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7.2.5_The localizer provides course guidance
throughout the descent path to the runway threshold
from a distance of 18 NM from the antenna between
an altitude of 1,000 feet above the highest terrain
along the course line and 4,500 feet above the
elevation of the antenna site. Proper off-course
indications are provided throughout the following
angular areas of the operational service volume:
7.2.5.1_To 10_ either side of the course along a radius
of 18 NM from the antenna.
7.2.5.2_From 10_ to 35_either side of the course
along a radius of 10 NM. (See FIG ENR 4.1-1.)
7.2.6_Unreliable signals may be received outside
these areas.
FIG ENR 4.1-1
Limits of Localizer Coverage
7.3_Localizer-Type Directional Aid
7.3.1_The localizer-type directional aid (LDA) is of
comparable use and accuracy to a localizer but is not
part of a complete ILS. The LDA course usually
provides a more precise approach course than the
similar Simplified Directional Facility (SDF) instal-
lation, which may have a course width of 6 degrees or
12 degrees.
7.3.2_The LDA is not aligned with the runway.
Straight-in minimums may be published where
alignment does not exceed 30 degrees between the
course and runway. Circling minimums only are
published where this alignment exceeds 30 degrees._
7.3.3_A very limited number of LDA approaches
also incorporate a glideslope. These are annotated in
the plan view of the instrument approach chart with
a note, _LDA/Glideslope." These procedures fall
under a newly defined category of approaches called
Approach with Vertical Guidance (APV) described in
Section ENR 1.5, paragraph 12, Instrument Approach Procedure Charts, subparagraph 12.1.7.2,
Approach with Vertical Guidance (APV). LDA
minima for with and without glideslope is provided
and annotated on the minima lines of the approach
chart as S-LDA/GS and S-LDA. Because the final
approach course is not aligned with the runway
centerline, additional maneuvering will be required
compared to an ILS approach.
7.4_Glide Slope/Glide Path
7.4.1_The UHF glide slope transmitter, operating on
one of the 40 ILS channels within the frequency range
329.15 MHz, to 335.00 MHz radiates its signals in the
direction of the localizer front course.
CAUTION-
False glide slope signals may exist in the area of the
localizer back course approach which can cause the glide
slope flag alarm to disappear and present unreliable glide
slope information. Disregard all glide slope signal
indications when making a localizer back course
approach unless a glide slope is specified on the approach
and landing chart.
7.4.2_The glide slope transmitter is located between
750 and 1,250 feet from the approach end of the
runway (down the runway) and offset 250-600 feet
from the runway centerline. It transmits a glide path
beam 1.4 degrees wide (vertically).
NOTE-
The term _glide path" means that portion of the glide slope
that intersects the localizer.
7.4.3_The glide path projection angle is normally
adjusted to 3 degrees above horizontal so that it
intersects the middle marker at about 200 feet and the
outer marker at about 1,400 feet above the runway
elevation. The glide slope is normally usable to the
distance of 10 NM. However, at some locations, the
AIP ENR 4.1-6
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
glide slope has been certified for an extended service
volume which exceeds 10 NM.
7.4.4_Pilots must be alert when approaching
glidepath interception. False courses and reverse
sensing will occur at angles considerably greater than
the published path.
7.4.5_Make every effort to remain on the indicated
glide path. Exercise caution: avoid flying below the
glide path to assure obstacle/terrain clearance is
maintained.
REFERENCE-
14 CFR Section 91.129(e).
7.4.6_A glide slope facility provides descent
information for navigation down to the lowest
authorized decision height (DH) specified in the
approved ILS approach procedure. The glidepath
may not be suitable for navigation below the lowest
authorized DH and any reference to glidepath
indications below that height must be supplemented
by visual reference to the runway environment. Glide
slopes with no published DH are usable to runway
threshold.
7.4.7_The published glide slope threshold crossing
height (TCH) DOES NOT represent the height of the
actual glide slope on course indication above the
runway threshold. It is used as a reference for
planning purposes which represents the height above
the runway threshold that an aircraft’s glide slope
antenna should be, if that aircraft remains on a
trajectory formed by the four-mile-to-middle
marker glidepath segment.
7.4.8_Pilots must be aware of the vertical height
between the aircraft’s glide slope antenna and the
main gear in the landing configuration and, at the DH,
plan to adjust the descent angle accordingly if the
published TCH indicates the wheel crossing height
over the runway threshold may be satisfactory. Tests
indicate a comfortable wheel crossing height is
approximately 20 to 30 feet, depending on the type of
aircraft.
NOTE-
The TCH for a runway is established based on several
factors including the largest aircraft category that
normally uses the runway, how airport layout effects the
glide slope antenna placement, and terrain. A higher than
optimum TCH, with the same glide path angle, may cause
the aircraft to touch down further from the threshold if the
trajectory of the approach is maintained until the flare.
