Introduction
The Instrument Landing System (ILS) is an
internationally normalized system for navigation of aircrafts upon the
final approach for landing. It was accepted as a standard system by the
ICAO, (International Civil Aviation Organization) in 1947.
Since the technical specifications of this system are worldwide prevalent, an aircraft equipped with a board system like the ILS, will reliably cooperate with an ILS ground system on every airport where such system is installed.
Since the technical specifications of this system are worldwide prevalent, an aircraft equipped with a board system like the ILS, will reliably cooperate with an ILS ground system on every airport where such system is installed.
The ILS system is nowadays the primary system for instrumental approach for category I.-III-A conditions of operation minimums
and it provides the horizontal as well as the vertical guidance
necessary for an accurate landing approach in IFR (Instrument Flight
Rules) conditions, thus in conditions of limited or reduced
visibility.The accurate landing approach is a procedure of permitted
descent with the use of navigational equipment coaxial with the
trajectory and given information about the angle of descent.
The equipment that provides a pilot instant
information about the distance to the point of reach is not a part of
the ILS system and therefore is for the discontinuous indication used a
set of two or three marker beacons
directly integrated into the system. The system of marker beacons can
however be complemented for a continuous measurement of distances with
the DME system (Distance measuring equipment), while the ground part of
this UKV distance meter is located co-operatively with the descent
beacon that forms the glide slope. It can also be supplemented with a
VOR system by which means the integrated navigational-landing complex
ILS/VOR/DME is formed.
Analysis
Categories of operation minimums.
Category I- A minimal height of resolution at 200 ft (60,96 m), whereas the decision height represents an altitude at which the pilot decides upon the visual contact with the runway if he’ll either finish the landing maneuver, or he’ll abort and repeat it.
- The visibility of the runway is at the minimum 1800 ft (548,64 m)
- The plane has to be equipped apart from the devices for flying in IFR (Instrument Flight Rules) conditions also with the ILS system and a marker beacon receiver.
- A minimal decision height at 100 ft (30,48 m)
- The visibility of the runway is at the minimum 1200 ft (365,76 m)
- The plane has to be equipped with a radio altimeter or an inner marker receiver, an autopilot link, a raindrops remover and also a system for the automatic draught control of the engine can be required. The crew consists of two pilots.
- A minimal decision height lower than 100 ft (30,48 m)
- The visibility of the runway is at the minimum 700 ft (213,36 m)
- The aircraft has to be equipped with an autopilot with a passive malfunction monitor or a HUD (Head-up display).
- A minimal decision height lower than 50 ft (15,24 m)
- The visibility of the runway is at the minimum 150 ft (45,72 m)
- A device for alteration of a rolling speed to travel speed.
- Zero visibility
Basic elements of the ILS system and THEIR brief description
The ILS system consists of four subsystems:- VHF localizer transmitter
- UHF glide slope transmitter
- marker beacons
- approach lighting system
Ground equipment
Localizer
One of the main components of the ILS
system is the localizer which handles the guidance in the horizontal
plane. The localizer is an antenna system comprised of a VHF transmitter
which uses the same frequency range as a VOR transmitter (108,10 ÷
111,95 MHz), however the frequencies of the localizer are only placed on
odd decimals, with a channel separation of 50 kHz. The trasmitter, or
antenna, is in the axis of the runway on it’s other end, opposite to the
direction of approach. A backcourse localizer is also used on some ILS
systems. The backcourse is intended for landing purposes and it’s
secured with a 75 MHz marker beacon or a NDB (Non Directional Beacon)
located 3÷5 nm (nautical miles), or 5,556÷9,26 km before the beginning
of the runway.
