135

Miami

location-to-satellite

line

270

090

150

180

120

G-28069 C 11/16/05

Figure 4 - Inmarsat BGAN coverage map

To determine the direction from your location to the satellite, i.e., directional aiming, follow the steps 1-4 (below).

1.Refer to the Inmarsat BGAN coverage map at Figure 4.

2.Find your geographical location on the map. In our example, the mount installer is located in Miami, Florida, USA.

3.Determine which satellite footprint you are under. Draw a line from your location to the image of the satellite (in the same satellite footprint). The compass direction of your location-to-satellite line determines the gross orientation of the mount. In our example, the mount installer has drawn a line from the Miami location to the satellite. Using a protractor to measure the line direction in degrees, the installer determines that the direction is 135 degrees.

4.Using the full size map (Figure 10, page 7), you may now draw on the map to determine your location- to-satellite direction.

5.Using the compass (provided), align the mount so that it points in the same compass direction that you determined in step 3, above. If the line of sight is clear, i.e., no obstructions, then you may use the location to attach the now aligned mount to the structure.

3004090-0001 Revision A

3004090-0001, 3004066-001 specifications

The Hughes 3004066-001 and 3004090-0001 series represent advanced satellite communication technologies designed for various applications, including military, commercial, and governmental use. These models are known for their innovative design and robust performance, catering to the ever-evolving demands of modern communication systems.

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In conclusion, the Hughes 3004066-001 and 3004090-0001 models exemplify cutting-edge satellite communication technology. With their high data throughput, dual-band operation, robust security features, energy efficiency, and user-friendly designs, they cater to a wide range of applications, ensuring reliable connectivity and performance in the most challenging environments. As technology continues to advance, these models remain at the forefront of satellite communication innovation, meeting the demands of users worldwide.