Pilots should consider the effect of a high TCH on the
runway available for stopping the aircraft.
7.5_Distance Measuring Equipment (DME)
7.5.1_When installed with an ILS and specified in the
approach procedure, DME may be used:
7.5.1.1_In lieu of the outer marker.
7.5.1.2_As a back course final approach fix.
7.5.1.3_To establish other fixes on the localizer
course.
7.5.2_In some cases, DME from a separate facility
may be used within Terminal Instrument Procedures
(TERPS) limitations:
7.5.2.1_To provide ARC initial approach segments.
7.5.2.2_As a final approach fix for back course
approaches.
7.5.2.3_As a substitute for the outer marker.
7.6_Marker Beacon
7.6.1_ILS marker beacons have a rated power output
of 3 watts or less and an antenna array designed to
produce an elliptical pattern with dimensions, at
1,000 feet above the antenna, of approximately
2,400_feet in width and 4,200 feet in length. Airborne
marker beacon receivers with a selective sensitivity
feature should always be operated in the _low"
sensitivity position for proper reception of ILS
marker beacons.
7.6.2_Ordinarily, there are two marker beacons
associated with an ILS, the outer marker (OM) and
the middle marker (MM). Locations with a Category
II or III ILS also have an inner marker (IM). When an
aircraft passes over a marker, the pilot will receive the
following indications:
7.6.3_The OM normally indicates a position at which
an aircraft at the appropriate altitude on the localizer
course will intercept the ILS glide path.
7.6.4_The MM indicates a position approximately
3,500 feet from the landing threshold. This will also
be the position where an aircraft on the glide path will
be at an altitude of approximately 200 feet above the
elevation of the touchdown zone.
7.6.5_The IM indicates a point at which an aircraft is
at a designated decision height (DH) on the glide path
between the middle marker and landing threshold.
7.6.6_A back course marker, normally indicates the
ILS back course final approach fix where approach
descent is commenced.
AIP ENR 4.1-7
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
TBL ENR 4.1-1
Marker Passage Indications
Marker Code Light
OM _ _ _ BLUE
MM _ _ AMBER
IM WHITE
BC WHITE
8. Compass Locator
8.1_Compass locator transmitters are often situated
at the middle and outer marker sites. The transmitters
have a power of less than 25 watts, a range of at least
15 miles, and operate between 190 and 535 kHz. At
some locations, higher-powered radio beacons, up to
400 watts, are used as outer marker compass locators.
These generally carry Transcribed Weather Broadcast (TWEB) information.
8.2_Compass locators transmit two-letter identification groups. The outer locator transmits the first two
letters of the localizer identification group, and the
middle locator transmits the last two letters of the
localizer identification group.
9. ILS Frequency
9.1_The frequency pairs in TBL ENR 4.1-2 are
allocated for ILS.
TBL ENR 4.1-2
Frequency Pairs Allocated for ILS
Localizer MHz Glide Slope
108.10 334.70
108.15 334.55
108.3 334.10
108.35 333.95
108.5 329.90
108.55 329.75
108.7 330.50
108.75 330.35
108.9 329.30
108.95 329.15
109.1 331.40
109.15 331.25
109.3 332.00
109.35 331.85
109.50 332.60
109.55 332.45
109.70 333.20
109.75 333.05
109.90 333.80
109.95 333.65
110.1 334.40
110.15 334.25
110.3 335.00
110.35 334.85
110.5 329.60
110.55 329.45
110.70 330.20
110.75 330.05
110.90 330.80
110.95 330.65
111.10 331.70
111.15 331.55
111.30 332.30
111.35 332.15
111.50 332.9
111.55 332.75
111.70 333.5
111.75 333.35
111.90 331.1
111.95 330.95
AIP ENR 4.1-8
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
10. ILS Minimums
10.1_The lowest authorized ILS minimums, with all
required ground and airborne systems components
operative, are:
10.1.1_Category I._Decision Height (DH) 200 feet
and Runway Visual Range (RVR) 2,400 feet (with
touchdown zone and centerline lighting, RVR
1,800_feet).
10.1.2_Category II._DH 100 feet and RVR
1,200_feet.
10.1.3_Category IIIa._No DH or DH below 100 feet
and RVR not less than 700 feet.
10.1.4_Category IIIb._No DH or DH below 50 feet
and RVR less than 700 feet but not less than 150 feet.
10.1.5_Category IIIc._No DH or no RVR limitation.
NOTE-
Special authorization and equipment are required for
Category II and III.
11. Inoperative ILS Components
11.1_Inoperative Localizer._When the localizer
fails, an ILS approach is not authorized.
11.2_Inoperative Glide Slope._When the glide
slope fails, the ILS reverts to a nonprecision localizer
approach.
