Hi,
This is my first attempt at this. A ham a few miles away has expressed an interest in linking with M3s. I think I already know it's not going to work at 11 miles given our elevation, but I do want to complete the exercise so I know how this works - and can start looking at the alternatives with nearby office buildings.
So here goes, in radio mobile, I established two sites, no problem, with elevation and position. On the link side I'm not sure how to input the data. For the M3 spec sheet located here: https://dl.ubnt.com/rocketm3_datasheet.pdf
We note that the TX gain is about 20 dbm or so at the "MCS 15" data rate. So, don't know how to move/translate those numbers to to tool where it's asking for Tx power (Watts), Tx antenna gain, and Rx antenna gain. Any help there? Also, what about Tx and Rx line loss, etc? Or maybe the numbers are all net for the unit?
Thanks,
Patrick KM5L
This is my first attempt at this. A ham a few miles away has expressed an interest in linking with M3s. I think I already know it's not going to work at 11 miles given our elevation, but I do want to complete the exercise so I know how this works - and can start looking at the alternatives with nearby office buildings.
So here goes, in radio mobile, I established two sites, no problem, with elevation and position. On the link side I'm not sure how to input the data. For the M3 spec sheet located here: https://dl.ubnt.com/rocketm3_datasheet.pdf
We note that the TX gain is about 20 dbm or so at the "MCS 15" data rate. So, don't know how to move/translate those numbers to to tool where it's asking for Tx power (Watts), Tx antenna gain, and Rx antenna gain. Any help there? Also, what about Tx and Rx line loss, etc? Or maybe the numbers are all net for the unit?
Thanks,
Patrick KM5L
| Tx power (Watts) | |
| Tx line loss (dB) | |
| Tx antenna gain (dBi) | |
| Rx antenna gain (dBi) | |
| Rx line loss (dB) | |
| Rx threshold (μV) | |
| Required reliability (%) |
line loss: I usually do 0.5dB loss for both Rx/Tx. These are ~6" cables (rocket) or internal to the device (Nanostation), so minimal loss and this is probably a conservative value.
Antenna gain: can be found on the specs. Note, There is a way to google around and find ubiquiti antenna data that can imported into radio mobile, for each specifiic antenna, then just select the antenna.
Rx threshold: 3.99uV = -95dBm is what I typically use, but adjust for the MCS rate you are modeling for. http://wa8lmf.net/miscinfo/dBm-to-Microvolts.pdf
Required reliability: I usually leave this default.
There's so many variables, that the coverage map gives a ballpark idea of what locations will work (significant to the rolling hills and mountain folks). But then one just has to try it to know what the local environment noise allows and rates can be achieved.
Radio Mobile is not a perfect science and people use it in various ways. This is how I use it.
I always model for MCS0 and then look to see what else I might get. Here are the parameters I use:
I use .25 watts Tx Power. While it's spec'd at .5 watts, that get's split between the vertical and horizontal domains; I use .5 dB loss in both Rx and Tx paths lines due to the coax jumpers; and I use 4 μV receive threshold because that's approximately equivalent to the MCS0 sensitivity of -94 dB. You didn't specify the antennas you plan to use... and the 26 dB Rocket Dish or 18 dB sector antenna are candidates. Those values get plugged into their respective fields.
When Radio Mobile comes back with its link analysis, it will calculate a Fade Margin. From, my personal experience (and the values I've used, above), I know I need about 15 dB of margin for a basic connection. Anything above will only increase the MCS rate for me. For example. I see that MCS15 requires 19 dB more received signal (94-75); I also see that the Rocket transmit power is 5 dB lower at that same rate... so I need a total of 24 dB (19+5) more fade margin... 39 dB in total (24+15) to achieve that data rate.
39 dB of Fade Margin is a lot, and I don't often achieve that (or MCS15 for that matter) on a link.
I hope this helps as a start. Your own experiences will likely change the way you use Radio Mobile. I started by modeling and then going out and seeing what results I got on the modeled links. Eventually I established this baseline and it's worked out pretty well for me. I have found that the UBNT airLink tool to be less than helpful.
