ATP EASA - Qatar 2

a simple intruding airplane proximity warning.

the intruder relative position and possibly an indication of a collision avoidance
manoeuvre within the vertical plane only.

the intruder relative position and possibly an indication of a collision avoidance manoeuvre
within both the vertical and horizontal planes.

the intruder relative position and possibly an indication of a collision avoidance manoeuvre
within the horizontal plane only.

airborne weather radar system

transponders fitted in the aircraft

F.M.S. (Flight Management System)

air traffic control radar systems

""traffic advisory"" and horizontal ""resolution advisory""

""traffic advisory"" only.

""traffic advisory"" and vertical ""resolution advisory"".

""traffic advisory"", vertical and horizontal ""resolution advisory"".

""traffic advisory"" and vertical ""resolution advisory"".

""traffic advisory"" and horizontal ""resolution advisory"".

""traffic advisory"" only.

""traffic advisory"", vertical and horizontal ""resolution advisory"".

blue or white empty lozenge.

red full square.

blue or white full lozenge

red full circle.

1, 4

1, 2, 3, 4, 5

2, 3, 4, 5

1, 3, 5

airspeed.

aerodynamic incidence.

attitude.

groundspeed.

1, 2, 5.

1, 2, 4.

1,5

2,5

through which the sum of the forces of all masses of the body is considered to act.

where the sum of the moments from the external forces acting on the body is equal to
zero.

where the sum of the external forces is equal to zero.

which is always used as datum when computing moments.

centre of thrust along the longitudinal axis, in relation to a datum line

point where all the aircraft mass is considered to be concentrated

focus along the longitudinal axis, in relation to a datum line

neutral point along the longitudinal axis, in relation to a datum line

A decrease in the landing speed.

A decrease in range.

A decrease of the stalling speed.

A tendency to yaw to the right on take-off.

The Maximum Landing Mass of an aeroplane is restricted by structural limitations, performance limitations and the strength of the runway.

The Maximum Zero Fuel Mass ensures that the centre of gravity remains within limits after the uplift of fuel.

The Maximum Take-off Mass is equal to the maximum mass when leaving the ramp.

The Basic Empty Mass is equal to the mass of the aeroplane excluding traffic load and useable fuel but including the crew.

increased cruise range.

higher stall speed.

lower optimum cruising speed.

reduced maximum cruise range.

decrease longitudinal static stability

increase longitudinal static stability

does not influence longitudinal static stability

not change the static curve of stability into longitudinal

will be greater than required

will give reduced safety margins

will not be achieved

are unaffected but V1 will be increased

lateral axis.

longitudinal axis.

vertical axis.

horizontal axis.

VR< VMCA< VLOF

VS< VMCA< V2 min

VMU<= VMCA< V1

V2min< VMCA> VMU

altitude reference to the standard datum plane

pressure altitude corrected for 'non standard' temperature

altitude read directly from the altimeter

height above the surface

is equal to the pressure altitude.

is used to determine the aeroplane performance.

is used to establish minimum clearance of 2.000 feet over mountains.

is used to calculate the FL above the Transition Altitude.

an increased landing distance and degraded go-around performance

a reduced landing distance and improved go-around performance

an increased landing distance and improved go-around performance

a reduced landing distance and degraded go around performance

a reduced take-off distance and improved initial climb performance

an increased take-off distance and degraded initial climb performance

an increased take-off distance and improved initial climb performance

a reduced take-off distance and degraded initial climb performance

the increase of altitude to distance over ground expressed as a percentage.

the increase of altitude to horizontal air distance expressed as a percentage.

true airspeed to rate of climb.

rate of climb to true airspeed.

landing gear operating speed.

design low operating speed.

long distance operating speed.

lift off speed.

Straight flight and altitude

Straight flight

Heading, altitude and a positive rate of climb of 100 ft/min

Altitude

an increased acceleration.

a shorter ground roll.

a higher V1.

a longer take-off run.

due to head wind because of the drag augmentation.

due to slush on the runway.

due to downhill slope because of the smaller angle of attack.

due to lower gross mass at take-off.

Maximum range speed decreases and maximum climb angle speed decreases.

Maximum range speed increases and maximum climb angle speed stays constant.

Maximum range speed decreases and maximum climb angle speed increases.

