I ran into some rather odd performance problems on one of my Ku dishes recently and decided to measure the CNR differences for several LNB and feed combinations. I thought this might be of some passing morbid interest to folks here as it shows rather significant unit-to-unit variations on a LNB that is generally well regarded.
Until recently my top performing Ku-band dish was generally a GeosatPRO 1.2m offset with an Invacom QPH-031 LNBF (quad linear/cicular). I also had a Fortec 1.8m prime-focus with a Frankenstein dual-ortho feed where I changed out the Ku section for a Invacom QTF-031 LNB (quad universal) on a custom adapter. Ideally a 1.8m dish should deliver about a 3.5 dB CNR improvement over a 1.2m, but I never saw this in practice. Long ago I did some quick-and-dirty comparisons with a prime-focus Ku feed (Invacom's ADF-120) on the QTF-031 and concluded there were a couple of reasons for the less than ideal gain improvement: (1) the Fortec is a rather flimsy dish and is not a great fit to a perfect paraboloid and (2) the Ku beam patterns for dual orthos are rather sloppy, probably because the feed provides no effective scalar at these frequencies.
Last spring I put a 1.8m Prodelin offset on a Ajak HH180 motor for exclusive Ku reception. I picked up a second QTF-031 LNB and machined an adapter for the rather impressive feed off the BUC/LNB package that came with the dish. I later added a second sidecar LNBF rotated to match 103W's oddball skew. I've been very happy with the performance of this dish, particularly with very weak or out-of-footprint feeds. However recently I noticed the Prodelin was only beating my 1.2m by about 1.5 - 2.0 dB at the center of the vertical band. Time for some fun on the roof!
I decided to take advantage of Dish's transponders on 85W as they are easy to lock and measure CNRs for both polarizations. I just wish they would cover the whole Ku band
I peaked both the Prodelin and 1.2m dishes on that bird and started rattling off CNRs. On first blush both polarizations averaged around a 3.25 dB CNR improvement for the Prodelin. The horizontal difference was fairly flat across the transponders, but the vertical difference was all over the map, ranging from about 1.5 to 4.5 dB of improvement. The worst performance was mid-band, exactly where I suspected.
I rotated the Prodelin feed by 90 degrees to see whether this was a dish artifact; it wasn't as the differences flipped. I then swapped the cables on the LNB - there was no change. That pretty much limited the suspects to the LNB or feed. I needed another LNB with a C120 flange and pulled out a spare Superdish FSS bandstacked device. As I have reported in previous threads, this performs very well for the ridiculously low prices they sell for on eBay. I swapped out LNBs on the Prodelin and ran another comparison against the 1.2m. This was startlingly better on the vertical side, averaging about a 4.0 dB CNR improvement for the Prodelin and having a much flatter profile.
It was tempting to leave the bandstacked LNB in place because of its outstanding performance. However I occasionally find some feeds on Atlantic birds well below 11.7 GHz and I really wanted to keep a universal LNB on the Prodelin. So off came the universal LNB on the Fortec and onto the Prodelin. Again I compared against the 1.2m. Overall this LNB measured just a hair worse than the bandstacked, but much better than the universal LNB that I had replaced. The first graph attachment shows the CNR variations between the two dishes as a function of frequency and by LNB on the 1.8m. Invacom 1 was the LNB originally from the Fortec and Invacom 2 is the crummy unit I had on the Prodelin.
The 1.2m and its LNB was the control, and its frequency response is superimposed on the 1.8m responses. One can probably make a pretty good estimate of the 1.2m response by averaging the curves for the different 1.8m LNBs. One can also readily see the droop in the Invacom 2 vertical response at mid-band. To factor out the 1.2m response, I then differenced CNRs for the Invacom 1 and Bandstacked LNBs against Invacom 2 for the second chart. The improvements in CNR at mid-band are very apparent here.
Invacom provides individual test curves for each LNB and of course they look just fine. Maybe I'll examine them a little closer some other time as Invacom only provides gain vs. frequency and NF vs. frequency. Perhaps when translated to CNRs this will explain the variations, but I rather doubt it. As a final twist I was curious as to how well the giant Ku feed that came with the Prodelin actually performs. I did not make a careful comparison, but I wedged a fairly decent Ku LNBF in its place on the Prodelin and again compared the performance against the 1.2m. Pretty much across the band the LNBF showed a 0.5 dB loss in CNR, confirming the original feed is probably the way to go.
I'm kind of happy this has been sorted out, but I'm not that happy to see such a variation in CNR. I don't really care much about LNB gain variation across the band, but CNR is another matter. A 1.5 dB unit-to-unit CNR variation means the 1.8m dish was acting like a 1.5m dish mid-band for the vertical polarization. While this has been fixed, I am curious about how my other LNBs perform.
