ATP EASA Qatar Yellow 2

65200 kg.

78000 kg

79000 kg

93000 kg

35 kg for children over 2 years occupying a seat and 10 kg for infants (less than 2 years)
occupying a seat.

35 kg for children over 2 years occupying a seat and 10 kg for infants (less than 2 years)
not occupying a seat.

35 kg irrespective of age provided they occupy a seat.

35 kg only if they are over 2 years old and occupy a seat.

35 kg irrespective of age provided they occupy a seat

35 kg only if they are over 2 years old and occupy a seat.

35 kg for children over 2 years occupying a seat and 10 kg for infants (less than 2 years)
occupying a seat.

35 kg for children over 2 years occupying a seat and 10 kg for infants (less than 2 years)
not occupying a seat.

76 kg

84 kg

84 kg (male) 76 kg (female).

88 kg (male) 74 kg (female).

35 kg for holiday charters and 38 kg for all other flights.

38 kg for all flights.

35 kg for all flights.

30 kg for holiday charters and 35 kg for all other flights.

flight crew 85 kg., cabin crew 75 kg. each. These do not include a hand baggage
allowance.
c) flight crew (male) 88 kg. (female) 75 kg., cabin crew 75 kg. each. These include an
allowance for hand baggage.

flight crew (male) 88 kg. (female) 75 kg., cabin crew 75 kg. each. These do not include an
allowance for hand baggage.p

light crew 85 kg., cabin crew 75 kg. each. These are inclusive of a hand
baggage allowance.

flight crew (male) 88 kg. (female) 75 kg., cabin crew 75 kg. each. These include an
allowance for hand baggage.

Dry Operating Mass plus the take-off fuel

Dry Operating Mass plus take-off fuel and the traffic load

Actual Zero Fuel Mass plus the traffic load

Actual Landing Mass plus the take-off fuel

Zero Fuel Mass minus Dry Operating Mass

Dry Operating Mass minus the disposable load

Take-off Mass minus Zero Fuel Mass.

Dry Operating Mass minus the variable load.

the revenue-earning portion of traffic load only.

traffic load plus useable fuel.

the revenue-earning portion of traffic load plus useable fuel.

traffic load only.

29280 kg.

17080 kg

12200 kg.

10080 kg.

18 900 kg

32 100 kg

32 900 kg

40 400 kg

25 000 kg

25 800 kg

55 000 kg

55 800 kg

1 550 kg

1 600 kg

2 150 kg

2 200 kg

53 000 kg

64 000 kg

71 000 kg

99 000 kg

in a quiet parking area clear of the normal manoeuvring area.

at a specified 'weighing location' on the airfield.

in an enclosed, non-air conditioned, hangar

in an area of the airfield set aside for maintenance

at intervals of 4 years if no modifications have taken place.

at regular annual intervals.

at intervals of 9 years.

only if major modifications have taken place.

Take-off Fuel Mass

Ramp Fuel Mass.

rip Fuel Mass.

Ramp Fuel Mass less the fuel for APU and run-up.

9 300 kg

12 900 kg

13 300 kg

14 600 kg

47 800 kg

48 000 kg

48 400 kg

53 000 kg

17 810 kg

21 070 kg

20 420 kg

21 170 kg

54 000 kg

55 000 kg

55 500 kg

61 500 kg

Maximum landing mass augmented by fuel on board at take-off.

Maximum zero fuel mass augmented by the fuel burn.

Maximum landing mass augmented by the fuel burn.

Maximum take-off mass decreased by the fuel burn.

lighter than anticipated and the calculated safety speeds will be too high

lighter than anticipated and the calculated safety speeds will be too low

heavier than anticipated and the calculated safety speeds will be too high

heavier than anticipated and the calculated safety speeds will be too low.

Gradient of climb for a given power setting will be higher.

Flight endurance will be increased.

Stalling speeds will be higher.

Stalling speeds will be lower.

remain constant, drag will decrease and endurance will decrease.

remain constant, drag will increase and endurance will increase.

be decreased, drag will decrease and endurance will increase.

be greater, drag will increase and endurance will decrease.

increased to 202 knots but, since the same angle of attack is used, drag and range will
remain the same.

unaffected as Vs always occurs at the same angle of attack.

increased to 191 knots, drag will increase and air distance per kg of fuel will
decrease

increased to 191 knots, drag will decrease and air distance per kg of fuel will increase.

at or near the focal point of the aeroplane axis system.

at or near the natural balance point of the empty aeroplane.

at or near the forward limit of the centre of gravity.

at a convenient point which may not physically be on the aeroplane.