Maximum range speed increases and maximum climb angle speed increases.

the take-off run available.

the accelerate-stop distance available.

the take-off distance available.

the landing distance available.

calculated V2 is less than 110% VMCA and V1, VR, VMCG.

take-off distance equals accelerate-stop distance.

all engine acceleration to V1 and braking distance for rejected take-off are equal.

one engine acceleration from V1 to VLOF plus flare distance between VLOF and 35 feet are
equal.

For a balanced field length the required take-off runway length always equals the available

A balanced field length gives the minimum required field length in the event of an engine failure.

A balanced take-off provides the lowest elevator input force requirement for rotation.

The maximum range for a propeller driven aeroplane.

The maximum range for a jet aeroplane.

The maximum endurance for a propeller driven aeroplane.

The maximum angle of climb for a propeller driven aeroplane.

4500 metres

6000 metres.

4000 metres.

5000 metres.

a chosen limit. If an engine failure is recognized after reaching V1 the take-off must be
aborted.

a chosen limit. If an engine failure is recognized before reaching V1 the take-off must be aborted.

sometimes greater than the rotation speed VR.

not less than V2min, the minimum take-off safety speed.

primary aerodynamic control, nosewheel steering and differential braking.

primary aerodynamic control only.

primary aerodynamic control and nosewheel.

nosewheel steering only.

all engines operating.

only one engine operating.

failure of critical engine or all engines operating which ever gives the largest take off distance.

failure of critical engine.

All Engine Take-off distance

Accelerate Stop Distance

Take-off distance

Take-off run

the accelerate-stop distance available.

the take-off run available.

the take-off distance available.

the distance to reach V1.

the lift-off point.

the middle of the segment between VLOF point and 35 ft point.

the point where V2 is reached.

the point half way between V1 and V2.

The take-off distance required with one engine out at V1 is the shortest.

The safety margin with respect to the runway length is greatest.

The accelerate stop distance required is the shortest.

The climb limited take-off mass is the highest.

horizontal distance along the take-off path from the start of the take-off to a point equidistant between the point at which VLOF is reached and the point at which the aeroplane is 35 ft above the take-off surface.

distance to 35 feet with an engine failure at V1 or 115% all engine distance to 35 feet.

distance to V1 and stop, assuming an engine failure at V1.

Distance from brake release to V2.

An underrun is an area beyond the runway end which can be used for an aborted take-off.

A stopway means an area beyond the take-off runway, able to support the aeroplane during an aborted take-off.

A clearway is an area beyond the runway which can be used for an aborted take-off.

If a clearway or a stopway is used, the liftoff point must be attainable at least at the end of
the permanent runway surface.

Low take-off mass, high flap setting and low field elevation.

Low take-off mass, low flap setting and low field elevation.

High take-off mass, high flap setting and low field elevation.

High take-off mass, low flap setting and high field elevation.

The screen height can be lowered to reduce the mass penalties.

In case of a reverser inoperative the wet runway performance information can still be used.

Screen height cannot be reduced.

When the runway is wet, the V1 reduction is sufficient to maintain the same margins on the runway length.

the horizontal distance along the take-off path from the start of the take-off to a point equidistant between the point at which VLOF is reached and the point at which the aeroplane is 35 ft above the take-off surface.

1.5 times the distance from the point of brake release to a point equidistant between the
point at which VLOF is reached and the point at which the aeroplane attains a height of 35 ft
above the runway with all engines operative.

1.15 times the distance from the point of brake release to the point at which VLOF is
reached assuming a failure of the critical engine at V1.

the distance of the point of brake release to a point equidistant between the point at which
VLOF is reached and the point at which the aeroplane attains a height of 50 ft above the
runway assuming a failure of the critical engine at V1.

No.

No, unless its centerline is on the extended centerline of the runway.

Yes, but the stopway must be able to carry the weight of the aeroplane.

Yes, but the stopway must have the same width as the runway.

VMCG, V1, VR, V2.

V1, VMCG, VR, V2.

V1, VR, VMCG, V2.

V1, VR, V2, VMCA.

V1 is not allowed to be greater than VMCG.

V1 is not allowed to be greater than VR.

When determining the V1, reverse thrust is only allowed to be taken into account on the
remaining symmetric engines.

The V1 correction for up-slope is negative.

V1 and 105% of VMCA.

105% of V1 and VMCA.