The course is periodically checked to ensure that the aircraft lies in the given tolerance
The course is periodically checked to ensure that the aircraft lies in the given tolerance
The transmitted signal:
The localizer, or VHF course marker, emits two directional radiation
patterns. One comprises of a bearing amplitude-modulated wave with a
harmonic signal frequency of 150 Hz and the other one with the same
bearing amplitude-modulated wave with a harmonic signal frequency of 90
Hz. These two directional radiation patterns do intersect and thus
create a course plane, or a horizontal axis of approach, which basically
represents an elongation of the runway’s axis
For an observer – a pilot, who is situated on the “approaching” side of the runway (therefore in front of the LLZ antenna system) predominates a modulation of 150 Hz on the right side of the course plane and 90 Hz on the left. The intersection of these two regions determines the on-track signal.
The width of the navigational ray can span from 3° to 6°, however mostly 5° are used. The ray is set to secure a signal approximately 700 ft (213, 36 m) wide on the borderline of the runway. The width of the ray magnifies, so at a distance of 10 nm (18,52 km) from the transmitter is the ray about 1 nm (1,852 km) wide.
The range of the localizer can be even 18 nm (33,336 km) in the 10° field from the center of the ray (on-track signal) and 10 nm (18,52km) in the field 10°÷35° from the center of the ray, because the main part of the signal is coaxial with the middle of the runway. The localizer is identified by an audio signal added to the navigational signal. The audio signal consists of letter „I“, following with a two-letter addition, for example: „I-OW“.
For an observer – a pilot, who is situated on the “approaching” side of the runway (therefore in front of the LLZ antenna system) predominates a modulation of 150 Hz on the right side of the course plane and 90 Hz on the left. The intersection of these two regions determines the on-track signal.
The width of the navigational ray can span from 3° to 6°, however mostly 5° are used. The ray is set to secure a signal approximately 700 ft (213, 36 m) wide on the borderline of the runway. The width of the ray magnifies, so at a distance of 10 nm (18,52 km) from the transmitter is the ray about 1 nm (1,852 km) wide.
The range of the localizer can be even 18 nm (33,336 km) in the 10° field from the center of the ray (on-track signal) and 10 nm (18,52km) in the field 10°÷35° from the center of the ray, because the main part of the signal is coaxial with the middle of the runway. The localizer is identified by an audio signal added to the navigational signal. The audio signal consists of letter „I“, following with a two-letter addition, for example: „I-OW“.
UHF descent beacon – glide slope
The transmitted signal:
The glide slope, or angle of the descent
plane provides the vertical guidance for the pilot during an approach.
It’s created by a ground UHF transmitter containing an antenna system
operating in the range of 329,30÷335.00 MHz, with a channel separation
of 50 kHz.
The transmitter is located 750÷1250 ft (228,6÷381 m) from the beginning of the runway and 400÷600 ft (121,92÷182,88 m) from it’s axis. The observed tolerance is ±0,5°. The UHF glide slope is paired with the corresponding frequency of the VHF localizer.
Like the signal of the localizer, so does the signal of the glide slope consist of two intersected radiation patterns, modulated at 90 and 150 Hz. However unlike the localizer, these signals are arranged on top of each other and emitted along the path of approach, as you can see in Fig. The thickness of the overlaping field is 0,7° over as well as under the optimal glide slope.
The signal of the glide slope can be set in the range of 2°÷4,5° over the horizontal plane of approach. Typically it’s a value of 2,5°÷3°, depending of the obstacles along the corridor of approach and the runway’s inclination.
False signals can be generated along the glide slope. It’s happening in multiples of the angle that‘s formed by the glide slope and the horizontal plane. The first case arises at approximately 6° over the horizontal plane. These false signals are inversive, which means that the directions to climb or descend will be swapped. A false signal at 9° will be oriented the same as the real glide slope. There are no false signals under the glide slope.
The transmitter is located 750÷1250 ft (228,6÷381 m) from the beginning of the runway and 400÷600 ft (121,92÷182,88 m) from it’s axis. The observed tolerance is ±0,5°. The UHF glide slope is paired with the corresponding frequency of the VHF localizer.
Like the signal of the localizer, so does the signal of the glide slope consist of two intersected radiation patterns, modulated at 90 and 150 Hz. However unlike the localizer, these signals are arranged on top of each other and emitted along the path of approach, as you can see in Fig. The thickness of the overlaping field is 0,7° over as well as under the optimal glide slope.