REFERENCE-
See the Inoperative Component Table in the U.S. Government Terminal
Procedures Publication (TPP) for adjustments to minimums due to
inoperative airborne or ground system equipment.
12. ILS Course Distortion
12.1_All pilots should be aware that disturbance to
ILS localizer/glide slope courses may occur when
surface vehicles/aircraft are operated near the
localizer/glide slope antennas. Most ILS installations
are subject to signal interference by either surface
vehicles, aircraft, or both. ILS _CRITICAL AREAS"
are established near each localizer and glide slope
antenna.
12.2_Air traffic control issues control instructions to
avoid interfering operations within ILS critical areas
at controlled airports during the hours the airport
traffic control tower is in operation as follows:
12.2.1_Weather Conditions._At or above 800 feet
and/or visibility 2 miles.
12.2.1.1_No critical area protection action is
provided.
12.2.1.2_If an aircraft advises the TOWER that an
_AUTOLAND"/_COUPLED" approach will be
conducted, an advisory will be promptly issued if a
vehicle/aircraft will be in or over a critical area when
the arriving aircraft is inside the ILS middle marker.
EXAMPLE-
Glide slope signal not protected.
12.2.2_Weather Conditions._Less than ceiling
800_feet and/or visibility 2 miles.
12.2.2.1_Glide Slope Critical Area._Vehicles/aircraft are not authorized in the area when an arriving
aircraft is between the ILS final approach fix and the
airport unless the aircraft has reported the airport in
sight and is circling or side stepping to land on other
than the ILS runway.
12.2.2.2_Localizer Critical Area._Except for aircraft that land, exit a runway, depart or miss approach,
vehicles and aircraft are not authorized in or over the
critical area when an arriving aircraft is between the
ILS final approach fix and the airport. Additionally,
when the ceiling is less than 200 feet and/or the
visibility is RVR 2,000 or less, vehicle/aircraft
operations in or over the area are not authorized when
an arriving aircraft is inside the ILS middle marker.
12.3_Aircraft holding below 5000 feet between the
outer marker and the airport may cause localizer
signal variations for aircraft conducting the ILS
approach. Accordingly, such holding is not authorized when weather or visibility conditions are less
than ceiling 800 feet and/or visibility 2 miles.
12.4_Pilots are cautioned that vehicular traffic not
subject to control by ATC may cause momentary
deviation to ILS course/glide slope signals. Also,
_critical areas" are not protected at uncontrolled
airports or at airports with an operating control tower
when weather/visibility conditions are above those
requiring protective measures. Aircraft conducting
_coupled" or _autoland" operations should be
especially alert in monitoring automatic flight control
systems. (See FIG ENR 4.1-2.)
NOTE-
Unless otherwise coordinated through flight standards,
ILS signals to Category 1 runways are not flight inspected
below 100 feet AGL. Guidance signal anomalies may be
encountered below this altitude.
AIP ENR 4.1-9
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
FIG ENR 4.1-2
FAA Instrument Landing Systems
AIP ENR 4.1-10
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
13. Continuous Power Facilities
13.1_In order to ensure that a basic ATC system
remains in operation despite an area wide or
catastrophic commercial power failure, key equipment and certain airports have been designated to
provide a network of facilities whose operational
capability can be utilized independent of any
commercial power supply.
13.2_In addition to those facilities comprising the
basic ATC system, the following approach and
lighting aids have been included in this program for
a selected runway:
13.2.1_ILS (Localizer, Glide Slope, Compass
Locator, Inner, Middle and Outer Markers).
13.2.2_Wind Measuring Capability.
13.2.3_Approach Light System (ALS) or Short ALS
(SALS).
13.2.4_Ceiling Measuring Capability.
13.2.5_Touchdown Zone Lighting (TDZL).
13.2.6_Centerline Lighting (CL).
13.2.7_Runway Visual Range (RVR).
13.2.8_High Intensity Runway Lighting (HIRL).
13.2.9_Taxiway Lighting.
13.2.10_Apron Light (Perimeter Only).
TBL ENR 4.1-3
Continuous Power Airports
Airport/Ident Runway No.
Albuquerque (ABQ) 08
Andrews AFB (ADW) 1L
Atlanta (ATL) 9R
Baltimore (BWI) 10
Bismarck (BIS) 31
Boise (BOI) 10R
Boston (BOS) 4R
Charlotte (CLT) 36L
Chicago (ORD) 14R
Cincinnati (CVG) 36
Cleveland (CLE) 5R
Dallas/Fort Worth (DFW) 17L
Denver (DEN) 35R
Des Moines (DSM) 30R
Detroit (DTW) 3L
Continuous Power Airports
Airport/Ident Runway No.
