The horizontal alignment refers to the position of the satellite emitting the signal. Therefore, your dish needs to point either to the east or west, in the direction where you wish to receive the signal.

For DISH 300 installations pointed to the 119°W location, azimuth is 252° and elevation is 22°. For DISH 300 installations pointed to the 110°W location, azimuth is 243° and elevation is 28°. Note: The azimuth angle has already been corrected for magnetic deviation, so you can use this number on a compass.

aid to pointing your antenna. Determine which satellite you want to point at. Maps are provided for DISH® 72°, DISH 110°, DISH 119°, DISH 129°, DIRECTV® 101°, Bell TV™ 82°, and Bell TV 91°. 2.

Tilt the top of the dish backwards by an amount of 38.3 deg. Apply an inclinometer to some convenient place. Read the angle. Tilt the top of the dish backwards and the inclinometer reading will change.

To adjust the elevation of your satellite dish:

1. Loosen the elevation bolts on either side of the back of your satellite dish, while supporting your satellite dish, so that it is still movable.
2. Lift your satellite dish vertically, while monitoring the broadcast signal on the signal meter on the Dish Pointing menu.

It starts with North at 0°. As you turn to your right (in a clockwise direction) you’ll face East (which is 90°), then South (which is 180°), then West (which is 270°), and then return to North (which is 360° and also 0°). So if the Azimuth for your satellite is, say, 45°, that means your satellite is northeast of you.

The azimuth angle is like a compass direction with North = 0° and South = 180°. Other authors use a variety of slightly different definitions (i.e., angles of ± 180° and South = 0°).

An azimuth is the direction measured in degrees clockwise from north on an azimuth circle. An azimuth circle consists of 360 degrees. The azimuth reading is 45° or the bearing is N 45° E.

The azimuth is the angle between North, measured clockwise around the observer’s horizon, and a celestial body (sun, moon). It determines the direction of the celestial body. For example, a celestial body due North has an azimuth of 0º, one due East 90º, one due South 180º and one due West 270º. Sun at azimuth 214.6º.

The azimuth angle is measured clockwise from the zero azimuth. For example, if you’re in the Northern Hemisphere and the zero azimuth is set to South, the azimuth angle value will be negative before solar noon, and positive after solar noon.

Use your compass to determine or follow an azimuth. The arrow on the compass points toward magnetic north. The arrow is also attracted by any mass of metal-a truck, your rifle, your helmet, and even electrical power lines. Thus, be sure you use your compass away from metal objects so it will not give a wrong reading.

An azimuth is the direction of travel indicated on a compass and expressed in degrees (135 degrees). A bearing describes an angle or difference from a point. On the compass, you use the north and south for the reference. An azimuth of 135 degrees is the same as the bearing 45 degrees East of South (S 45 E).

difference between the two azimuths (the calibration point value) from your computed magnetic azimuth. Techniques for Using the Lensatic Compass. The two basic techniques for using the lensatic compass are the center hold technique and compass-to-cheek technique.

Back azimuth

1. Find your favourite object.
2. Set the compass so that the DOT arrow points to the object.
3. Fit the needle into the orienting arrow.
4. Read the azimuth set by the indexing line.
5. Correct for declination (from magnetic north to grid north)
6. Find the object on the map.
7. Orient the map.
8. Calculate the back azimuth.

A bearing is an angle less than 90° within a quadrant defined by the cardinal directions. An azimuth is an angle between 0° and 360° measured clockwise from North.

A celestial body’s amplitude angle is the complement of its azimuth angle. To determine compass error, simply convert the computed amplitude angle to true degrees and compare it with the observed compass bearing.

However, one of the most phenomenal that affects to the accuracy of the magnetic compass sensor is the temperature. The second scheme increases both the temperature working range and steady error performance of the sensor.

3 Factors that Influence Electronic Compass Accuracy

• #1 Time Varying Magnetic Fields.
• #2 Tilt Measurement Errors.
• #3 Magnetic Inclination (Dip Angle)