1.2 Vs for twin and three engine jet aeroplane.

1.15 Vs for turbo-prop with three or more engines.

1.1 VMCA.

1.15 VMCG.

1.1 VSO.

1.15 VR.

higher than than VR.

equal to or higher than VMCG.

equal to or higher than V2.

equal to or higher than VMCA.

must be higher than V2.

must be higher than VLOF.

is the speed at which rotation to the lift-off angle of attack is initiated.

must be equal to or lower than V1.

hat speed at which the PIC should decide to continue or not the take-off in the case of an
engine failure.

the take-off safety speed.

the lowest airspeed required to retract flaps without stall problems.

the lowest safety airspeed at which the aeroplane is under control with aerodynamic
surfaces in the case of an engine failure.

V1

V2

VMCG

VMCA

lift off speed.

take-off climb speed or speed at 35 ft.

take-off decision speed

critical engine failure speed.

the take-off distance available (TODA), the maximum brake energy and the climb gradient with one engine inoperative.

the maximum brake energy only.

the climb gradient with one engine inoperative only.

the take-off distance available (TODA) only.

the length of the take-off run available plus the length of the clearway available.

the runway length minus stopway.

the runway length plus half of the clearway.

the total runway length, without clearway even if this one exists.

VR may not be lower than V1

V1 may not be higher than Vmcg

When determining V1, reverse thrust may only be used on the remaining symmetric
engine

The correction for up-slope on the balanced V1 is negative

A reduction of screen height is allowed in order to reduce weight penalties

The use of a reduced Vr is sufficient to maitain the same safety margins as for a dry
runway

In case of a reverser inoperative the wet runway performance information can still be used

Screenheight reduction can not be applied because of reduction in obstacle clearance.

reduces V1 and reduces take-off distance required (TODR).

increases V1 and reduces the accelerate stop distance required (ASDR).

reduces V1 and increases the accelerate stop distance required (ASDR).

increases V1 and increases the take-off distance required (TODR).

VMCA increases with increasing pressure altitude.

VMCA is not affected by pressure altitude.

VMCA decreases with increasing pressure altitude.

VMCA increases with pressure altitude higher than 4000 ft.

1.15 Vs for four-engine turboprop aeroplanes and 1.20 Vs for two or three engine turboprop aeroplanes.

1.20 Vs for all turbojet aeroplanes.

1.15 Vs for all turbojet aeroplanes.

1.20 Vs for all turboprop powered aeroplanes.

V1 <= VR

V1 > Vlof

V1 > VR

V1 < VMCG

VR is the lowest climb speed after engine failure.

In case of engine failure below VR the take-off should be aborted.
d) VR is the lowest speed for directional control in case of engine failure.

VR is the speed at which rotation should be initiated.

VR must not be less than 1.1 VMCA and not less than V1.

VR must not be less than 1.05 VMCA and not less than V1.

VR must not be less than VMCA and not less than 1.05 V1.

VR must not be less than 1.05 VMCA and not less than 1.1 V1.

V2 decreases if not restricted by VMCA.

V2 has the same value in both cases.

V2 increases in proportion to the angle at which the flaps are set.

V2 has no connection with T/O flap setting, as it is a function of runway length only.

The VMCG will be lowered to V1.

The ASDR will become greater than the one engine out take-off distance.

The one engine out take-off distance will become greater than the ASDR.

The take-off is not permitted.

reverse engine thrust.

reduce the engine thrust.

apply wheel brakes.

deploy airbrakes or spoilers.

In the accelerate stop distance available.

In the one-engine failure case, take-off distance.

In the all-engine take-off distance.

In the take-off run available.

The field length limited take-off mass will increase.

V1 is increased.

V1 remains constant.

The usable length of the clearway is not limited.

if the accelerate stop distance is equal to the one engine out take-off distance.

for a runway length limited take-off with a stopway to give the highest mass.

for a runway length limited take-off with a clearway to give the highest mass.

if it is equal to V2.

The accelerate stop distance is equal to the take-off distance available.

The clearway does not equal the stopway.

The accelerate stop distance is equal to the all engine take-off distance.

The one engine out take-off distance is equal to the all engine take-off distance.

a greater field length limited take off mass but with a lower V1

a greater field length limited take off mass but with a higher V1

the obstacle clearance limit to be increased with no effect on V1

the obstacle clearance limit to be increased with an higher V1

increases the field length limited take-off mass.

decreases the brake energy limited take-off mass.

increases the climb limited take-off mass.

decreases the take-off distance.

the minimum vertical distance between the lowest part of the aeroplane and all obstacles within the obstacle corridor.

based on pressure altitudes.

the height by which acceleration and flap retraction should be completed.

the height at which power is reduced to maximum climb thrust.

the failure of the critical engine on a multi-engines aeroplane.

the failure of any engine on a multi-engined aeroplane.

