Navigation

Question 1

What is true direction?

Answer 1

Direction measured with reference to true North

Question 2

What is magnetic direction?

Answer 2

Direction measured with reference to magnetic North

Question 3

What is magnetic variation?

Answer 3

The difference between magnetic north and true North. E + / W -

Question 4

What is compass direction?

Answer 4

Direction measured with reference to compass North.

Question 5

What is compass deviation?

Answer 5

The difference between compass north and magnetic North. E + / W -

Question 6

What are the lines that run pole to pole on the earth called?

Answer 6

Meridians of longitude - They run from pole to pole and their units are degrees, minutes and seconds and are named east to wet depending on their position in relation to the Greenwich meridian.

Question 7

How do you measure a change of latitude?

Answer 7

They are measured in North and South in terms of degrees, minutes and seconds (60 minutes = 1 degree).

Question 8

What are the lines that run East to West on the earth called?

Answer 8

Parallels of latitude and are described by their angle above or below the equator. They are measured in degrees minutes and seconds and have a maximum value of 90.

Question 9

How do you measure the change in longitude?

Answer 9

Ch. long = Departure / Cos Lat

Question 10

What is a great circle track?

Answer 10

A great circle track is the shortest distance from one place to another on a sphere with a constantly changing track (convergence)

Question 11

What is a Rhumb line?

Answer 11

A rhumb line is a straight line between 2 points on a sphere and therefore takes longer than a great circle track.

Question 12

What is convergency?

Answer 12

Convergency is the angle of inclination between 2 meridians measured at a given latitude. As it’s a function of Sine, and therefore maximum at the poles and 0 at the equator. Convergency = Ch. Long x sine mean latitude

Question 13

What is a conversion angle?

Answer 13

A conversion angle is the angle between a rhumb line and a great circle track. 1/2 x convergency = Conversion angle

Question 14

What is chart scale?

Answer 14

Chart Scale or Representative Fraction is the ratio of chart length to earth distance. Therefore: 1/RF = CL/ED

Question 15

Describe the doppler effect?

Answer 15

The doppler effect is the apparent change in frequency received caused by the relative motion of a transmitter (Doppler shift).

Question 16

What is an airborne Doppler system?

Answer 16

An airborne Doppler system is a self contained radio / radar based system which is based on the Doppler effect which is used to mathematically calculate the ground speed of an aircraft.

Question 17

What is an INS / IRS?

Answer 17

An INS, inertial navigation system is an on board self contained navigation system which mathematically provides continuous information on the aircrafts position without any external reference. In order to keep the accelerometers level they are mounted on a gimbal assembly platform which is kept level with the use of rate gyros and motors.

Question 18

How does an INS / IRS work?

Answer 18

An INS / IRS works by measuring the aircrafts accelerations in order to mathematically provide continuous information on the aircrafts position by entering a known value (lat / long). It contains, Accelerometers, gyroscopes and a position computer.

Question 19

How does an INS / IRS find true North?

Answer 19

By using its rate gyros it is aligned to true North.

Question 20

How does an INS / IRS find magnetic north?

Answer 20

By using a stored magnetic variation and applying it to True North.

Question 21

Advantages of an INS / IRS?

Answer 21

INS: Self contained and therefore free from external navigation aids. Very accurate Totally global system and can therefore allow travel where no ground based nav aids exists, such as Atlantic or Pacific. IRS: Quick warm up times No real wander No precession Extreme accracy

Question 22

Describe GPS?

Answer 22

Global Positioning System (GPS0 / Global Navigation Satellite System (GNSS). USA: NAVSTAR SV: 6 Orbits: 4 Height: 20,180 Km Degrees to the EQ: 55 degrees Time to Orbit: 11hr 56 mins L1: 1575 MHz (All users) L2: 1227 MHz (Authorised users) Geodetic system: WGS84 2 Satellites give a lat and long, 3rd satellite will confirm the position and a 4th will give altitude information also. 5 provide basic RAIM and 6 give full RAIM (or 5SV + barometric height input). RAIM is Receiver Autonomous Integrity Monitoring and will identify and remove the SV causing the error from the satellite solution.