Until recently my top performing Ku-band dish was generally a GeosatPRO 1.2m offset with an Invacom QPH-031 LNBF (quad linear/cicular). I also had a Fortec 1.8m prime-focus with a Frankenstein dual-ortho feed where I changed out the Ku section for a Invacom QTF-031 LNB (quad universal) on a custom adapter. Ideally a 1.8m dish should deliver about a 3.5 dB CNR improvement over a 1.2m, but I never saw this in practice. Long ago I did some quick-and-dirty comparisons with a prime-focus Ku feed (Invacom's ADF-120) on the QTF-031 and concluded there were a couple of reasons for the less than ideal gain improvement: (1) the Fortec is a rather flimsy dish and is not a great fit to a perfect paraboloid and (2) the Ku beam patterns for dual orthos are rather sloppy, probably because the feed provides no effective scalar at these frequencies.
Last spring I put a 1.8m Prodelin offset on a Ajak HH180 motor for exclusive Ku reception. I picked up a second QTF-031 LNB and machined an adapter for the rather impressive feed off the BUC/LNB package that came with the dish. I later added a second sidecar LNBF rotated to match 103W's oddball skew. I've been very happy with the performance of this dish, particularly with very weak or out-of-footprint feeds. However recently I noticed the Prodelin was only beating my 1.2m by about 1.5 - 2.0 dB at the center of the vertical band. Time for some fun on the roof!
I decided to take advantage of Dish's transponders on 85W as they are easy to lock and measure CNRs for both polarizations. I just wish they would cover the whole Ku band
I peaked both the Prodelin and 1.2m dishes on that bird and started rattling off CNRs. On first blush both polarizations averaged around a 3.25 dB CNR improvement for the Prodelin. The horizontal difference was fairly flat across the transponders, but the vertical difference was all over the map, ranging from about 1.5 to 4.5 dB of improvement. The worst performance was mid-band, exactly where I suspected. I rotated the Prodelin feed by 90 degrees to see whether this was a dish artifact; it wasn't as the differences flipped. I then swapped the cables on the LNB - there was no change. That pretty much limited the suspects to the LNB or feed. I needed another LNB with a C120 flange and pulled out a spare Superdish FSS bandstacked device. As I have reported in previous threads, this performs very well for the ridiculously low prices they sell for on eBay. I swapped out LNBs on the Prodelin and ran another comparison against the 1.2m. This was startlingly better on the vertical side, averaging about a 4.0 dB CNR improvement for the Prodelin and having a much flatter profile.
It was tempting to leave the bandstacked LNB in place because of its outstanding performance. However I occasionally find some feeds on Atlantic birds well below 11.7 GHz and I really wanted to keep a universal LNB on the Prodelin. So off came the universal LNB on the Fortec and onto the Prodelin. Again I compared against the 1.2m. Overall this LNB measured just a hair worse than the bandstacked, but much better than the universal LNB that I had replaced. The first graph attachment shows the CNR variations between the two dishes as a function of frequency and by LNB on the 1.8m. Invacom 1 was the LNB originally from the Fortec and Invacom 2 is the crummy unit I had on the Prodelin.
The 1.2m and its LNB was the control, and its frequency response is superimposed on the 1.8m responses. One can probably make a pretty good estimate of the 1.2m response by averaging the curves for the different 1.8m LNBs. One can also readily see the droop in the Invacom 2 vertical response at mid-band. To factor out the 1.2m response, I then differenced CNRs for the Invacom 1 and Bandstacked LNBs against Invacom 2 for the second chart. The improvements in CNR at mid-band are very apparent here.
Invacom provides individual test curves for each LNB and of course they look just fine. Maybe I'll examine them a little closer some other time as Invacom only provides gain vs. frequency and NF vs. frequency. Perhaps when translated to CNRs this will explain the variations, but I rather doubt it. As a final twist I was curious as to how well the giant Ku feed that came with the Prodelin actually performs. I did not make a careful comparison, but I wedged a fairly decent Ku LNBF in its place on the Prodelin and again compared the performance against the 1.2m. Pretty much across the band the LNBF showed a 0.5 dB loss in CNR, confirming the original feed is probably the way to go.
I'm kind of happy this has been sorted out, but I'm not that happy to see such a variation in CNR. I don't really care much about LNB gain variation across the band, but CNR is another matter. A 1.5 dB unit-to-unit CNR variation means the 1.8m dish was acting like a 1.5m dish mid-band for the vertical polarization. While this has been fixed, I am curious about how my other LNBs perform.