2 engined aeroplane.

the failure of two engines on a multi-engined aeroplane.

400 ft above field elevation.

35 ft above ground.

When gear retraction is completed.

1500 ft above field elevation.

when landing gear is fully retracted.

when flap retraction begins.

when flaps are selected up.

when acceleration starts from V2 to the speed for flap retraction.

by banking not more than 15° between 50 ft and 400 ft above the runway elevation.

by banking as much as needed if aeroplane is more than 50 ft above runway elevation.

only by using standard turns.

by standard turns - but only after passing 1500 ft.

at completion of gear retraction.

at completion of flap retraction.

at reaching V2.

at 35 ft above the runway.

a lower flap setting for take-off and selecting a higher V2.

selecting a lower V1.

selecting a lower V2.

selecting a lower VR.

when acceleration to flap retraction speed is started.

when landing gear is fully retracted.

when acceleration starts from VLOF to V2.

when flap retraction is completed.

The minimum value according to regulations is 1000 ft.

A lower height than 400 ft is allowed in special circumstances e.g. noise abatement.

There is no legal minimum value, because this will be determined from case to case during the calculation of the net flight path.

The minimum value according to regulations is 400 ft.

The maximum acceleration height depends on the maximum time take-off thrust may be applied.

The minimum legally allowed acceleration height is at 1500 ft.

There is no requirement for minimum climb performance when flying at the accelerationheight

The minimum one engine out acceleration height must be maintained in case of all engines
operating.

decreases / remains constant.

increases / increases.

remains constant / remains constant.

decreases / decreases.

15 degrees up to height of 400 ft.

10 degrees up to a height of 400 ft.

20 degrees up to a height of 400 ft.

25 degrees up to a height of 400 ft.

The speed for which the ratio between rate of climb and forward speed is maximum.

V2 + 10 kt.

V2.

The speed for maximum rate of climb.

lower.

higher

unchanged.

only affected by the aeroplane gross mass.

TAS decreases.

TAS increases.

TAS is constant.

TAS is not related to Mach Number.

The highest CL/CD ratio.

The highest CL/CD² ratio.

1.2 Vs

1.1 Vs

Vs, maximum range speed, maximum angle climb speed.

Vs, maximum angle climb speed, maximum range speed.

Maximum endurance speed, maximum range speed, maximum angle of climb speed.

Maximum endurance speed, long range speed, maximum range speed.

IAS decreases and TAS decreases.

IAS increases and TAS increases.

The lift coefficient increases.

The TAS continues to increase, which may lead to structural problems.

IAS stays constant so there will be no problems.

The ""1.3G"" altitude is exceeded, so Mach buffet will start immediately.

The Maximum operating Mach number.

The Stalling speed.

The Minimum control speed air.

The Mach limit for the Mach trim system.

improves the maximum range.

increases the stalling speed.

improves the longitudinal stabiity.

decreases the maximum range.

60 minutes flying time in still air at the approved one engine out cruise speed.

60 minutes flying time in still air at the normal cruising speed.

30 minutes flying time at the normal cruising speed.

75 minutes flying time at the approved one engine out cruise speed.

Maximum Operating Speed

Never Exceed Speed

High Speed Buffet Limit

Maximum Operational Mach Number

When determining the maximum allowable landing mass at destination, 60% of the available distance is taken into account, if the runway is expected to be dry.

In any case runway slope is one of the factors taken into account when determining the required landing field length.

An anti-skid system malfunction has no effect on the required landing field length.

The required landing field length is the distance from 35 ft to the full stop point.

Maximum Landing Distance at the destination aerodrome and at any alternate aerodrome is 0,7 x LDA (Landing Distance Available).

Maximum Landing Distance at destination is 0,95 x LDA (Landing Distance Available).

Maximum Take-off Run is 0,5 x runway.

Maximum use of clearway is 1,5 x runway

92%

70%

43%

67%

92%

43%

0.60

115/100

1.67

60/115

7 000 kg

2 700 kg

5 700 kg

NOTAM and AIP (Air Information Publication)

Only AIP (Air Information Publication)

SIGMET

RAD/NAV charts

is of the highest wake turbulence category

has a certified landing mass greater than or equal to 136 000 kg

has a certified take-off mass greater than or equal to 140 000 kg

requires a runway length of at least 2 000m at maximum certified take-off mass

Blood fat.

