Hi, Folks!
I'm in the process of setting up a second LNB on a 90cm dish, and thought that it would be worthwhile creating a thread that seeks to understand both the theory and practice behind adding additional LNBs to a dish. For folks that aren't familiar with this, the goal of doing so is to receive additional satellites with a single fixed dish. First of all, I'd like to express my thanks to "Anole" and "Smith, P" for getting me started on the theoretical aspects in this thread! Second, please understand that I'm no expert - I'm just posting as I try to learn all of this!
Taking a step beyond the approximations in the other thread, here's one which I believe might be even better. Let's use an example where I'm interested in receiving both 110 and 119 - I'll use these only because they're easy to aim at, since they have strong transponder signals. To begin with, I'll use a satellite calculator to figure out where I need to aim to hit either bird. Based on my location, I get:
119: Azimuth 174.9 Elevation 46.5
110: Azimuth 160.5 Elevation 44.8
We then need to figure out where to point the dish. Let's say that we decide to point the dish to 119, so that the dish has azimuth 174.9 and elevation 46.5. Now, where should the second LNB be placed to attempt to receive 110 from the same dish? My (revised) approximation to the proper position is:
Horizontal offset = focal_length * sin(dish_azimuth - new_azimuth)
Vertical offset = focal_length * sin(dish_elevation - new_elevation)
My satellite dish is a Fortec Star 90cm, which has a focal length of 510mm. The offsets for me are therefore:
Horizontal: 510mm * sin(174.9 - 160.5 [degrees]) = 127mm
Vertical: 510mm * sin(46.5 - 44.8 [degrees]) = 15mm
[EDIT: We interrupt this post... to let you know that I originally had the sign bit flipped on the east/west correction!
That's the bad news. The good news is that it was found by actually measuring optimal LNB placement, as documented later on in this thread. Numerically, the formula really works! The following paragraph has been corrected to fix the initial error.]
To translate these numbers, a positive horizontal offset means to move the new LNB to the west (i.e. left as you face the dish), while a negative horizontal offset means to move it to the east (right as you face the dish). For positive vertical offsets, move the new LNB upward, while a negative result means to move the LNB downward. So, in this case, I would need to place the 110 LNB 127mm (or 5 inches) to the left of the old LNB, and mount it 15mm (or ~0.6") higher.
Regardless of these guesses, I'd greatly appreciate your input, for I'm sure that better approximations will be possible. For example, these approximations all assume that the dish is spherical, even though it's actually parabolic. With a spherical dish, it may well be that moving the LNB one degree will change the target by one degree. With a parabolic dish, though, is this really the case? My gut tells me that the F/D ratio (the degree of curvature of the dish) might have something to do with a proper estimate. Any ideas as to how this might affect the results?
[EDIT2: It appears that the formula works fine, with no adjustment necessary for the F/D ratio, etc. It just works!]
What will make this most interesting will be to compare this theory to actual practice. Once I get around to actually installing my dish, I'll let you know how well this works out!
Cheers!
I'm in the process of setting up a second LNB on a 90cm dish, and thought that it would be worthwhile creating a thread that seeks to understand both the theory and practice behind adding additional LNBs to a dish. For folks that aren't familiar with this, the goal of doing so is to receive additional satellites with a single fixed dish. First of all, I'd like to express my thanks to "Anole" and "Smith, P" for getting me started on the theoretical aspects in this thread! Second, please understand that I'm no expert - I'm just posting as I try to learn all of this!
Taking a step beyond the approximations in the other thread, here's one which I believe might be even better. Let's use an example where I'm interested in receiving both 110 and 119 - I'll use these only because they're easy to aim at, since they have strong transponder signals. To begin with, I'll use a satellite calculator to figure out where I need to aim to hit either bird. Based on my location, I get:
119: Azimuth 174.9 Elevation 46.5
110: Azimuth 160.5 Elevation 44.8
We then need to figure out where to point the dish. Let's say that we decide to point the dish to 119, so that the dish has azimuth 174.9 and elevation 46.5. Now, where should the second LNB be placed to attempt to receive 110 from the same dish? My (revised) approximation to the proper position is:
Horizontal offset = focal_length * sin(dish_azimuth - new_azimuth)
Vertical offset = focal_length * sin(dish_elevation - new_elevation)
My satellite dish is a Fortec Star 90cm, which has a focal length of 510mm. The offsets for me are therefore:
Horizontal: 510mm * sin(174.9 - 160.5 [degrees]) = 127mm
Vertical: 510mm * sin(46.5 - 44.8 [degrees]) = 15mm
[EDIT: We interrupt this post... to let you know that I originally had the sign bit flipped on the east/west correction!
That's the bad news. The good news is that it was found by actually measuring optimal LNB placement, as documented later on in this thread. Numerically, the formula really works! The following paragraph has been corrected to fix the initial error.]To translate these numbers, a positive horizontal offset means to move the new LNB to the west (i.e. left as you face the dish), while a negative horizontal offset means to move it to the east (right as you face the dish). For positive vertical offsets, move the new LNB upward, while a negative result means to move the LNB downward. So, in this case, I would need to place the 110 LNB 127mm (or 5 inches) to the left of the old LNB, and mount it 15mm (or ~0.6") higher.
Regardless of these guesses, I'd greatly appreciate your input, for I'm sure that better approximations will be possible. For example, these approximations all assume that the dish is spherical, even though it's actually parabolic. With a spherical dish, it may well be that moving the LNB one degree will change the target by one degree. With a parabolic dish, though, is this really the case? My gut tells me that the F/D ratio (the degree of curvature of the dish) might have something to do with a proper estimate. Any ideas as to how this might affect the results?
[EDIT2: It appears that the formula works fine, with no adjustment necessary for the F/D ratio, etc. It just works!]
What will make this most interesting will be to compare this theory to actual practice. Once I get around to actually installing my dish, I'll let you know how well this works out!
Cheers!
P.S. While some folks think that theory's a waste of time, it's worth comparing this prediction to the approximation listed in the other thread. In that case, the estimated location for the new LNB is found as:
Horizontal offset: focal_length * sin(new_orbital_position - old_orbital_position)
Vertical offset: horizontal_offset * tan(my_skew_angle)
Using the same example setup, the numbers would work out to:
Horizontal: 510mm * sin(9) = 80mm (~3.1 inches)
Vertical: 80mm * tan(6.7) = 9mm (~1/3 inch)
In the other thread, there's then some special casing to figure out which directions to move the LNBs. Once I install my dish, it'll be fascinating to see which method is closest!
Horizontal offset: focal_length * sin(new_orbital_position - old_orbital_position)
Vertical offset: horizontal_offset * tan(my_skew_angle)
Using the same example setup, the numbers would work out to:
Horizontal: 510mm * sin(9) = 80mm (~3.1 inches)
Vertical: 80mm * tan(6.7) = 9mm (~1/3 inch)
In the other thread, there's then some special casing to figure out which directions to move the LNBs. Once I install my dish, it'll be fascinating to see which method is closest!
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