Andre, K6AH
If you telnet into the node, the following command will indicate the MCS rate the device is running:
Here's an example of a node I have in my backyard pointing to a regional AREDN backbone node around 26 miles away, The Node Status screen indicates -73 / -95 / 22 dB S/N/R.
type rate throughput ewma prob this prob retry this succ/attempt success attempts
HT20/LGI MCS0 5.6 100.0 100.0 1 0( 0) 1 1
HT20/LGI MCS1 10.5 100.0 100.0 4 0( 0) 4 4
HT20/LGI MCS2 14.8 100.0 100.0 5 0( 0) 93 93
HT20/LGI MCS3 18.6 97.7 100.0 5 0( 0) 1380 1416
HT20/LGI tP MCS4 25.1 99.9 100.0 5 0( 0) 31688 33264
HT20/LGI MCS5 8.6 25.8 100.0 0 0( 0) 175 3495
HT20/LGI MCS6 0.0 0.0 0.0 0 0( 0) 1 3495
HT20/LGI MCS7 0.0 0.0 0.0 0 0( 0) 0 3495
HT20/LGI MCS8 10.5 100.0 100.0 0 0( 0) 1 1
HT20/LGI MCS9 18.6 99.9 100.0 5 0( 0) 368 380
HT20/LGI MCS10 25.1 99.9 100.0 5 0( 0) 37921 38776
HT20/LGI T MCS11 30.3 99.9 100.0 5 0( 0) 439091 448760
HT20/LGI MCS12 14.1 33.2 100.0 6 0( 0) 4482 8447
HT20/LGI MCS13 0.0 0.0 0.0 0 0( 0) 0 3495
HT20/LGI MCS14 0.0 0.0 0.0 0 0( 0) 0 3496
HT20/LGI MCS15 0.0 0.0 0.0 0 0( 0) 0 3495
The "T" in the 10th character position indicates the current MCS rate, and a "t" indicates the current fallback rate. In this case the link is running MCS11 at 30.3 Mbps.
Note that the command returns this chart for each of its connections.
Andre, K6AH
Thanks to you both.
Patrick
With apologies to Joyce Kilmer
Strictly-speaking it is not all attenuation - some of it is forward-scattering that messes up the coherence of wave fronts so that they do not add up properly at the receiver. So it looks like attenuation, but does not behave exactly like an attenuator. One big tree can have more attenuation than you expect; a forest can have less attenuation that you might calculate. Leaves and twigs that are 1/2 wavelength long have the biggest impact.
The problem with RadioMobile is that it really underestimates the effect of passing through trees, or tree tops. It also does not know what your path really looks like in terms of ground cover and obstacles. It is probably the wrong tool for propagation through trees, but you can try to increase the "density" number in Options/Elevation data to match your field test results. First look at the point-to-point path (tools/radio link - view profile) and see what objects the land cover file thinks are in the path (you might be surprised). Then adjust the height and density of those objects (options/elevation data). The highest density I think you can use is 1000%. Someone in the RadioMobile user group tried to make trees match the actual measured 3 GHz results and needed a density number > 1000%. So that may not be the answer.
There is a hidden feature to use an alternative attenuation model in RadioMobile. You need to edit the "landheight.dat" file. For example:
The first set of numbers comes from the GUI. The last one is a line *you* add, saying to use model #2 with parameters 0.2/0.5/0.8 (in this example).
This is the CCIR 236-2 model (Google is your friend).The parameters are k, x and y, respectively.
If you add this line, the numbers will appear in the GUI as shown in the attached JPG.
Note: this model then applies to ALL the objects in the land cover file, not just trees.
I would like to calibrate this model against field measurements of attenuation due to ground clutter (aka trees) versus height, but nobody has given me a quad copter yet ;-)
With the numbers shown (and not based on anything in particular) I see results that seem to me a lot closer to reality; i.e., only very short paths work in leafy areas.
This becomes very important when entering the height above ground for nodes. If canopy is at 30ft and you enter 50ft you could be telling Radio
Mobile your node is 80ft Above Ground Level.
The elevation data itself was not seriously affected by tree canopy
"... the SRTM elevations for evergreen forests are, on average, nearly 2 meters above the ground surface elevations. Interestingly, the bias for deciduous forests is much lower at less than one-half meter. A partial explanation for this observation may be that SRTM data were collected in February, which represents leaf-off conditions for deciduous forests in the conterminous United States, and more of the radar signals probably penetrated the relatively open canopy and reflected from the ground surface."