30000 Nm

50000 Nm

80000 Nm

130000 Nmg

62.5 kg.

65.8 kg.

68.9 kg.

73.5 kg.

104 kg

110 kg

165 kg

183 kg

is the airspeed of the aeroplane upon reaching 35 feet above the take-off surface.

is an airspeed at which the aeroplane is airborne but below 35 ft and the pilot is assumed to
have made a decision to continue or discontinue the take-off .

is the airspeed on the ground at which the pilot is assumed to have made a
decision to continue or discontinue the take-off.

is always equal to VEF (Engine Failure speed).

Induced drag decreases with increasing speed.

nduced drag increases with increasing speed.

Induced drag is independant of the speed.

Induced drag decreases with increasing angle of attack.

safety speed for take-off in case of a contaminated runway.

stalling speed or minimum steady flight speed at which the aeroplane is
controllable.

design stress speed

speed for best specific range.

increasing the CAS.

increasing the angle of attack.

increasing the TAS.

decreasing the 'nose-up' elevator trim setting.

VS

VS1

VSO

VMC

is approximately climb gradient times true airspeed divided by 100.

is the downhill component of the true airspeed.

is the horizontal component of the true airspeed

is angle of climb times true airspeed.

the radius of the turn and the bank angle.

the true airspeed and the bank angle.

the bank angle only.

the radius of the turn and the weight of the aeroplane.

decreases with increasing gross weight.

decreases with increasing airspeed.

is independent of the airspeed.

increases with increasing airspeed

VSO (stalling speed in landing configuration)

VS1 (stalling speed in clean configuration)

VMO (maximum operating limit speed)

VA (design manoeuvring speed)

a reduced take-off distance and improved initial climb performance

an increases 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 performance0

increases the angle of climb but decreases the rate of climb.

does not have any noticeable effect on climb performance.

reduces the angle and the rate of climb.

reduces the angle of climb but increases the rate of climb.

increases the angle of climb but decreases the rate of climb.

does not have any noticeable effect on climb performance.

reduces the angle and the rate of climb.

reduces the angle of climb but increases the rate of climb.

does not have any effect on the angle of flight path during climb.

improves angle and rate of climb.

has no effect on rate of climb.

decreases angle and rate of climb.

Tailwind only effects holding speed.

The IAS will be increased.

The IAS will be decreased.

No affect

increases the power required because of the greater drag caused by the
windmilling engine and the compensation for the yaw effect

does not affect the aeroplane performance since it is independent of the power plant.

decreases the power required because of the lower drag caused by the windmilling engine.

increases the power required and decreases the total drag due to the windmilling engine.

take-off climb speed.

speed for best angle of climb.

take-off decision speed.

engine failure speed.

the speed for best rate of climb.

the speed for best angle of climb.

the speed for best specific range.

the speed for best angle of flight path.

VX.

VY.

V2

VO

Lift-off IAS.

Lift-off TAS.

Lift-off groundspeed.

Lift-off EAS.

High temperature and low relative humidity

Low temperature and low relative humidity

High temperature and high relative humidity

Low temperature and high relative humidity

decreases the take-off speed V1.

decreases the TAS for take-off.

increases the IAS for take-off.

has no effect on the take-off speed V1.

lower.

higher.

unaffected.

only higher for three and four engine aeroplanes.

Airport elevation, runway slope, standard temperature, standard pressure and wind
components.

Airport elevation, runway slope, standard temperature, pressure altitude and wind
components.

Airport elevation, runway slope, outside air temperature, pressure altitude and
wind components.

Airport elevation, runway slope, outside air temperature, standard pressure and wind
components.

decreases the field length limited take-off mass.

increases the climb limited take-off mass.

decreases the take-off distance.

has no influence on the allowed take-off mass.

a reduced landing distance and degraded go-around performance

a reduced landing distance and better go-around performance

an increased landing distance and degraded go-around performance

an increased landing distance and better go-around performance

5%

10%

15%

20%

T - W sin GAMMA = D

T - D = W sin GAMMA

T + W sin GAMMA = D

T + D = - W sin GAMMA

increases / increases / decreases

decreases / constant / decreases

increases / increases / constant

increases / constant / increases

Decrease of aircraft mass

Increase of aircraft mass.