Question 23

What are the advantages of GPS? (5)

Answer 23

Truly global

Ability to be very accurate

Higher capability with redundancy

Free

Global Landing System (GLS) - USA only

Question 24

Disadvantages of GPS? (4 x system errors).

Answer 24

System errors:

Clock error - Corrected with Pseudo ranges

Ionospheric - Reduced by using 2 frequencies

Multi path - Relected signals from ground objects

Orbital Perturbations - Other satellites passing close by

Question 25

What is included in the GPS navigation message? (6)

Answer 25

Clock data

Ephemeris data

Orbital

Ionospheric

Health

Almanac

Question 26

How long does the GPS navigation message take to download?

Answer 26

12.5 minutes usually, but 15 to also get the first GPS fix.

Question 27

What type of GPS receiver is used on aircraft?

Answer 27

Multichannel - tracks up to 12 SV’s - Best for dynamic environment.

Question 28

What is SBAS?

Answer 28

SBAS: WAAS (Satellite Based Augmentation System: Wide Area Augmentation System) - continental range

This is a space based augmentation system which improves accuracy to CAT 1 Level. This is done by monitoring stations producing correction messages that are transmitted in real time to receivers from geostationary satellites.

This removes position errors and selective availability as well as reducing propagation errors.

Question 29

What is GBAS?

Answer 29

GBAS : LAAS (Ground Based Augmentation System / Local Area Augmentation System) - 20 nm range

This is a ground based augmentation system which improves accuracy to CAT 3 Level. This is done by monitoring stations on airfields producing correction messages that are transmitted in real time by ground based VHF transmitters to.

Pseudolites may also be used to enhance the accuracy and are usually located in pairs either side of the approach path.

This removes position errors and selective availability as well as reducing propagation errors.

Question 30

What do you know about FANS?

Answer 30

FANS - Future Air Navigation Systems is the operational concepts for the future of air traffic management such as:

CPDLC (Controller Pilot Data Link Communications)

ACARS (Aircraft Communications Addressing and Reporting System)

TCAS (Traffic Collision and Avoidance Systems)

Question 31

What is RNAV?

Answer 31

RNAV is area navigation is any system that allows the aircraft to fly within a required level of accuracy, without the requirementtofly directly over ground based facilities.

Question 32

What are the two different types of RNAV?

Answer 32

Basic RNAV (B-RNAV) - within 5 nm accuracy at least 95% of the time. RNP5

Precision RNAV (P-RNAV) - within 1 nm accuracy at least 95% of the time. This is used FMS. RNP1

Question 33

What are the 3 different levels of RNAV (for both P and B)?

Answer 33

1D = Just horizontal plane

2D = Horizontal and Vertical plane

3D = Horizontal, Vertical and Timing

Question 34

What are the 1st, 2nd and 3rd choice of system for the FMS?

Answer 34

1) DME/DME (theta/theta)
2) VOR/DME (rho/theta)
3) DR (only for limited time though - uses last computer data)

Question 35

What are the components of an RNAV system?

Answer 35

Navigation Computer Unit

CDI / HSI

Control Display Unit (CDU)

Question 36

Describe VHF direction finding?

Answer 36

VDF is used in order to triangulate an aircrafts position with certain stations which are capable (listed in AIP). These positions are then passed to the pilot in the following format:

QDM - Magnetic bearing to station

QDR - Magnetic bearing from a station

QUJ - True bearing to station

QTE - Tr;ue bearing from a station

Request example:

“True bearing, true bearing, Oxford approach, G-ABCD request true bearing G-ABCD”

All no wind.

Question 37

What are the 4 accuracies of VDF?

Answer 37

A = 2 degrees

B = 5 degrees

C = 10 degrees

D = <10 degrees

Usually will only get Bravo.

Question 38

What is the line of sight formula?

Answer 38

Line of sight range (mtrs) = 1.23 x (√Height Tx + √Height Rx)

Question 39

Describe the principle of operation on an NDB / ADF.

Answer 39

NDB (Nondirectional Beacon) is ground based.

ADF (Automatic Direction Finding) is aircraft based.