El Paso (ELP) 22
Great Falls (GTF) 03
Houston (IAH) 08
Indianapolis (IND) 4L
Jacksonville (JAX) 07
Kansas City (MCI) 19
Los Angeles (LAX) 24R
Memphis (MEM) 36L
Miami (MIA) 9L
Milwaukee (MKE) 01
Minneapolis (MSP) 29L
Nashville (BNA) 2L
Newark (EWR) 4R
New Orleans (MSY) 10
New York (JFK) 4R
New York (LGA) 22
Oklahoma City (OKC) 35R
Omaha (OMA) 14
Ontario, California (ONT) 26R
Philadelphia (PHL) 9R
Phoenix (PHX) 08R
Pittsburgh (PIT) 10L
Reno (RNO) 16
Salt Lake City (SLC) 34L
San Antonio (SAT) 12R
San Diego (SAN) 09
San Francisco (SFO) 28R
Seattle (SEA) 16R
St. Louis (STL) 24
Tampa (TPA) 36L
Tulsa (TUL) 35R
Washington (DCA) 36
Washington (IAD) 1R
Wichita (ICT) 01
13.3_The above have been designated _Continuous
Power Airports," and have independent back up
capability for the equipment installed.
NOTE-
The existing CPA runway is listed. Pending and future
changes at some locations will require a revised runway
designation.
AIP ENR 4.1-11
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
14. Simplified Directional Facility (SDF)
14.1_The SDF provides a final approach course
similar to that of the ILS localizer. It does not provide
glide slope information. A clear understanding of the
ILS localizer and the additional factors listed below
completely describe the operational characteristics
and use of the SDF.
14.2_The SDF transmits signals within the range of
108.10 to 111.95 MHz.
14.3_The approach techniques and procedures used
in an SDF instrument approach are essentially the
same as those employed in executing a standard
no-glide-slope localizer approach except the SDF
course may not be aligned with the runway and the
course may be wider, resulting in less precision.
14.4_Usable off-course indications are limited to
35_degrees either side of the course centerline.
Instrument indications received beyond 35 degrees
should be disregarded.
14.5_The SDF antenna may be offset from the
runway centerline. Because of this, the angle of
convergence between the final approach course and
the runway bearing should be determined by
reference to the instrument approach procedure chart.
This angle is generally not more than 3 degrees.
However, it should be noted that inasmuch as the
approach course originates at the antenna site, an
approach which is continued beyond the runway
threshold will lead the aircraft to the SDF offset
position rather than along the runway centerline.
14.6_The SDF signal is fixed at either 6 degrees or
12_degrees as necessary to provide maximum _fly
ability" and optimum course quality.
14.7_Identification consists of a three-letter identifier transmitted in Morse Code on the SDF frequency.
The appropriate instrument approach chart will
indicate the identifier used at a particular airport.
15. Microwave Landing System (MLS)
15.1_General
15.1.1_The MLS provides precision navigation
guidance for exact alignment and descent of aircraft
on approach to a runway. It provides azimuth,
elevation, and distance information. The elevation
transmitter is located to the side of the runway near
the approach threshold. The precision DME, which
provides range information, is normally collocated
with the azimuth transmitter.
15.1.2_Both lateral and vertical guidance may be
displayed on conventional course deviation indicators or incorporated into multipurpose cockpit
displays. Range information can be displayed by
conventional DME indicators and also incorporated
into multipurpose displays.
15.1.3_The MLS supplements the ILS as the standard
landing system in the U.S. for civil, military, and
international civil aviation. At international airports,
ILS service is protected to 2010.
15.1.4_The system may be divided into five
functions:
15.1.4.1_Approach azimuth.
15.1.4.2_Back azimuth.
15.1.4.3_Approach elevation.
15.1.4.4_Range.
15.1.4.5_Data communications.
15.1.5_The standard configuration of MLS ground
equipment includes:
15.1.5.1_An azimuth station to perform functions
15.1.4.1 and 15.1.4.5 above. In addition to providing
azimuth navigation guidance, the azimuth station
also transmits basic data which consists of
information associated directly with the operation of
the landing system, as well as advisory data on the
performance of the ground equipment.
15.1.5.2_An elevation station to perform function
15.1.4.3.
15.1.5.3_Distance Measuring Equipment (DME) to
perform function 15.1.4.4. The DME provides range
guidance, both standard (DME/N) and precision
DME (DME/P).
15.1.6_MLS Expansion Capabilities._The standard configuration can be expanded by adding one or
more of the following functions or characteristics.
15.1.6.1_Back Azimuth._Provides lateral guidance
for missed approach and departure navigation.
15.1.6.2_Auxiliary Data Transmissions._Provides
additional data, including refined airborne positioning, meteorological information, runway status, and
other supplementary information.
15.1.6.3_Expanded Service Volume (ESV).
Provides proportional guidance to 60 degrees.
AIP ENR 4.1-12
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
15.1.7_MLS identification is a four-letter designation starting with the letter M. It is transmitted in
Morse Code at least six times per minute by the
approach azimuth (and back azimuth) ground
equipment.
