006 - Feedlines and Antenna Systems

Question 1

B-006-001-001
What connects your transceiver to your antenna?

(a) A transmission line
(b) The power cord
(c) A ground wire
(d) A dummy load

Answer 1

B-006-001-001
What connects your transceiver to your antenna?

(a) A transmission line

Question 2

B-006-001-002
The characteristic impedance of a transmission line is determined by the:

(a) physical dimensions and relative positions of the conductors
(b) length of the line
(c) frequency at which the line is operated
(d) load placed on the line

Answer 2

B-006-001-002
The characteristic impedance of a transmission line is determined by the:

(a) physical dimensions and relative positions of the conductors

Question 3

B-006-001-003
The characteristic impedance of a 20 metre piece of transmission line is 52 ohms. If 10 metres were cut off, the impedance would be:

(a) 26 ohms
(b) 39 ohms
(c) 13 ohms
(d) 52 ohms

Answer 3

B-006-001-003
The characteristic impedance of a 20 metre piece of transmission line is 52 ohms. If 10 metres were cut off, the impedance would be:

(d) 52 ohms

Question 4

B-006-001-004
The characteristic impedance of a coaxial line:

(a) can be the same for different diameter line
(b) changes significantly with the frequency of the energy it carries
(c) is correct for only one size of line
(d) is greater for larger diameter line

Answer 4

B-006-001-004
The characteristic impedance of a coaxial line:

(a) can be the same for different diameter line

Question 5

B-006-001-005
What commonly available antenna transmission line can be buried directly in the ground for some distance without adverse effects?

(a) 300 ohm twin-lead
(b) Coaxial cable
(c) 600 ohm open-wire line
(d) 75 ohm twin-lead

Answer 5

B-006-001-005
What commonly available antenna transmission line can be buried directly in the ground for some distance without adverse effects?

(b) Coaxial cable

Question 6

B-006-001-006
The characteristic impedance of a transmission line is:

(a) the impedance of a section of the line one wavelength long
(b) equal to the pure resistance which, if connected to the end of the line, will absorb all the power arriving along it
(c) the dynamic impedance of the line at the operating frequency
(d) the ratio of the power supplied to the line to the power delivered to the load

Answer 6

B-006-001-006
The characteristic impedance of a transmission line is:

(b) equal to the pure resistance which, if connected to the end of the line, will absorb all the power arriving along it

Question 7

B-006-001-007
A transmission line differs from an ordinary circuit or network in communications or signalling devices in one very important way. That important aspect is:

(a) capacitive reactance
(b) propagation delay
(c) inductive reactance
(d) resistance

Answer 7

B-006-001-007
A transmission line differs from an ordinary circuit or network in communications or signalling devices in one very important way. That important aspect is:

(b) propagation delay

Question 8

B-006-001-008
The characteristic impedance of a parallel wire transmission line does not depend on the:

(a) radius of the conductors
(b) centre to centre distance between conductors
(c) dielectric
(d) velocity of energy on the line

Answer 8

B-006-001-008
The characteristic impedance of a parallel wire transmission line does not depend on the:

(d) velocity of energy on the line

Question 9

B-006-001-009
If the impedance terminating a transmission line differs significantly from the characteristic impedance of the line, what will be observed at the input of the line?

(a) Some value of impedance influenced by line length
(b) An infinite impedance
(c) A negative impedance
(d) An impedance nearly equal to the characteristic impedance

Answer 9

B-006-001-009
If the impedance terminating a transmission line differs significantly from the characteristic impedance of the line, what will be observed at the input of the line?

(a) Some value of impedance influenced by line length

Question 10

B-006-001-010
What factors determine the characteristic impedance of a parallel-conductor antenna transmission line?

(a) The distance between the centres of the conductors and the radius of the conductors
(b) The distance between the centres of the conductors and the length of the line
(c) The radius of the conductors and the frequency of the signal
(d) The frequency of the signal and the length of the line

Answer 10

B-006-001-010
What factors determine the characteristic impedance of a parallel-conductor antenna transmission line?

(a) The distance between the centres of the conductors and the radius of the conductors

Question 11

B-006-001-011
What factors determine the characteristic impedance of a coaxial antenna transmission line?

(a) The diameter of the shield and the length of the line
(b) The diameter of the shield and the frequency of the signal
(c) The frequency of the signal and the length of the line
(d) The ratio of the diameter of the inner conductor to the diameter of the outer shield

Answer 11

B-006-001-011
What factors determine the characteristic impedance of a coaxial antenna transmission line?