Hemoglobin in the red blood cells.

Plasma.

White blood cells

talk oneself through the relevant procedure aloud to emotionally calm down and reduce the rate of breathing simultaneously

don an oxygen mask

excecute the valsalva manoeuvre

close the eyes and relax

nitrogen gas bubbles can be released in the body fluids causing gas embolism, bends and chokes

automatically oxygen is deployed into the cabin

temperature in the cockpit will increase

pressure differentials will suck air into the cabin

Dizzy feeling

Slow heart beat

Slow rate of breathing

Cyanosis (blueing of lips and finger nails)

1,2 and 3 are correct, 4 is false

1,2 and 4 are correct, 3 is false

1 is false, all others are correct

2 and 4 are false

between 30 and 60 seconds

approximately 3 minutes

approximately 5 minutes

less than 20 seconds

are forbidden

can be performed without any danger

are allowed, if 38000 FT are not exceeded

should be avoided because hypoxia may develop

30 -90 seconds

10-15 seconds

3-4 minutes

5 minutes or more

can cause decompression sicknesss even when flying at pressure altitudes below 18 000 FT

prevents any dangers caused by aeroembolism (decompression sickness) when climbing to altitudes not exceeding 30 000 FT

has no influence on altitude flights

is forbidden for the flight crew, because it leads to hypoxia

24 hours

3 hours after non decompression diving

36 hours after any scuba diving

48 hours after a continuous ascent in the water has been made

a lack of carbon dioxide in the blood

an excess of carbon dioxide in the blood

acidosis

hypochondria

bends

chokes

creeps

leans

1,3 and 4 are correct

1,2,3 and 4 are correct

1,2 and 3 are correct

1,2 and 4 are correct

a normal compensatory physiological reaction to a drop in partial oxygen pressure (i.e. when climbing a high mountain)

an accellerated heart frequency caused by an increasing blood pressure

an accellerated heart frequency caused by a decreasing blood-pressure

a reduction of partial oxygen pressure in the brain

About 12 seconds

Between 20 seconds and 1 minute

About 40 secods

More than 1 minute

Between 3 and 5 minutes depending on the physical activities of the subjected pilot

About 18 seconds

Between 25 seconds and 1 minute 30 seconds

About 30 seconds

surplus of CO2 in the blood

surplus of O2 in the blood

shortage of CO in the blood

shortage of CO2 in the blood

creeps

chokes

leans

bends

creeps

chokes

bends

1 to 2 minutes

3 to 5 minutes

5 to 10 minutes

10 to 12 minutes

30 to 60 seconds

15 seconds or less

5 minutes.

10 minutes.

24 hours

6 hours

12 hours

48 hours

decompression sickness without having a decompression

hyperventilation

hypoxia

stress

carbon dioxide in the blood

nitrogen in the air

water vapour in the alveoli

oxygen in the cells

Problems in the personal relation between crew members very likely hamper their communication process.

There is no relation between inadequate communication and incidents or accidents.

Inconsistent communication behaviour improves flight safety.

Problems in the personal relation between crew members hardly hamper their communication process.

It increases fatigue, concentration and attention difficulties, the risk of sensory illusions and mood disorders

It increases fatigue and concentration difficulties, but facilitates stress management by muscular relaxation,

It causes muscular spasms

It reduces concentration and fatigue only with sleep loss greater than 48 hours

It separates the troposphere from the stratosphere

It is, by definition, an isothermal layer

It indicates a strong temperature lapse rate

It is, by definition, a temperature inversion

FL 80

FL 20

FL 100

FL 110

+7°C

+3°C

0°C

-3°C

has a fixed value of 1°C/100m

varies with time

has a fixed value of 0.65°C/100m

has a fixed value of 2°C/1000 FT

At standard temperature.

At sea level when the temperature is 0°C.

When the altimeter has no position error.

When the altimeter setting is 1013,2 hPa.