15.2_Approach Azimuth Guidance
15.2.1_The azimuth station transmits MLS angle and
data on one of the 200 channels within the frequency
range of 5031 to 5091 MHz.
15.2.2_The equipment is normally located about
1,000 feet beyond the stop end of the runway, but
there is considerable flexibility in selecting sites. For
example, for heliport operations the azimuth
transmitter can be collocated with the elevation
transmitter.
15.2.3_The azimuth coverage extends:
(See FIG ENR 4.1-3.)
FIG ENR 4.1-3
Coverage Volume
Azimuth
APPROACH
AZIMUTH
AZIMUTH
-40°
+40°
20 NM
ESV
ESV
14 NM
+60°
MAXIMUM LIMIT
14 NM
-60°
15.2.3.1_Laterally, at least 40 degrees on either side
of the runway centerline in a standard configuration.
15.2.3.2_In elevation, up to an angle of 15 degrees -
and to at least 20,000 feet.
15.2.3.3_In range, to at least 20 NM.
15.3_Elevation Guidance
15.3.1_The elevation station transmits signals on the
same frequency as the azimuth station. A single
frequency is time-shared between all angle and data
functions.
15.3.2_The elevation transmitter is normally located
about 400 feet from the side of the runway between
runway threshold and the touchdown zone.
15.3.3_Elevation coverage is provided in the same
airspace as the azimuth guidance signals:
15.3.3.1_In elevation, to at least +15 degrees.
15.3.3.2_Laterally, to fill the azimuth lateral
coverage.
15.3.3.3_In range, to at least 20 NM. (See
FIG ENR 4.1-4.)
FIG ENR 4.1-4
Coverage Volumes
Elevation
ELEVATION
NORMAL
GLIDE PATH
MAXIMUM LIMIT 20,000’
20 NM 30
3
15
o
o
o
o
15.4_Range Guidance
15.4.1_The MLS Precision Distance Measuring
Equipment (DME/P) functions the same as the
navigation DME, but with some technical differences. The beacon transponder operates in the
frequency band 962 to 1105 MHz and responds to an
aircraft interrogator. The MLS DME/P accuracy is
improved to be consistent with the accuracy provided
by the MLS azimuth and elevation stations.
15.4.2_A DME/P channel is paired with the azimuth
and elevation channel. A complete listing of the 200
paired channels of the DME/P with the angle
functions is contained in FAA Standard 022 (MLS
Interoperability and Performance Requirements).
AIP ENR 4.1-13
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
15.4.3_The DME/N or DME/P is an integral part of
the MLS and is installed at all MLS facilities unless
a waiver is obtained. This occurs infrequently and
only at outlying, low density airports where marker
beacons or compass locators are already in place.
15.5_Data Communications
15.5.1_The data transmission can include both the
basic and auxiliary data words. All MLS facilities
transmit basic data. Where needed, auxiliary data can
be transmitted.
15.5.2_Coverage Limits._MLS data are transmitted
throughout the azimuth (and back azimuth when
provided) coverage sectors.
15.5.3_Basic Data Content._Representative data
include:
15.5.3.1_Station identification.
15.5.3.2_Exact locations of azimuth, elevation and
DME/P stations (for MLS receiver processing
functions).
15.5.3.3_Ground equipment performance level.
15.5.3.4_DME/P channel and status.
15.5.4_Auxiliary Data Content._Representative
data include:
15.5.4.1_3-D locations of MLS equipment.
15.5.4.2_Waypoint coordinates.
15.5.4.3_Runway conditions.
15.5.4.4_Weather (e.g., RVR, ceiling, altimeter
setting, wind, wake vortex, wind shear).
15.6_Operational Flexibility._The MLS has the
capability to fulfill a variety of needs in the approach,
landing, missed approach, and departure phases of
flight. For example:
15.6.1_Curved and segmented approaches.
15.6.2_Selectable glide path angles.
15.6.3_Accurate 3-D positioning of the aircraft in
space.
15.6.4_The establishment of boundaries to ensure
clearance from obstructions in the terminal area.
15.7_While many of these capabilities are available
to any MLS-equipped aircraft, the more sophisti-
cated capabilities (such as curved and segmented
approaches) are dependent upon the particular
capabilities of the airborne equipment.
15.8_Summary
15.8.1_Accuracy._The MLS provides precision,
three-dimensional navigation guidance accurate
enough for all approach and landing maneuvers.
15.8.2_Coverage._Accuracy is consistent throughout the coverage volumes shown in FIG ENR 4.1-5.
FIG ENR 4.1-5
Coverage Volumes
3-D Representation
15.8.3_Environment._The system has low susceptibility to interference from weather conditions and
airport ground traffic.
15.8.4_Channels._MLS has 200 channels - enough
for any foreseeable need.