(d) The ratio of the diameter of the inner conductor to the diameter of the outer shield

Question 12

B-006-002-001
What is a coaxial cable?

(a) A center wire inside an insulating material which is covered by a metal sleeve or shield
(b) Two wires side-by-side in a plastic ribbon
(c) Two wires side-by-side held apart by insulating rods
(d) Two wires twisted around each other in a spiral

Answer 12

B-006-002-001
What is a coaxial cable?

(a) A center wire inside an insulating material which is covered by a metal sleeve or shield

Question 13

B-006-002-002
What is parallel-conductor transmission line?

(a) Two wires twisted around each other in a spiral
(b) A center wire inside an insulating material which is covered by a metal sleeve or shield
(c) A metal pipe which is as wide or slightly wider than a wavelength of the signal it carries
(d) Two wires side-by-side held apart by insulating material

Answer 13

B-006-002-002
What is parallel-conductor transmission line?

(d) Two wires side-by-side held apart by insulating material

Question 14

B-006-002-003
What kind of antenna transmission line is made of two conductors held apart by insulated rods?

(a) Coaxial cable
(b) Twin lead in a plastic ribbon
(c) Open wire line
(d) Twisted pair

Answer 14

B-006-002-003
What kind of antenna transmission line is made of two conductors held apart by insulated rods?

(c) Open wire line

Question 15

B-006-002-004
What does the term “balun” mean?

(a) Balanced unloader
(b) Balanced to unbalanced
(c) Balanced unmodulator
(d) Balanced antenna network

Answer 15

B-006-002-004
What does the term “balun” mean?

(b) Balanced to unbalanced

Question 16

B-006-002-005
Where would you install a balun to feed a dipole antenna with 50-ohm coaxial cable?

(a) Between the transmitter and the coaxial cable
(b) Between the antenna and the ground
(c) Between the coaxial cable and the antenna
(d) Between the coaxial cable and the ground

Answer 16

B-006-002-005
Where would you install a balun to feed a dipole antenna with 50-ohm coaxial cable?

(c) Between the coaxial cable and the antenna

Question 17

B-006-002-006
What is an unbalanced line?

(a) Transmission line with neither conductor connected to ground
(b) Transmission line with one conductor connected to ground
(c) Transmission line with both conductors connected to ground
(d) Transmission line with both conductors connected to each other

Answer 17

B-006-002-006
What is an unbalanced line?

(b) Transmission line with one conductor connected to ground

Question 18

B-006-002-007
What device can be installed to feed a balanced antenna with an unbalanced transmission line?

(a) A triaxial transformer
(b) A balun
(c) A wave trap
(d) A loading coil

Answer 18

B-006-002-007
What device can be installed to feed a balanced antenna with an unbalanced transmission line?

(b) A balun

Question 19

B-006-002-008
A flexible coaxial line contains:

(a) four or more conductors running parallel
(b) braided shield conductor and insulation around a central conductor
(c) only one conductor
(d) two parallel conductors separated by spacers

Answer 19

B-006-002-008
A flexible coaxial line contains:

(b) braided shield conductor and insulation around a central conductor

Question 20

B-006-002-009
A balanced transmission line:

(a) has one conductor inside the other
(b) carries RF current on one wire only
(c) is made of two parallel wires
(d) is made of one conductor only

Answer 20

B-006-002-009
A balanced transmission line:

(c) is made of two parallel wires

Question 21

B-006-002-010
A 75 ohm transmission line could be matched to the 300 ohm feed point of an antenna:

(a) with an extra 250 ohm resistor
(b) by using a 4 to 1 trigatron
(c) by using a 4 to 1 impedance transformer
(d) by inserting a diode in one leg of the antenna

Answer 21

B-006-002-010
A 75 ohm transmission line could be matched to the 300 ohm feed point of an antenna:

(c) by using a 4 to 1 impedance transformer

Question 22

B-006-002-011
What kind of antenna transmission line can be constructed using two conductors which are maintained a uniform distance apart using insulated spreaders?

(a) Coaxial cable
(b) 600 ohm open wire line
(c) 75 ohm twin-lead
(d) 300 ohm twin-lead

Answer 22

B-006-002-011
What kind of antenna transmission line can be constructed using two conductors which are maintained a uniform distance apart using insulated spreaders?