Bearing by switched Cardioid

NDB’s are a medium range ground based navigation aid and transmit in the MF / LF band (190 KHz - 1750 KHz).

The ADF inside the aircraft is either displayed a relative bearing (RBI) or as a QDM on an RMI)

Question 40

What is the range of an NDB (formulas for it)? (2)

Answer 40

Rang in nm = 3 x √ Power in Watts (land)

Rang in nm = 9 x √ Power in Watts (sea)

Question 41

What are the errors of NDB / ADF?

Answer 41

Static (thunderstorms) - large discharges of static electricity will cause large bearing errors in the ADF and will point towards the CB.

Night effect - At night the D region in the ionosphere disappears and allows skywave contamination.

Coastal Refraction - As the speed of a wave speeds up over water, it can refract (be pulled) twards the coast. This is minimal when 90 degrees to the coast but increases as the angle of incidence increases. This is why coastal NDB’s are positioned very close to the coast.

Station interferrence - due to congestion of stations in the LF / MF bands.

Outside the DOC - The DOC of an NDB is based upon a daytime signal / noise ratio of 3:1.

Quadrantial error - This is caused by the interferrence of the aircraft itself and is worst when at 45, 135, 225 and 335 degrees to the beacon.

Question 42

What accuracy does ICAO say an NDB must maintain accuracy within?

Answer 42

5 degrees

Question 43

What is ADF BFO?

Answer 43

ADF Beat frequency oscilator (BFO)

NDB’s have 2 different types of emmission:

A1A or A2A:

• A1A is for tuning and ID
• A2A is for tuning only

The BFO circuit imposes a tone onto the carrier wave to make the NDB’s ident audible.

Question 44

What are the types VOR and how do they work? (3)

Reference

Variphase

Clockwise / Anti-clockwise

Answer 44

A VOR is a VHF Omnidirectional Range that provides a magnetic bearing from the beacon by phase comparison.

There are 3 main different types of VOR, a CVOR (Conventional VOR), a DVOR, (Doppler VOR) and a TVOR (Terminal VOR).

The CVOR works by using phase difference between AM and FM, whereby the FM is the reference signal and that AM is the variphase which moves clockwise.

The DVOR works by using phase difference between AM and FM, whereby the AM is the reference signal and that FM is the variphase which moves anti-clockwise.

The radial = Phase difference (FM to aM)

Question 45

What frequencies do VOR’s transmit?

Answer 45

TVOR = 108 - 112 MHz (First decimal is even)

C/DVOR = 112 - 118 (Odd and even decimal)

Question 46

What is that forumal for the range of a VOR?

Answer 46

1.23 x (√Htx + √Hrx)

Question 47

What are the errors of a VOR?

Answer 47

Site error due to rough ground

Scalloping due to the removal of the D-layer at night

Co station interferrence (DOC)

Receiver error (+/- 3 degrees)

Question 48

What is full scale deflection on a CDI of a VOR?

Answer 48

10 degrees

Question 49

What accuracy of a VOR must be maintained within?

Answer 49

+/- 5 degrees within the DOC at ALL times

Question 50

How many chnnels are available on a VOR?

Answer 50

160 channels

Question 51

What has the further range out of an NDB or a VOR?

Answer 51

Technically an NDB has the furthest range due to its surface wave propogation path, and not line of sight propogation path i.e:

Range over land = 3 x √power in watts

Range over sea = 9 x √power in watts

Question 52

Describe an ILS and how it works?

Answer 52

An ILS (Instrument Landing System) has 2 separate ground transmitters, the localiser and the glidpath. Its method of operation is bearing by lobe comparison and their depth of modulation.

The localiser has a 90Hz lobe (left) and a 150 Hz lobe (right) which depth of modulation increases away from the centreline. For example an aircraft with more 150Hz is more right of the centreline.

The glidepath has an upper (90Hz) and lower (150Hz) lobe which works on the same principle as the localiser. False glidepaths can occur and are only found above the actual glidepath.

Question 53

What are the ILS LOC / GP frequency bands and where are they positioned?

Answer 53

LOC

VHF (108-112 with odd decimal)

Positioned approximately 300 metres from the up-wind end of the runway.