Tailwind.

Headwind.

Low mass

High mass.

Headwind.

Tailwind.

The maximum thrust is equal to the total drag

The thrust is equal to the maximum drag.

The thrust is equal to minimum drag

The thrust does not increase further with increasing speed.

The lift coefficient decreases with increasing altitude.

The lift coefficient increases with increasing altitude.

The lift coefficient is independant of altitude

Only at low speeds the lift coefficient decreases with increasing altitude

decreases as mass decreases.

is the altitude at which the specific range reaches its minimum

increases as mass decreases and is the altitude at which the specific range
reaches its maximum.

is the altitude up to which cabin pressure of 8 000 ft can be maintained

can be reached only with minimim steady flight speed

is the altitude at which the rate of climb theoretically is zero.

is the altitude at which the best climb gradient attainable is 5%

is the altitude at which the aeroplane reaches a maximum rate of climb of 100 ft/min.

less than 4 000 m.

higher than 4 000 m.

unchanged, equal to 4 000 m.

only a new performance analysis will determine if the service ceiling is higher or lower than
4 000 m.¹úw

Increased pressure altitude, increased outside air temperature, increased take-off mass.

Decreased take-off mass, increased density, increased flap setting.

Decreased take-off mass, increased pressure altitude, increased temperature.

Increased outside air temperature, decreased pressure altitude, decreased flap setting.

1547 m.

1720 m.

1779 m.

1978 m.

The climb limited take-off mass increases when a larger take-off flap setting is used

The performance limited take-off mass is the highest of:field length limited take-off
massclimb limited take-off massobstacle limited take-off mass.

The climb limited take-off mass depends on pressure altitude and outer air
temperature

The climb limited take-off mass will increase if the headwind component increases.

10%

15%

20%

30%

The one engine out take-off distance required may exceed the take-off distance available.

V2 may be too high so that climb performance decreases.

It may lead to over-rotation.

The stop distance required will exceed the stop distance available.

VR is the speed at which the pilot should start to rotate the aeroplane.

VR should not be higher than V1.

VR should not be higher than 1.05 VMCG.

VR is the speed at which, during rotation, the nose wheel comes off the runway.

(i) V1 (ii) 2 seconds (iii) Take-off distance available.

(i) V1 (ii) 1 second (iii) Accelerate - stop distance available.

(i) V1 (ii) 2 seconds (iii) Accelerate - stop distance available.

(i) V2 (ii) 3 seconds (iii) Take-off distance available.

Straight flight can not be maintained below VMCA, when the critical engine has
failed.

The aeroplane is uncontrollable below VMCA

The aeroplane will not gather the minimum required climb gradient

VMCA only applies to four-engine aeroplanes

Inoperative anti-skid.

Increased take-off mass.

Inoperative flight management system.

Increased outside air temperature.

the take-off may be continued if a clearway is available.

the take-off should only be rejected if a stopway is available.

the take-off must be rejected.

the take-off is to be continued unless V1 is less than the balanced V1.

the take-off must be rejected if the speed is still below VLOF

a height of 50 ft must be reached within the take-off distance.

the take-off must be continued.

the take-off should be rejected if the speed is still below VR.

Allowable take-off mass is not affected by runway slope.

A downhill slope increases allowable take-off mass.

A downhill slope decreases allowable take-off mass.

An uphill slope increases take-off mass

increases the take-off distance more than the accelerate stop distance.

decreases the accelerate stop distance only.

decreases the take-off distance only.

increases the allowed take-off mass.

Increased TOD required and increased field length limited TOM.

Decreased TOD required and decreased field length limited TOM.

Decreased TOD required and increased field length limited TOM.

Increased TOD required and decreased field length limited TOM.

windshear is reported on the take-off path.

it is dark.

he runway is dry.

the runway is wet

the runway is contaminated.

it is dark.

the runway is wet

obstacles are present close to the end of the runway

Increased TOD required and increased field length limited TOM.