(b) 600 ohm open wire line

Question 23

B-006-003-001
Why does coaxial cable make a good antenna transmission line?

(a) It is weatherproof, and its impedance is higher than that of most amateur antennas
(b) It can be used near metal objects, and its impedance is higher than that of most amateur antennas
(c) It is weatherproof, and its impedance matches most amateur antennas
(d) You can make it at home, and its impedance matches most amateur antennas

Answer 23

B-006-003-001
Why does coaxial cable make a good antenna transmission line?

(c) It is weatherproof, and its impedance matches most amateur antennas

Question 24

B-006-003-002
What is the best antenna transmission line to use, if it must be put near grounded metal objects?

(a) Ladder-line
(b) Twisted pair
(c) Twin lead
(d) Coaxial cable

Answer 24

B-006-003-002
What is the best antenna transmission line to use, if it must be put near grounded metal objects?

(d) Coaxial cable

Question 25

B-006-003-003 What are some reasons not to use parallel-conductor transmission line? (a) It does not work well when tied down to metal objects, and you should use a balun and may have to use an impedance-matching device with your transceiver (b) You must use an impedance-matching device with your transceiver, and it does not work very well with a high SWR (c) It does not work well when tied down to metal objects, and it cannot operate under high power (d) It is difficult to make at home, and it does not work very well with a high SWR

Answer 25

B-006-003-003 What are some reasons not to use parallel-conductor transmission line? (a) It does not work well when tied down to metal objects, and you should use a balun and may have to use an impedance-matching device with your transceiver

Question 26

B-006-003-004 What common connector type usually joins RG-213 coaxial cable to an HF transceiver? (a) An F-type cable connector (b) A banana plug connector (c) A PL-259 connector (d) A binding post connector

Answer 26

B-006-003-004 What common connector type usually joins RG-213 coaxial cable to an HF transceiver? (c) A PL-259 connector

Question 27

B-006-003-005 What common connector usually joins a hand-held transceiver to its antenna? (a) A PL-259 connector (b) An F-type cable connector (c) An SMA connector (d) A binding post connector

Answer 27

B-006-003-005 What common connector usually joins a hand-held transceiver to its antenna? (c) An SMA connector

Question 28

B-006-003-006 Which of these common connectors has the lowest loss at UHF? (a) An F-type cable connector (b) A type-N connector (c) A BNC connector (d) A PL-259 connector

Answer 28

B-006-003-006 Which of these common connectors has the lowest loss at UHF? (b) A type-N connector

Question 29

B-006-003-007 If you install a 6 metre Yagi on a tower 60 metres (200 ft) from your transmitter, which of the following transmission lines provides the least loss? (a) RG-174 (b) RG-59 (c) RG-58 (d) RG-213

Answer 29

B-006-003-007 If you install a 6 metre Yagi on a tower 60 metres (200 ft) from your transmitter, which of the following transmission lines provides the least loss? (d) RG-213

Question 30

B-006-003-008 Why should you regularly clean and tighten all antenna connectors? (a) To keep them looking nice (b) To keep them from getting stuck in place (c) To increase their capacitance (d) To help keep their contact resistance at a minimum

Answer 30

B-006-003-008 Why should you regularly clean and tighten all antenna connectors? (d) To help keep their contact resistance at a minimum

Question 31

B-006-003-009 What commonly available antenna transmission line can be buried directly in the ground for some distance without adverse effects? (a) 75 ohm twin-lead (b) Coaxial cable (c) 600 ohm open wire line (d) 300 ohm twin-lead

Answer 31

B-006-003-009 What commonly available antenna transmission line can be buried directly in the ground for some distance without adverse effects? (b) Coaxial cable

Question 32

B-006-003-010 When antenna transmission lines must be placed near grounded metal objects, which of the following transmission lines should be used? (a) Coaxial cable (b) 300 ohm twin-lead (c) 600 ohm open wire line (d) 75 ohm twin-lead

Answer 32

B-006-003-010 When antenna transmission lines must be placed near grounded metal objects, which of the following transmission lines should be used? (a) Coaxial cable

Question 33

B-006-003-011 TV twin-lead transmission line can be used for a transmission line in an amateur station. The impedance of this line is approximately: (a) 600 ohms (b) 50 ohms (c) 70 ohms (d) 300 ohms

Answer 33

B-006-003-011 TV twin-lead transmission line can be used for a transmission line in an amateur station. The impedance of this line is approximately: (d) 300 ohms