GP

UHF (330-335 MHz)

Positioned approximately 300 metres from the threshold and 200 metres from runway edge (abeam).

Question 54

Markers:

Outer: Colour, Modulation Freq, Morse ID and Distance

Middle: Colour, Modulation Freq, Morse ID and Distance

Inner: Colour, Modulation Freq, Morse ID and Distance

Answer 54

Outer: Blue, 400Hz, - - - - and 6000m

Middle: Orange, 1300Hz, - . - . - . and 1000m

Inner: White, 3000Hz, . . . . and 300m

Question 55

What is full scale deflection for both the ILS LOC and GS?

Answer 55

Localiser: 2.5 degrees

Glideslope: 0.7 degrees

Question 56

What are the errors for an ILS?

Answer 56

Back beam

False glide path

Scalloping

FM interference (counteracted by FM immune filter)

Backcourse ILS (prohibited in most of EU including UK)

Question 57

What is a primary radar?

Answer 57

Primary Surveillance Radar (PSR) transmits a high power signal, some of which is reflected by the aircraft back to the radar.

The radar determines the aircraft’s position in range from the elapsed time between transmission and reception of the reflection.

PSR does not require any specific equipment on the aircraft.

Primary radar uses 1 frequency to transmit and receive on.

Question 58

What is secondary radar?

Answer 58

Secondary Surveillance Radar (SSR) systems consist of two main elements, a ground based interrogator/receiver and an aircraft transponder. The aircraft’s transponder responds to interrogations from the ground station, enabling the aircraft’s range and bearing from the ground station to be determined.

Question 59

Describe PRI and PRF?

Answer 59

The PRI (pulse recurrence interval) is the time between two pulses

The PRF (pulse recurruence frequency) is the number of pulses transmitted per second.

1/PRI = PRF

1/PRF = PRI

Question 60

What is the formula to work out the range (nm)?

Answer 60

Max range (nm) = 81,000 / PRF

NB:

1/PRI = PRF

Question 61

How is transmission power proportional to the range? What do we need to do to the power in order to double the range?

Answer 61

In order to double the range we would need to multiple the power by 16.

P ∝ Range⁴

Question 62

What is super refraction and how is it caused?

Answer 62

Certain atmospheric conditions can actually increase the range of radar pulses by refracting the waves that would usually travel in straight lines.

Predominantly these are caused by temperature inversions.

Question 63

How does a radar receiver on MTI overcome false second trace returns?

Answer 63

MTI radars remove second trace returns by changing the PRI between onsecutive pulses with a technique known as “jittering the PRF”

Question 64

In order to have a small point and not a large rectangle, the radar should have short pulses and narrow width. How do we achieve this?

Answer 64

We achieve this by increasing the size of the antenna

Question 65

What radar (microwave horn, parabolic reflector or slotted planar aray) is best for producing smaller side lobes and improving resolution?

Answer 65

Slotted planar array reduces side lobes which reduces the power required and therefore improves the resolution

Question 66

What does RADAR stand for?

Answer 66

Radio Detection and Ranging

Question 67

Where is the interrogator for SSR?

Answer 67

At a ground station

Question 68

What frequencies do the ground station and aircraft transmit and receive on for SSR?

Answer 68

Ground system:

Transmits 1030 MHz

Receives 1090 MHz

Aircraft:

Transmits 1090 MHz

Receives 1030 MHz

UHF BAND

Question 69

What does Mode A, C and S replies give?

Answer 69

Mode A:

Identification (12 replies give 4096 combinations)

Mode C:

Pressure Altitude

• Accuracy at aircraft = 300’
• Increments = 100’
• Accuracy at ATC = 50’

Mode S:

Selective addressing with:

• Nearly 17,000,000 discrete codes (24-bit)
• Data link
• Height readout in 25’ increments

Question 70

What are the advantages and disadvantages of SSR?

Answer 70

Advantages:

• Callsign
• Pressure altitude or FL
• Groundspeed
• Destination

Disadvantages:

Requires transponder in the aircraft

Garbling (interference when aircraft is <1.7nm from eachother)

Fruiting (interferrence caused by replies to other interrogators on the ground)

Limited codes (4096)

Question 71

What are the advantages of Mode S?