Decreased TOD required and increased field length limited TOM.

Increased TOD required and decreased field length limited TOM.

Decreased TOD required and decreased field length limited TOM

Reduced thrust can be used when the actual take-off mass is less than the field
length limited take-off mass.

Reduced thrust is primarily a noise abatement procedure.

In case of reduced thrust V1 should be decreased.

Reduced thrust is used in order to save fuel.

can be used if the actual take-off mass is higher than the performance limited take-off
mass.

is not recommended at very low temperatures (OAT).

can be used if the headwind component during take-off is at least 10 kt.
;

has the benefit of improving engine life.

It will increase the take-off distance required.

It will decrease the take-off distance required.

It will increase the accelerate stop distance.

It will increase the take-off ground run.

It will decrease the take-off distance.

It will increase the take-off distance.

It will increase the take-off distance available.

It will increase the accelerate stop distance available.

Allowable take-off mass increases.

There is no effect on allowable take-off mass.

Allowable take-off mass decreases.

Allowable take-off mass remains uninfluenced up to 5000 ft PA.

he greater the depth of contamination at constant take-off mass, the more V1 has to be
decreased to compensate for decreasing friction.

The performance data for take-off must be determined in general by means of
calculation, only a few values are verified by flight tests.

Dry snow is not considered to affect the take-off performance

A slush covered runway must be cleared before take-off, even if the performance data for
contaminated runway is available

VR

VMCA

VREF

V2

The accelerate stop distance decreases.

Take-off with antiskid inoperative is not permitted.

The accelerate stop distance increases.

It has no effect on the accelerate stop distance

Because overheated brakes will not perform adequately in the event of a
rejected take-off.

To ensure that the brake wear is not excessive.

To ensure that the wheels have warmed up evenly.

o ensure that the thermal blow-out plugs are not melted.

A low runway elevation and a cross wind.

A high runway elevation and a head wind.

A high runway elevation and tail wind.

A low runway elevation and a head wind.

VR, or VMU if this is lower than VR.

VLOF in terms of ground speed.

V1 in kt TAS.

V1 in kt ground speed.

1, 4, 6, 9

1, 4, 5, 10

2, 3, 6, 9

1, 5, 8, 10

The climb limited take-off mass is determined at the speed for best rate of climb

The climb limited take-off mass decreases with increasing OAT.

On high elevation airports equipped with long runways the aeroplane will always be climb
limited.\x

50% of a head wind is taken into account when determining the climb limited take-off
mass

102150 kg

118455 kg

121310 kg

106425 kg

0.125D

-90m + 1.125D

90m + 0.125D

90m + D/0.125

Remain constant / decrease.

Reduce / decrease.

Reduce / remain constant.

Remain constant / become larger

VX is sometimes below and sometimes above VY depending on altitude.

VX is always above VY.

VX is always below VY.

VY is always above VMO.

Aerodynamics.

Theoretical ceiling.

Service ceiling.

Economy

is dependent on the OAT.

is dependent on aerodynamic ceiling.

is the highest pressure altitude certified for normal operation

is only certified for four-engine aeroplanes.

Step climbs do not have any special purpose for jet aeroplanes, they are used for piston engine aeroplanes only

To respect ATC flight level constraints

To fly as close as possible to the optimum altitude as aeroplane mass reduces.

Step climbs are only justified if at the higher altitude less headwind or more tailwind can be
expected

Increases.

Decreases.

Does not change.

Increases only if there is no wind

a 1% higher TAS for maximum specific range.

an IAS which is 1% higher than the IAS for maximum specific range.

a specific range which is about 99% of maximum specific range and higher
cruise speed

a specific range which is 99% of maximum specific range and a lower cruise speed

3804 kg/h

3365 kg/h.

4044 kg/h

3578 kg/h.

Increase / decrease.

Increase / increase.

Decrease / increase

Decrease / decrease

Maximum range.

Maximum endurance.

Holding.

Long range.

In order to achieve speed stability.

he aircraft can be operated close to the buffet onset speed

In order to prevent loss of speed stability and tuck-under.

