|
Size: 3506
Comment:
|
Size: 3516
Comment:
|
| Deletions are marked like this. | Additions are marked like this. |
| Line 30: | Line 30: |
| '''ERROR:''' wrong angle! What we want is $ \large \alpha ~=~ \phi_m - \gamma $. The following is approximately right near zenith because $ R_{288} ~ \cong ~ 2 \times R_E $ in this particular instance, but not always! More complex math needed. | '''ERROR:''' wrong angle! What we want is $ \large \alpha ~=~ \phi_m - \gamma $. The following is approximately right near zenith because $ R_{288} ~ \approx ~ 2 \times R_E $ in this particular instance, but not always! More complex math needed. |
| Line 32: | Line 32: |
| $ W ~ \cong ~ N d $ is approximately the length of the antenna - and since we can leave some elements off, we can adjust N until the angular spacing is exactly the spacing of the arrays. In other words, all the arrays besides the one in the center of the beam are in nulls. At least for the nearby arrays at small angles; for the ones farther out, they will move into the edges of powered lobes - except that those lobes will be at much lower power levels. | $ W ~ \approx ~ N d $ is approximately the length of the antenna - and since we can leave some elements off, we can adjust N until the angular spacing is exactly the spacing of the arrays. In other words, all the arrays besides the one in the center of the beam are in nulls. At least for the nearby arrays at small angles; for the ones farther out, they will move into the edges of powered lobes - except that those lobes will be at much lower power levels. |
| Line 36: | Line 36: |
| So, what is the orbiting array angle versus antenna size, assuming a small angle approximation of $ \sin( \gamma ) \cong \gamma $? That angle is $ 2 { \large \pi} / P $ given $ P $ arrays in orbit . | So, what is the orbiting array angle versus antenna size, assuming a small angle approximation of $ \sin( \gamma ) \approx \gamma $? That angle is $ 2 { \large \pi} / P $ given $ P $ arrays in orbit . |
| Line 38: | Line 38: |
| $ { \LARGE { { 2 \pi } \over P } } { \large ~ \cong ~ } { \LARGE { { R_E \lambda } \over { R_{288} W } } } ~~~ $ or $ ~~~ { \large L ~ \cong ~ }{ \LARGE { { { \lambda P } \over { 2 \pi } } { R_E \over R_{288} } } } $ | $ { \LARGE { { 2 \pi } \over P } } { \large ~ \approx ~ } { \LARGE { { R_E \lambda } \over { R_{288} W } } } ~~~ $ or $ ~~~ { \large L ~ \approx ~ }{ \LARGE { { { \lambda P } \over { 2 \pi } } { R_E \over R_{288} } } } $ |
Ground Antenna Array Zeros
Summary: The zeros of the ground antenna array can be lined up to overlap non-selected orbiting arrays, nulling them out if they are not selected.
Note: this is incomplete. It is only for an array at zenith, from 0° latitude. The ground array will probably need to be larger to select arrays near the horizon. I also computed \alpha incorrectly, big errors far from zenith.
from Haupt pages 55 to 57:
\large { \psi ~=~ { \LARGE \left( { 2 \pi d } \over \lambda \right) } \sin( \phi ) } ~~~~~ where \phi is the angle from zenith
For an equatorial antenna array pointed at zenith:
\large { Power ~=~ } \LARGE \left( { \sin( N \psi / 2 ) } \over { N \sin( \psi / 2 ) } \right)^2 ~ ~ ~
So \psi where the power is zero are given by:
\large { \psi_0 ~=~ \pm { \LARGE \left( { 2 m \pi } \over N \right) } ~~~~ m = 1, 2, 3, ... }
So we can find \sin( \phi_m ) from:
{ \LARGE \left( { 2 \pi d } \over \lambda \right) } { \large \sin( \phi_m) ~=~ } { \LARGE \left( { 2 \pi m } \over N \right) } or { \large \sin( \phi_m ) ~=~ } { \LARGE { { m \lambda } \over { N d } } }
The ground antenna is at radius R_E . What is the angle \large \gamma of the thinsat array( at radius R_{288} ) from zenith? We can compute this from the SSA triangle:
{ \large \sin( \gamma ) ~=~ { \LARGE \left( { R_E } \over { R_{288} } \right) } \sin( \phi_m ) ~=~ { \LARGE \left( { R_E \lambda } \over { R_{288} N d } \right) } m }
ERROR: wrong angle! What we want is \large \alpha ~=~ \phi_m - \gamma . The following is approximately right near zenith because R_{288} ~ \approx ~ 2 \times R_E in this particular instance, but not always! More complex math needed.
W ~ \approx ~ N d is approximately the length of the antenna - and since we can leave some elements off, we can adjust N until the angular spacing is exactly the spacing of the arrays. In other words, all the arrays besides the one in the center of the beam are in nulls. At least for the nearby arrays at small angles; for the ones farther out, they will move into the edges of powered lobes - except that those lobes will be at much lower power levels.
This is cool!
So, what is the orbiting array angle versus antenna size, assuming a small angle approximation of \sin( \gamma ) \approx \gamma ? That angle is 2 { \large \pi} / P given P arrays in orbit .
{ \LARGE { { 2 \pi } \over P } } { \large ~ \approx ~ } { \LARGE { { R_E \lambda } \over { R_{288} W } } } ~~~ or ~~~ { \large L ~ \approx ~ }{ \LARGE { { { \lambda P } \over { 2 \pi } } { R_E \over R_{288} } } }
\lambda |
4.28 mm |
R_E |
6378 km |
R_{288} |
12789 km |
P |
W |
100 |
3.4 cm |
3600 |
1.22 m |
10000 |
3.4 m |
This is the selectivity of the antenna, assuming many other orbiting arrays are broadcasting simultaneously to the same region. In the distant future, we will have thousands of arrays near the same angular address - all addressing different ground antenna regions. With 10,000 angular addresses, the angular addresses are 8.04 kilometers apart; the arrays might be arranged in a rotating tilted disk around orbit center, radius 30 km, spaced 1 km apart, about 2800 arrays, or 28 million arrays in the entire orbit. At 7842 thinsats each, that is 220 billion total thinsats.