In the PC version of RM the antenna height is clearly intended to be the height above ground (attached image)
and where the ground level is, I think, is shown rather unambiguously (attached image - yellow line).
I'v got a repeater site where IIRC ground level is actually 30foot (+/- .5m GPS accuracy) below SRTM data.
Mind you this is California we don't necessarily have seasons on our trees even for deciduous trees but your right I had forgotten about that factoid that many areas may have been "leafless" and may not be as serious as I've experienced.
"ground truth" studies have shown that SRTM 30-meter data can be off 9 meters in absolute elevation level, or 7 meters in relative elevation (so-called 90% errors).
It's just not due to trees.
Like anything with a computer, you have to do some reality check on your data.
http://www.igc.usp.br/pessoais/guano/downloads/SRTM-program-final-versio...
Agreed: airLink is nice in some ways. Although reported signals are hopelessly optimistic, unless you have mountaintop-to-mountaintop topology. You can lower your link right into a forest and airLink will say everything is fine. But as long as you understand that, it is useful.
Another one I like is "heywhatsthat.com" You have to imagine the tree layer, but I like the way it interfaces with the googlemap/googleearth tools. Google has taken to making 3-D maps of more populated areas and they even show individual large buildings. Another nice feature is that you can click on a spot on the profile and it will take you right to the map and show you what is there. You can save the URL they give you and recall it later quickly.
The original use of it is to identify mountain peaks you can see from any given location - useful in areas that actually *have* mountains ;-)
It is fundamental that 0.6 Fresnel clearance MUST clear tree tops. Not as black and white at 900 Mhz, but nearly so with 900 being slightly more forgiving. This clearance is a must for 2.4 GHz and up. I have made 100s of microwave paths. Ham radio can cut a lot of corners versus any equivalent commercial system design for lower frequencies and modes, but not when it comes to 2.4 GHz and above. Unless, you are ok with the frustration and links that work some of the year.
If there is a rise or a ridge in the terrain shown on the path profile that is within 20 meters (per airLink) of 0.6 Fresnel in the path, drive to the area and make a physical survey. APRS is very helpful in locating yourself with the areas of interest. Also, the Boy Scout Handbook taught us how to estimate tree heights ... although I never understood why they needed to know. There might be building. It might be a bare ridge and not a problem. Or, as I found once in PA, an enormous coal mine slag pile in the way that the field survey did not initially recognize!
I think airLink is a fantastic tool with instant results, but some help from the real world is necessary.
-Jeff W9NIZ
I put a web cam with a 20x zoom lens on the tower and it is my favorite "propagation tool". Visibility around here is variable, having the camera permanently up there, gives me a chance to pick a day when the "seeing" is good and snap some photo's. The camera displays the heading to a fraction of a degree so I can plot the sight line on Google maps.
In the attached photo, the buildings just beyond the airport are 13 miles and the faint ones in the background are about 23 miles. Time-of-day (sun angle) makes a lot of difference in what you can see. But the farthest I have seen is about 30 miles. This is not Montana.
We're putting in equipment on lab-campus at JPL in Pasadena this Saturday. Here's a validation of line of sight pic. That's Pasadena with the building cluster as near as we can tell (if I'm pointing the right direction) from Pleasants Pk. This is about 40 miles through LA smog to Pasadena, the campus is 42 miles. I found a rare day where I could see this far. I'm waiting for the perfect day to take pics and see how far away it's possible to see.
Joe AE6XE
Nice smog. Nice mountains too.
The camera is a Canon VB-M40 which I think is obsolete now. But there is a 41/42/43 as well.
As Johnny Carson used to say, "I don't trust any air I can't see!" :-)
what at camera are you using? I am looking for a couple to put on my main repeater site in Redlands both for security and line of site. If I find something of good quality and price I will also be placing them at a local hospital as well as up at CSUSB.
Keith
http://www.aliexpress.com/item/7-Inch-2MP-High-Speed-Dome-PTZ-IP-Camera-...
We love the optics. Just snapped these pics from video over 30+ miles RF to Pleasants PK. Looking over LA sun down, see white dot on right side. This is LA Doppler radar site. See zoom in at low light, can count the hikers on weekends.
Joe AE6XE