-56.5°C

-273°C

-44.7°C

-100°C

FL 110

FL 130

FL 150

FL 90

ISA -20°C

ISA +/-0°C

ISA +20°C

ISA +12°C

19340 feet

20660 feet

21740 feet

18260 feet

1375 FT.

1200 FT

1105 FT.

1280 FT.

It will decrease

It will increase

It will remain the same

It is not possible to give a definitive answer

the elevation = 0

T actual = T standard

T actual > T standard

T actual < T standard

160 metres

600 metres

540 metres

120 metres

The temperature to which a mass of air must be cooled in order to reach saturation.

The temperature at which the relative humidity and saturation vapour pressure are the
same.

The freezing level (danger of icing).

The temperature at which ice melts.

It increases with increasing water vapour.

It is not influenced by changing water vapour.

It decreases with increasing water vapour.

It is only influenced by temperature.

changes when water vapour is added, even though the temperature remains constant.

is not affected when air is ascending or descending.

is not affected by temperature changes of the air.

does not change when water vapour is added provided the temperature of the air remains
constant.

It can only be equal to, or lower, than the temperature of the air mass

It can be higher than the temperature of the air mass

It can be used to estimate the air mass's relative humidity even if the air temperature is
unknown

It can be used together with the air pressure to estimate the air mass's relative humidity

increases if the air is cooled whilst maintaining the vapour pressure constant

is higher in warm air than in cool air

is higher in cool air than in warm air

decreases if the air is cooled whilst maintaining the vapour pressure constant

the temperature to which moist air must be cooled to become saturated at a given pressure

the lowest temperature at which evaporation will occur for a given pressure

the lowest temperature to which air must be cooled in order to reduce the relative humidity

the temperature below which the change of state in a given volume of air will result in the
absorption of latent heat

actual water vapour content and saturated water vapour content

water vapour weight and dry air weight

water vapour weight and humid air volume

dew point and air temperature

Solid direct to vapour

Solid direct to liquid

Liquid direct to solid

Liquid direct to vapour

Through water vapour released during fuel combustion

Through a decrease in pressure, and the associated adiabatic drop in temperature at the wing tips while flying through relatively warm but humid air

Only through unburnt fuel in the exhaust gases

In conditions of low humidity, through the particles of soot contained in the exhaust gases

at a temperature below freezing

small and at a temperature below freezing

large and at a temperature below freezing

at a temperature below -60°C

a droplet still in liquid state at a temperature below freezing

a water droplet that is mainly frozen

a small particle of water at a temperature below -50°C

a water droplet that has been frozen during its descent

remains liquid at a below freezing temperature

has frozen to become an ice pellet

has a shell of ice with water inside it

is at an above freezing temperature in below freezing air

CU, CB.

ST, CS.

SC, NS.

CI, SC.

AS

CS

ST

SC

water or ice particles falling out of a cloud that evaporate before reaching the
ground

strong downdraughts in the polar jet stream, associated with jet streaks

gusts associated with a well developed Bora

strong katabatic winds in mountainous areas and accompanied by heavy precipitation

medium level clouds (ALSO CALLED ALTO CUMULUS)

low level clouds

high level clouds

convective clouds

presence of mountain waves

risk of orographic thunderstorms

development of thermal lows

presence of valley winds

Rain falls through a layer where temperatures are below 0°C

Rain falls on cold ground and then freezes

Through melting of sleet grains

Through melting of ice crystals

CB

NS

CS

AC

rain falls into a layer of air with temperatures below 0°C

ice pellets melt

water vapour first turns into water droplets

snow falls into an above-freezing layer of air

Cold front.

Warm front.

Cold occlusion.

Warm occlusion.

0° - 7°N.

3° - 8°S.

8° - 12°S.

7° - 12°N.

vertical variation in the horizontal wind

vertical variation in the vertical wind

horizontal variation in the horizontal wind

horizontal variation in the vertical wind

Dissipating stage

Cumulus stage

Mature stage

Anvil stage

4 km

400 m

20 km

50 km

1 to 5 minutes.

Less than 1 minute.

1 to 2 hours.

About 30 minutes.

true north

magnetic north

the 0-meridian

grid north

An aerodrome forecast valid for 9 hours

A landing forecast appended to METAR/SPECI, valid for 2 hours

A route forecast valid for 24 hours

A routine report

5-7 Eights of the sky is cloud covered

3-4 Eights of the sky is cloud covered

3-5 Eights of the sky is cloud covered

Nil significant cloud cover

120° / 15 kt gusts 25 kt

140° / 10 kt

300° / 15 kt maximum wind 25 kt

250° / 20 kt

60 minutes.

120 minutes.