It is efficient to fly slightly faster than with maximum range speed

can be flown in a steady climb only.

can be reached with the 'best rate of climb' speed in level flight

is achieved in unaccelerated level flight with minimum fuel consumption.

is the same as maximum specific range with wind correction

decreases the induced drag and reduces the power required.

increases the power required.

increases the induced drag.

affects neither drag nor power required.

decreases with increasing mass and is independent of altitude.

is only limiting at low altitudes

narrows with increasing mass and increasing altitude

increases with increasing mass

limits the maneuvering load factor at high altitudes.

can be reduced by increasing the load factor.

has to be considered at take-off and landing.?

exists only above MMO.

the pressure altitude at which the best specific range can be achieved

the pressure altitude at which the fuel flow is a maximum

the pressure altitude up to which a cabin altitude of 8000 ft can be maintained.

the pressure altitude at which the speed for high speed buffet as TAS is a maximum.

if the temperature (OAT) is increased

if the aeroplane mass is decreased.

if the aeroplane mass is increased

if the tailwind component is decreased.

the IAS for long range cruise increases continuously with decreasing altitude

the TAS for long range cruise increases continuously with decreasing altitude.

the Mach number for long range cruise decreases continuously with decreasing
altitude

the Mach number for long range cruise increases continuously with decreasing altitude

If at the lower altitude either considerably less headwind or considerably more
tailwind can be expected.

If the maximum altitude is below the optimum altitude

If the temperature is lower at the low altitude (high altitude inversion).

If at the lower altitude either more headwind or less tailwind can be expected.

The speed must be increased to compensate the lower mass.

The specific range and the optimum altitude increases

The specific range increases and the optimum altitude decreases.

The specific range decreases and the optimum altitude increases

the aeroplane descends if the airspeed is maintained.

the aeroplane decelerates if it is in the region of reversed command

the aeroplane accelerates if the altitude is maintained.

the aeroplane decelerates if the altitude is maintained.

180 minutes flying time to a suitable airport in still air with one engine
inoperative.

180 minutes flying time to a suitable airport under the prevailing weather condition with
one engine inoperative

180 minutes flying time from suitable airport in still air at a normal cruising speed

90 minutes flying time from the first enroute airport and another 90 minutes from the
second enroute airport in still air with one engine inoperative.

of greatest lift-to-drag ratio.

giving the lowest Cl/Cd ratio.

for long-range cruise.

giving the highest Cd/Cl ratio.

the obstacle clearance during a descent to the new cruising altitude if an engine
has failed.

the actual engine thrust output at the altitude of engine failure.

the maximum flight path gradient during the descent.

the landing mass limit at the alternate

the critical Mach number.

the minimum drag

the maximum lift

the minimum angle of descent

ETOPS.

Drift Down Procedure

Emergency Descent Procedure.

Long Range Cruise Descent

to conduct an instrument approach at the alternate

to conduct a visual approach if VASI is available

after engine failure if the aeroplane is above the one engine out maximum
altitude

after cabin depressurization

obstacle clearance during descent to the net level-off altitude

engine power at the altitude at which engine failure occurs

climb gradient during the descent to the net level-off altitude

weight during landing at the alternate

decrease

increaseincrease at first and decrease later on

increase at first and decrease later on

remain constant

Increases in the first part, decreases in the second

Increases in the first part, is constant in the second.

Decreases in the first part, increases in the second

Is constant in the first part, decreases in the second.

The higher the gross mass the greater is the speed for descent

The higher the gross mass the lower is the speed for descent.

The mass of an aeroplane does not have any effect on the speed for descent.

The higher the average temperature (OAT) the lower is the speed for descent.

A tailwind component increases the ground distance

A headwind component increases the ground distance

A tailwind component decreases the ground distance

A tailwind component increases fuel and time to descent.

minimum climb gradient in the event of a go-around with one engine
inoperative.

manoeuverability in the event of landing with one engine inoperative.

manoeuverability during approach with full flaps and gear down, all engines operating.

obstacle clearance in the approach area.

use maximum reverse thrust, and should start braking below the hydroplaning speed.

postpone the landing until the risk of hydroplaning no longer exists.

make a ""positive"" landing and apply maximum reverse thrust and brakes as
quickly as possible

use normal landing-, braking- and reverse technique.

Increasing VREF

Keeping same VREF because wind has no influence on IAS.

Lowering VREF

Increasing VREF and making a steeper glide path to avoid the use of spoilers.