Answer 71

Unambiguous aircraft ID

No garble

Improved SA for controller

More codes

Reduced R/T (datalink)

Improved short term conflict alert

Question 72

What type of Radar is a DME?

Answer 72

Secondary Radar

Question 73

What band does DME operate and what frequencies?

Answer 73

UHF

Between 962 MHz and 1213 MHz.

1030 MHz and 1090 MHz is not available for DME.

Question 74

What frequency difference is there between interrogation and transmitted frequencies for DME?

Answer 74

+/- 63 MHz

Question 75

How does a DME operate?

Answer 75

The aircraft interrogator and receiver transmits pairs of pulses at random intervals omnidirectionally.

The ground station transponder re-transmits all pulses at +/- 63 MHz after a 50 micro second delay.

The aircraft receiver identifies its own pulses and determines the range from the time taken minus 50 microseconds.

Question 76

How many aircraft can interrogate a DME at once?

Answer 76

100 aircraft

Question 77

Describe the range search for a DME?

Answer 77

Rapid lock on: DME interrogator transmits 150 pulse-pairs per second for 15000 pulse-pairs.

If lock on is not achieved that it will go to 60 pulse per second.

At lock on it will go to 25 pulse pairs per second.

In modern equipment this takes around 5 seconds.

Question 78

Describe the DME beacon saturation?

Answer 78

It is assumed that an aircraft will require 27 pulse pairs for lock on and the output of a modern ground beacon is a constant 2700 pulse pairs per second. Therefore it becomes saturated at 100 aircraft and excludes transmissions from aircraft whose pulses are weaker.

Question 79

If DME is paired with an ILS where is zero range given?

Answer 79

On the threshold of the ILS runway

Question 80

What is the only error DME experiences?

Answer 80

Slant range

Question 81

Describe the functions of a transponder?

Answer 81

Code selection: 4 digit code should be changed when Tx is on STBY to avoid inadvertant distress signal.

Transmission functions:

STBY: Usually warmed up in the STBY position

ON: Provides mode A (ID only)

ALT: Additionally provides aircraft pressure alt or FL

TST: Provides a self check of its operation, if ok reply / monitor light will illuminate.

IDENT SWITCH: Causes a special symbol to bloom around the aircraft for 20 seconds on the controllers display

Question 82

How does an isoecho / airborne weather radar work and what are its functions?

Answer 82

AWR is a primary radar and uses the echo principle to detect range and the searchlight principle to depict relative bearing.

The main functions of the AWR is:

• To detect the size of water droplets
• Determine the height of cloud tops
• Map the terrain
• Provide position fixes from prominent features.

Question 83

What are the two types of beams and what are their uses / distances?

Answer 83

Pensil (conical) beam for ranges >60nm

Fan (Cosecant²) beam for ground mapping and shorter distances <60 nm

Question 84

How is beam width reduced?

Answer 84

By increasing the size of the antenna

Question 85

What frequency and band does the AWR operate in?

Answer 85

9375 MHz (9.375 GHZ) in the SHF band

Question 86

What indicates turbulence on AWR?

Answer 86

Steep colour gradient

Question 87

What could falsely indicate water on AWR?

Answer 87

Hill shadows or mountain shadows

Question 88

What axis (2) is the AWR stabilised in?

Answer 88

Pitch and roll axis

Question 89

What is the tilt of an AWR? (up/down and left/right)?

Answer 89

Up/down: +/- 15 degrees

Left/right: +/- 90 degrees

Question 90

What is AGC (auto gain control) on AWR?

Answer 90

AGC makes the system less sensitive to short range returns so that an overall even picture is produced.

Without the AGC you would expect closer targets to be brighter on the screen.

Question 91

What are the associated colours shown on AWR in respect to reflective levels in wx mode?

Answer 91

• Black
• Green
• Yellow
• Red
• Magenta

Question 92

What are the associated colours shown on AWR in respect to reflective levels in navigation mode (terrain)?

Answer 92

Green (light returns)

Yellow (medium returns)

Red (heavy ground returns)