15.8.5_Data._The MLS transmits ground-air data
messages associated with system operation.
15.8.6_Range Information._Continuous range information is provided with an accuracy of about
100_feet.
AIP ENR 4.1-14
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
16. LORAN
16.1_Introduction
16.1.1_The LOng RAnge Navigation-C (LORAN)
system is a hyperbolic, terrestrial-based navigation
system operating in the 90-110 kHz frequency band.
LORAN, operated by the U.S. Coast Guard (USCG),
has been in service for over 50 years and is used for
navigation by the various transportation modes, as
well as, for precise time and frequency applications.
The system is configured to provide reliable, all
weather navigation for marine users along the U.S.
coasts and in the Great Lakes.
16.1.2_In the 1980’s, responding to aviation user and
industry requests, the USCG and FAA expanded
LORAN coverage to include the entire continental
U.S. This work was completed in late 1990, but the
LORAN system failed to gain significant user
acceptance and primarily due to transmitter and user
equipment performance limitations, attempts to
obtain FAA certification of nonprecision approach
capable receivers were unsuccessful. More recently,
concern regarding the vulnerability of Global
Positioning System (GPS) and the consequences of
losing GPS on the critical U.S. infrastructure
(e.g.,_NAS) has renewed and refocused attention on
LORAN.
16.1.3_LORAN is also supported in the Canadian
airspace system. Currently, LORAN receivers are
only certified for en route navigation.
16.1.4_Additional information can be found in the
_LORAN-C User Handbook," COMDT PUBP
16562.6, or the website:
http://www.navcen.uscg.gov.
16.2_LORAN Chain
16.2.1_The locations of the U.S. and Canadian
LORAN transmitters and monitor sites are illustrated
in FIG ENR 4.1-6. Station operations are organized
into subgroups of four to six stations called _chains."
One station in the chain is designated the _Master"
and the others are _secondary" stations. The resulting
chain based coverage is seen in FIG ENR 4.1-7.
FIG ENR 4.1-6
U.S. and Canadian LORAN System Architecture
AIP ENR 4.1-15
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
FIG ENR 4.1-7
LORAN Chain Based Coverage
16.2.2_The LORAN navigation signal is a carefully
structured sequence of brief radio frequency pulses
centered at 100 kHz. The sequence of signal
transmissions consists of a pulse group from the
Master (M) station followed at precise time intervals
by groups from the secondary stations, which are
designated by the U.S. Coast Guard with the letters V,
W, X, Y and Z. All secondary stations radiate pulses
in groups of eight, but for identification the Master
signal has an additional ninth pulse. (See
FIG ENR 4.1-8.) The timing of the LORAN system
is tightly controlled and synchronized to Coordinated
Universal Time (UTC). Like the GPS, this is a
Stratum_1 timing standard.
16.2.3_The time interval between the reoccurrence of
the Master pulse group is called the Group Repetition
Interval (GRI). The GRI is the same for all stations in
a chain and each LORAN chain has a unique GRI.
Since all stations in a particular chain operate on the
same radio frequency, the GRI is the key by which a
LORAN receiver can identify and isolate signal
groups from a specific chain.
EXAMPLE-
Transmitters in the Northeast U.S. chain (FIG ENR 4.1-9)
operate with a GRI of 99,600 microseconds which is
shortened to 9960 for convenience. The master station (M)
at Seneca, New York, controls secondary stations (W) at
Caribou, Maine; (X) at Nantucket, Massachusetts; (Y) at
Carolina Beach, North Carolina, and (Z) at Dana, Indiana.
In order to keep chain operations precise, monitor
receivers are located at Cape Elizabeth, ME; Sandy Hook,
NJ; Dunbar Forest, MI, and Plumbrook, OH. Monitor
receivers continuously measure various aspects of the
quality (e.g., pulse shape) and accuracy (e.g., timing) of
LORAN signals and report system status to a control
station.
16.2.4_The line between the Master and each
secondary station is the _baseline" for a pair of
stations. Typical baselines are from 600 to
1000_nautical miles in length. The continuation of the
baseline in either direction is a _baseline extension."
16.2.5_At the LORAN transmitter stations there are
cesium oscillators, transmitter time and control
equipment, a transmitter, primary power (e.g.,_commercial or generator) and auxiliary power equipment
(e.g., uninterruptible power supplies and generators),
and a transmitting antenna (configurations may either
have 1 or 4 towers) with the tower heights ranging
from 700 to 1350 feet tall. Depending on the coverage
area requirements a LORAN station transmits from
400 to 1,600 kilowatts of peak signal power.
16.2.6_The USCG operates the LORAN transmitter
stations under a reduced staffing structure that is
made possible by the remote control and monitoring
of the critical station and signal parameters. The
actual control of the transmitting station is
AIP ENR 4.1-16
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
accomplished remotely at Coast Guard Navigation
Center (NAVCEN) located in Alexandria, Virginia.