The signal of the glide slope can be set in the range of 2°÷4,5° over the horizontal plane of approach. Typically it’s a value of 2,5°÷3°, depending of the obstacles along the corridor of approach and the runway’s inclination.
False signals can be generated along the glide slope. It’s happening in multiples of the angle that‘s formed by the glide slope and the horizontal plane. The first case arises at approximately 6° over the horizontal plane. These false signals are inversive, which means that the directions to climb or descend will be swapped. A false signal at 9° will be oriented the same as the real glide slope. There are no false signals under the glide slope.
Localizer receiver
The signal is received on board of an
aircraft by an onboard localizer receiver. A simplified block scheme of
the onboard receiver of the localizer’s signals is displayed in Fig.
The localizer receiver and the VOR receiver form a single unit. The
signal of the localizer launches the vertical indicator called the track
bar (TB). Provided that the final approach does occur from south to
north, an aircraft flying westward from the runway’s axis is
situated in an area modulated at 90 Hz, therefore the track bar is
deflected to the right side.
On the contrary, if the plane’s positioned east from the runway’s axis, the 150 Hz modulated signal causes the track bar to lean out to the right side. In the area of intersection, both signals affect the track bar, which causes to a certain extent a deflection in the direction of the stronger signal. Thus if an aircraft flies roughly in the axis of approach leaned out partially to the right, the track bar is going to deflect a bit to the left. This indicates a necessary correction to the left. In the point where both signals 90 Hz and 150 Hz have the same intensity, the track bar is in the middle. Meaning that the plane is located exactly in the approach axis
When the track bar is used in conjunction with a VOR, a lean out of 10° to one or the other side from the signal causes a full deflection of the indicator. If the same pointer is used as an indicator of the ILS localizer, a full deflection will be induced by a 2,5° diversion from the center of the localizer’s beam. Therefore the sensitivity of the TB is roughly four times greater in the function as an indicator of the localizer as at the indication of information from the VOR.
In case that a red NAV bat appears in the upper right section of the onboard ILS indicator , it represents that the signal is far too weak or out of the receiver’s reach and for that reason the pointer’s deflection cannot be considered to be accurate. The vertical pointer will return to the neutral position, meaning to the center of the indicator. A momentary display of the NAV bat, short deviations of the TB, or both instances happening at once can occur in the case that an aircraft flies between the receiver’s antenna and the transmitter, or some other obstacle gets into their way.
glide slope receiver
The glide slope’s signal is on board of a
plane received by means of a UHF antenna. In modern avionics are the
controls for this receiver combined with the VOR’s controls, so the
correct frequency of the glide slope beacon is tuned in automatically at
the instant when the localizer’s frequency is selected.
The glide slope’s signal puts the
horizontal pointer of the glide slope into operation which intersects
the TB, see and . This indicator has its own GS bat which
lights up whenever the glide slope beacon’s signal is too weak or the
onboard receiver, hence the whole aircraft is out of the signal’s reach .
The onboard indicator of the ILS system can
be used by a pilot to determine the exact position because it provides
vertical as well as horizontal guiding. The case in portrays
both indicators in the middle, which means that the aircraft is located
in the point of intersection of the course plane (horizontal) and the
glide slope. The event pictured in indicates that the pilot must
descent and correct the flight course to the left in order to aquire
the correct course and glide slope level. The case shows
a necessity to ascend and adjust the flight course to the right.
With a 1,4° overlapping of the beams is the
area around 1500 ft (457,2 m) wide at a distance of 10 NM (18,52 km),
150 ft (45,72 m) at a distance of 1 NM (1,852 km), and less than one
foot (0,3 m) at the instant of touch down.
The apparent sensitivity of the instrument
increases as the aircraft closes in to the runway. The pilot has to
watch the indicator with attention so that he can keep an overlap of
both needles of the pointer in the middle of the indicator. Thereby
he’ll achieve a precise homing all the way to the touch down.
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