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LOng RAnge Navigation- LORAN, (Class II navigation)

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1st Modern practical area navigation system for use in general aviation. ... known as a hyperbolic lines of position since the lines look like a parabola. ... – PowerPoint PPT presentation

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Title: LOng RAnge Navigation- LORAN, (Class II navigation)


1
LOng RAnge Navigation- LORAN, (Class II
navigation)
  • AST 241
  • Dr. Barnhart

2
LORAN Overview
  • 1st Modern practical area navigation system for
    use in general aviation.
  • Developed for maritime navigation. Early LORAN
    As were exclusively for marine use
  • Still in use today although its use beyond 6 8
    years from now is uncertain

3
LORAN Overview
  • Certain LORAN-C receivers are approved for IFR
    Enroute and Terminal navigation but not for
    approaches.
  • Most LORAN-C recievers are used for VFR
    navigation
  • For all practical purposes (for the pilot)
    LORAN-C provides the same type of nav. Data to
    the pilot ( ground track, desired track,
    groundspeed, ETE)

4
LORAN-C Theory
  • Operates in the LOW frequency electromagnetic
    energy radio bandwidth which follows the
    curvature of the earth therefore making it
    suitable for longer ranges

5
LORAN Theory
  • The LORAN-C concept is based on groups or
    chains of stations around the world.
  • Worldwide there are 28 chains.
  • Each chain consists of one master station and 4
    6 secondary stations in a geographic area (ie.
    Northeast U.S.chain, Great Lakes U.S. chain, etc.)

6
LORAN Theory
  • The master station of each chain broadcasts a
    continuous string of Low Frequency pulses
    (measures in microseconds).
  • The unique time between the start and stop of
    each pulse identifies the particular chain.

7
LORAN Theory
  • This time is known as the Group Repetition
    Interval or GRI.
  • For instance the time between the start and stop
    of each pulse in the northeast U.S. chain is
    99,600 microseconds or 9960 for short. 9960 is
    identified as the great lakes chain

8
LORAN Theory
  • The GRI is entered into the LORAN-C unit in the
    aircraft upon startup along with the approximate
    LAT./Long. Position during the initialization
    process. This helps the unit find its position
    more quickly.

9
LORAN Theory
  • The LORAN-C unit then searches for that master
    station and the two strongest secondary signals.
  • The master station pulse triggers a response from
    the secondary stations. The receiver corrects for
    any time lag in pulse reply.

10
LORAN Theory
  • The receiver then calculates the time it takes
    these signals to reach the aircraft and
    essentially generates hyperbolic Lines of
    Position (LOP) from each station- known as a
    hyperbolic lines of position since the lines look
    like a parabola.

11
LORAN Theory
  • Two intersecting hyperbolas produce two possible
    points for the aircraft position.
  • Using a second slave (or secondary) station the
    receiver then pinpoints its position. Entering
    the Lat./long. During initialization also aids in
    this process.

12
LORAN Limitations
  • Area of coverage limited to chains which dont
    give global coverage
  • The sky wave component of the signal bounces
    off the ionosphere causing navigational errors
    when traveling greater than 1,000 NM from the
    farthest master or secondary station- causes
    errors in position of up to three miles (greater
    in some cases).

13
LORAN Limitations- sky waves
  • 1,000 miles is significant as at ranges less than
    this, the ground wave is significantly greater in
    strength than the sky waves therefore the
    receiver is programmed to reject the weaker sky
    waves.

14
LORAN Limitations- sky waves
  • At distances of between 1,000 and 1,400 NM the
    ground and sky waves are approximately the same
    strength making the signals seem the same to the
    receiver.
  • Since the sky waves take longer to reach the
    receiver than the ground waves, this leads to
    position errors.

15
LORAN Limitations- sky waves
  • Manufacturers deal with in one of two ways
  • Programming the receivers to reject all sky waves
    thereby reducing the effective range of the unit
    (but maximizing the accuracy)
  • Informing the user that nav. Data may be
    inaccurate between 1,000 and 1,400 NM
  • At ranges greater than 1,400 NM, the receivers
    can be programmed to use the sky wave

16
LORAN Limitations
  • As the aircraft moves through precipitation, it
    generates static electricity which generates
    electromagnetic noise around the aircraft
    thereby interfering with the LORAN signal-
    causing the Signal Strength to Noise ratio (SNR
    ratio) to go to unacceptable limits.
  • SNR ratio is a function of precip. Intensity and
    distance from the stations.

17
LORAN- Accuracy
  • LORAN accuracy is also best over water during the
    day.
  • Conversely it is least accurate over land masses
    at night (sky waves more intense at night).

18
LORAN Accuracy
  • Repeatable Accuracy- ability to return to a
    pre-set position for LORAN-C is .01 NM or 60ft.
  • Absolute Accuracy- ability of the receiver to
    determine its position independently is generally
    within at least 3 NM for distances up to 2,800 NM.
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