East Coast and Midwest stations are controlled by the
NAVCEN. Stations on the West Coast and in Alaska
are controlled by the NAVCEN Detachment (Det),
located in Petaluma, California. In the event of a
problem at one of these two 24 hour-a-day staffed
sites, monitoring and control of the entire LORAN
system can be done at either location. If both NACEN
and NAVCEN Det are down or if there is an
equipment problem at a specific station, local station
personnel are available to operate and perform repairs
at each LORAN station.
16.2.7_The transmitted signal is also monitored in the
service areas (i.e., area of published LORAN
coverage) and its status provided to NAVCEN and
NAVCEN Det. The System Area Monitor (SAM) is
a single site used to observe the transmitted signal
(signal strength, time difference, and pulse shape). If
an out-of-tolerance situation that could affect
navigation accuracy is detected, an alert signal called
_Blink" is activated. Blink is a distinctive change in
the group of eight pulses that can be recognized
automatically by a receiver so the user is notified
instantly that the LORAN system should not be used
for navigation. Out-of-tolerance situations which
only the local station can detect are also monitored.
These situations when detected cause signal
transmissions from a station to be halted.
16.2.8_Each individual LORAN chain provides
navigation-quality signal coverage over an identified
area as shown in FIG ENR 4.1-10 for the West Coast
chain, GRI 9940. The chain Master station is at
Fallon, Nevada, and secondary stations are at George,
Washington; Middletown, California, and Searchlight, Nevada. In a signal coverage area the signal
strength relative to the normal ambient radio noise
must be adequate to assure successful reception.
Similar coverage area charts are available for all
chains.
AIP ENR 4.1-17
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
FIG ENR 4.1-8
The LORAN Pulse and Pulse Group
AIP ENR 4.1-18
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
FIG ENR 4.1-9
Northeast U.S. LORAN Chain
AIP ENR 4.1-19
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
FIG ENR 4.1-10
West Coast U.S. LORAN Chain
AIP ENR 4.1-20
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
16.3_The LORAN Receiver
16.3.1_For a currently certified LORAN aviation
receiver to provide navigation information for a pilot,
it must successfully receive, or _acquire," signals
from three or more stations in a chain. Acquisition
involves the time synchronization of the receiver with
the chain GRI, identification of the Master station
signals from among those checked, identification of
secondary station signals, and the proper selection of
the tracking point on each signal at which
measurements are made. However, a new generation
of receivers has been developed that use pulses from
all stations that can be received at the pilot’s location.
Use of _all-in-view" stations by a receiver is made
possible due to the synchronization of LORAN
stations signals to UTC. This new generation of
receivers, along with improvements at the transmitting stations and changes in system policy and
operations doctrine may allow for LORAN’s use in
nonprecision approaches. At this time these receivers
are available for purchase, but none have been
certified for aviation use.
16.3.2_The basic measurements made by certified
LORAN receivers are the differences in time-of-arrival between the Master signal and the signals from
each of the secondary stations of a chain. Each _time
difference" (TD) value is measured to a precision of
about 0.1 microseconds. As a rule of thumb,
0.1_microsecond is equal to about 100 feet.
16.3.3_An aircraft’s LORAN receiver must recognize three signal conditions:
16.3.3.1_Usable signals;
16.3.3.2_Absence of signals, and
16.3.3.3_Signal blink.
16.3.4_The most critical phase of flight is during the
approach to landing at an airport. During the
approach phase the receiver must detect a lost signal,
or a signal Blink, within 10 seconds of the occurrence
and warn the pilot of the event. At this time there are
no receivers that are certified for nonprecision
approaches.
16.3.5_Most certified receivers have various internal
tests for estimating the probable accuracy of the
current TD values and consequent navigation
solutions. Tests may include verification of the timing
alignment of the receiver clock with the LORAN
pulse, or a continuous measurement of the signal-
to-noise ratio (SNR). SNR is the relative strength of
the LORAN signals compared to the local ambient
noise level. If any of the tests fail, or if the quantities
measured are out of the limits set for reliable
navigation, then an alarm will be activated to alert the
pilot.
16.3.6_LORAN signals operate in the low frequency
band (90-110 kHz) that has been reserved for marine
navigation signals. Adjacent to the band, however,
are numerous low frequency communications
transmitters. Nearby signals can distort the LORAN
signals and must be eliminated by the receiver to
assure proper operation. To eliminate interfering
signals, LORAN receivers have selective internal
filters. These filters, commonly known as _notch
filters," reduce the effect of interfering signals.
16.3.7_Careful installation of antennas, good metal-
to-metal electrical bonding, and provisions for
precipitation noise discharge on the aircraft are
essential for the successful operation of LORAN
receivers. A LORAN antenna should be installed on
an aircraft in accordance with the manufacturer’s
instructions. Corroded bonding straps should be
replaced, and static discharge devices installed at
points indicated by the aircraft manufacturer.
