Hz>3kHz of the SM. I didn’t do any other frequencies as I had confidence what I tested here would be mirrored. The things that would make a difference would be attack/decay times & over all flatness through the audio spectrum because of the filters, & I couldn’t measure that.
My test signals were at 1V input to the SM. It makes it easier to figure voltage change to dB ratios. The input level clip light comes on about .548 V with the level set to max. Setting the input level to 12:00 with 1 V input put it just a bit below the max LED clip level. With the output level controls set straight up, it is unity gain. It is very close probably with in the tolerance of the individual pots. Now my Oppo has a max analog output level in the unbalanced mode of 2V. So if you plug a disc player like this into the SM you will definetly need to back off on the input level. For myself the Oppo plugs into a Chase RLC1 control unit before going to the SM so it's very easy to control the input level with out having to adjust the Oppo.
I started by sending corner signals to the unit & & adjusted output gain to read 1.0 V on my meter. After doing that I used a center front signal & in the 5.1 mode I adjusted center front out put to 1 V.
I went back to the 4.0 mode & repeated the QS corner signals & this time I measured the cross talk on the other chs. I repeated with center left, right, front, back. In the attachment I normalized everything relative to 1.0 V & just calculated the dB attenuation. For example a left front only (or right front only) might output 1.0V but measuring them with center front each ch drops down to .70 V. As it should be! I don’t think any vintage decoder could do this. I also noticed it on center left, right, & back.
https://www.dropbox.com/s/77psu5spg7mi7h2/INVOLVE QS.pdf?dl=0
I learned that the SM is very accurate & predictable & if I use test noise & an SPL meter to fine tune, I’m adjusting to account for speaker & room acoustics not the decoder.
About the only oddity I found in both the QS & SQ modes is that 5.1 center front does not have as hard a center front output as I expected. The front L/R outputs are only about 6dB down. I sent these test results to Chucky as I wanted validation that my testing method wasn't full of gaping holes. He rplied in part:
So the measurement was correct. Interestingly when I was using DPL II a lot I came to the same conclusion. Adjusting the width between hard center front & phantom center I chose in between where the center front was dominate but front L/R down by about 6dB.
I did some SQ test tones & checked that out but not with as many positions. Mainly I was curious about all the stuff regarding center front to back leakage in SQ. The front to back separation in SQ is not as high as QS but at about -16dB that’s still plenty good. I guess the only other way to reduce the leakage is to blend the rear output a bit & that reduces the rear ch width. Who wants to do that?
Over all I am just so delighted that the SM decodes that precise even after over a year of frequent use. I’d expect all analog to need to trim pot adjusting by now. And really with a clean digital source instead of LP & phono cartridge, with the Surround Master decoder and the encoder at the front end, this is better than we old quaddies could have ever dreamed of from 2 chs.