1,05 VSO

1,30 VSO

1,10 VSO

VMCA x 1,2

the climb requirements with one engine inoperative in the landing configuration

the climb requirements with all engines in the approach configuration.

the climb requirements with all engines in the landing configuration but with gear up.

the climb requirements with one engine inoperative in the approach
configuration

manoeuvrability in case of landing with one engine inoperative.

obstacle clearance in the approach area.

minimum climb gradient in case of a go-around with one engine inoperative.

manoeuvrability during approach with full flaps and gear down, all engines operating

500 ft above the heighest obstacle

the heighest obstacle.

1000 ft above the heighest obstacle within a radius of 600 m from the aircraft.

2000 ft above the heighest obstacle within a radius of 600 ft from the aircraft.

2h 35min

3h 00min

2h 10min

2h 32min

193 NM

228 NM

157 NM

128 NM

1000 kg

700 kg

800 kg

500 kg

200 kg/h

213 kg/h

267 kg/h

188 kg/h

110 NM

130 NM

140 NM

120 NM

42093 kg.

42210 kg.

42195 kg.

42312 kg.

30 minutes holding 1,500 feet above aerodrome B

15 minutes holding 2,000 feet above aerodrome A

30 minutes holding 1,500 feeI above aerodrome A

30 minutes holding 2,000 feet above aerodrome B

At the destination there will still be 30 US gallons in the tanks

The remaining fuel is not sufficient to reach the destination with reserves intact

At departure the reserve fuel was 28 US gallons

At destination the required reserves remain intact.cep

filed flight plan.

filed flight plan with amendments and clearance included.

flight plan with the correct time of departure.

flight plan in the course of which radio communication should be practised between
aeroplane and ATC.

estimated time over the first point en route

estimated take-off time

estimated off-block time

allocated slot time

IAS

TAS

CAS

Groundspeed

heavy ""H""

heavy/medium ""H/M""

medium ""M""

medium plus ""M+""

medium ""M""

heavy ""H""

light ""L""

unclassified ""U""

Central European Time

local standard time

UTC

Local mean time

estimated take-off mass

maximum certified take-off mass

maximum certified landing mass

actual take-off mass

the required fuel for the flight plus the alternate and 45 minutes

the total usable fuel on board

the required fuel for the flight

the total usable fuel on board minus reserve fuel

1h 35min

2h 04min

2h 52min

2h 49min

1:00 hour.

0:30 hours.

0:10 hours.

3:00 hours.

the time of take-off.

the estimated off-block time

the time at which the flight plan is filed.

the time overhead the first reporting point after take-off.

1+5

2+4

1+2+3

3+4+5

30 minutes or more

45 minutes or more

60 minutes or more

90 minutes or more

174 NM

203 NM

193 NM

188 NM

Temperature/dewpoint

runway in use

period of validity

day/month

the minimum obstruction clearance altitude (MOCA) is 3500 ft

the airway base is 3500 ft MSL

The minimum enroute altitude (MEA) is 3500 ft

the airway is a low level link route 2100 ft - 3500 ft MSL

1500 ft MSL is the minimum radio reception altitude (MRA).

the airway base is 1500 ft MSL.

the minimum enroute altitude (MEA) is FL 80.

the airways extends from 1500 ft MSL to FL 80.

minimum enroute altitude (MEA)

maximum authorised altitude (MAA)

minimum holding altitude (MHA)

base of the airway (AGL)
base of the airway (AGL)

magnetic headings

true course

magnetic course

true headings

NOTAM

AIP (Air Information Publication)

SIGMET

ATCC broadcasts

ATCC broadcasts

SIGMET

NOTAM

AIP (Air Information Publication)

NAV/RAD charts

AIP (Air Information Publication)

ATCC

NOTAM

the minimum safe altitude is 8 000 ft

the minimum flight level is FL 80

the altitude of the highest obstacle is 8 000 ft

the floor of the airway is at 8 000 ft

20 NM

10 NM

25 NM

15 NM

30 min

45 min

60 min

Variable with wind velocity.

To increase the safety of the flight.

To reduce the landing weight and thus reduce the structural stress on the aircraft.

To reduce the minimum required fuel and therefore be able to increase the
traffic load.

To increase the amount of extra fuel.