16.4_LORAN Navigation
16.4.1_An airborne LORAN receiver has four major
parts:
16.4.1.1_Signal processor;
16.4.1.2_Navigation computer;
16.4.1.3_Control/display, and
16.4.1.4_Antenna.
16.4.2_The signal processor acquires LORAN
signals and measures the difference between the
time-of-arrival of each secondary station pulse
group and the Master station pulse group. The
measured TDs depend on the location of the receiver
in relation to the three or more transmitters.
AIP ENR 4.1-21
United States of America 15 MAR 07
Federal Aviation Administration Nineteenth Edition
FIG ENR 4.1-11
First Line-of-Position
16.4.2.1_The first TD will locate an aircraft
somewhere on a line-of-position (LOP) on which the
receiver will measure the same TD value.
16.4.2.2_A second LOP is defined by a TD
measurement between the Master station signal and
the signal form another secondary station.
FIG ENR 4.1-12
Second Line-of-Position
16.4.2.3_The intersection of the measured LOPs is
the position of the aircraft.
FIG ENR 4.1-13
Intersection of Lines-of-Position
16.4.3_The navigation computer converts TD values
to corresponding latitude and longitude. Once the
time and position of the aircraft are established at
two_points, distance to destination, cross track error,
ground speed, estimated time of arrival, etc., can be
determined. Cross track error can be displayed as the
vertical needle of a course deviation indicator, or
digitally, as decimal parts of a mile left or right of
course.
16.5_Notices to Airmen (NOTAMs) are issued for
LORAN chain or station outages. Domestic
NOTAM_(D)s are issued under the identifier _LRN."
International NOTAMs are issued under the KNMH
series. Pilots may obtain these NOTAMs from FSS
briefers upon request.
16.6_LORAN Status Information._To find out
more information on the LORAN system and its
operational status you can visit the website
http://www.navcen.uscg.gov/loran/default.htm or
contact NAVCEN’s Navigation Information Service
(NIS) watchstander, phone_(703) 313-5900,
fax_(703) 313-5920.
16.7_LORAN’s future._The U.S. will continue to
operate the LORAN system in the short term. During
this time, the FAA LORAN evaluation program,
AIP ENR 4.1-22
United States of America 15 MAR 07
Federal Aviation Administration
Nineteenth Edition
being conducted with the support of a team
comprising government, academia, and industry, will
identify and assess LORAN’s potential contributions
to required navigation services for the National
Airspace System (NAS), and support decisions
regarding continued operation of the system. If the
government concludes LORAN should not be kept as
part of the mix of federally provided radio navigation
systems, it will give the users of LORAN reasonable
notice so that they will have the opportunity to
transition to alternative navigation aids.
17. Inertial Reference Unit (IRU), Inertial
Navigation System (INS), and Attitude
Heading Reference System (AHRS)
17.1_IRUs are self-contained systems comprised of
gyros and accelerometers that provide aircraft
attitude (pitch, roll, and heading), position, and
velocity information in response to signals resulting
from inertial effects on system components. Once
aligned with a known position, IRUs continuously
calculate position and velocity. IRU position
accuracy decays with time. This degradation is
known as _drift."
17.2_INSs combine the components of an IRU with
an internal navigation computer. By programming a
series of waypoints, these systems will navigate along
a predetermined track.
17.3_AHRSs are electronic devices that provide
attitude information to aircraft systems such as
weather radar and autopilot, but do not directly
compute position information.
18. Global Positioning System (GPS)
18.1_System Overview
18.1.1_System Description. The Global Positioning
System is a satellite-based radio navigation system,
which broadcasts a signal that is used by receivers to
determine precise position anywhere in the world.
The receiver tracks multiple satellites and determines
a pseudorange measurement that is then used to
determine the user location. A minimum of four
satellites is necessary to establish an accurate
three-dimensional position. The Department of
Defense (DOD) is responsible for operating the GPS
satellite constellation and monitors the GPS satellites
to ensure proper operation. Every satellite’s orbital
parameters (ephemeris data) are sent to each satellite
for broadcast as part of the data message embedded
in the GPS signal. The GPS coordinate system is the
Cartesian earth-centered earth-fixed coordinates as
specified in the World Geodetic System 1984
(WGS-84).
18.1.2_System Availability and Reliability
18.1.2.1_The status of GPS satellites is broadcast as
part of the data message transmitted by the GPS
satellites. GPS status information is also available by
means of the U.S. Coast Guard navigation
information service: (703) 313-5907, Internet:
http://www.navcen.uscg.gov/. Additionally, satellite status is available through the Notice to Airmen
(NOTAM) system. |
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发表于 2008-12-19 23:31:36
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