Question 34

B-006-004-001 Why should you use only good quality coaxial cable and connectors for a UHF antenna system? (a) To keep television interference high (b) To keep RF loss low (c) To keep the power going to your antenna system from getting too high (d) To keep the standing wave ratio of your antenna system high

Answer 34

B-006-004-001 Why should you use only good quality coaxial cable and connectors for a UHF antenna system? (b) To keep RF loss low

Question 35

B-006-004-002 What are some reasons to use parallel-conductor transmission line? (a) It has low impedance, and will operate with a high SWR (b) It will operate with a high SWR, and has less loss than coaxial cable (c) It will operate with a high SWR, and it works well when tied down to metal objects (d) It has a low impedance, and has less loss than coaxial cable

Answer 35

B-006-004-002 What are some reasons to use parallel-conductor transmission line? (b) It will operate with a high SWR, and has less loss than coaxial cable

Question 36

B-006-004-003 If your transmitter and antenna are 15 metres (50 ft) apart, but are connected by 60 metres (200 ft) of RG-58 coaxial cable, what should be done to reduce transmission line loss? (a) Shorten the excess cable so the transmission line is an odd number of wavelengths long (b) Shorten the excess cable (c) Roll the excess cable into a coil which is as small as possible (d) Shorten the excess cable so the transmission line is an even number of wavelengths long

Answer 36

B-006-004-003 If your transmitter and antenna are 15 metres (50 ft) apart, but are connected by 60 metres (200 ft) of RG-58 coaxial cable, what should be done to reduce transmission line loss? (b) Shorten the excess cable

Question 37

B-006-004-004 As the length of a transmission line is changed, what happens to signal loss? (a) Signal loss decreases as length increases (b) Signal loss is the least when the length is the same as the signal's wavelength (c) Signal loss increases as length increases (d) Signal loss is the same for any length of transmission line

Answer 37

B-006-004-004 As the length of a transmission line is changed, what happens to signal loss? (c) Signal loss increases as length increases

Question 38

B-006-004-005 As the frequency of a signal is changed, what happens to signal loss in a transmission line? (a) Signal loss increases with decreasing frequency (b) Signal loss is the least when the signal's wavelength is the same as the transmission line's length (c) Signal loss increases with increasing frequency (d) Signal loss is the same for any frequency

Answer 38

B-006-004-005 As the frequency of a signal is changed, what happens to signal loss in a transmission line? (c) Signal loss increases with increasing frequency

Question 39

B-006-004-006 Losses occurring on a transmission line between transmitter and antenna results in: (a) less RF power being radiated (b) an SWR reading of 1:1 (c) reflections occurring in the line (d) the wire radiating RF energy

Answer 39

B-006-004-006 Losses occurring on a transmission line between transmitter and antenna results in: (a) less RF power being radiated

Question 40

B-006-004-007 The lowest loss transmission line on HF is: (a) 75 ohm twin-lead (b) coaxial cable (c) open wire line (d) 300 ohm twin-lead

Answer 40

B-006-004-007 The lowest loss transmission line on HF is: (c) open wire line

Question 41

B-006-004-008 In what values are RF transmission line losses expressed? (a) Ohms per MHz (b) dB per unit length (c) dB per MHz (d) Ohms per metre

Answer 41

B-006-004-008 In what values are RF transmission line losses expressed? (b) dB per unit length

Question 42

B-006-004-009 If the length of coaxial transmission line is increased from 20 metres (66 ft) to 40 metres (132 ft), how would this affect the line loss? (a) It would be reduced by 10% (b) It would be increased by 10% (c) It would be increased by 100% (d) It would be reduced to 50%

Answer 42

B-006-004-009 If the length of coaxial transmission line is increased from 20 metres (66 ft) to 40 metres (132 ft), how would this affect the line loss? (c) It would be increased by 100%

Question 43

B-006-004-010 If the frequency is increased, how would this affect the loss on a transmission line? (a) It is independent of frequency (b) It would increase (c) It depends on the line length (d) It would decrease

Answer 43

B-006-004-010 If the frequency is increased, how would this affect the loss on a transmission line? (b) It would increase

Question 44

B-006-005-001 What does an SWR reading of 1:1 mean? (a) An antenna for another frequency band is probably connected (b) No power is going to the antenna (c) The best impedance match has been attained (d) The SWR meter is broken

Answer 44

B-006-005-001 What does an SWR reading of 1:1 mean? (c) The best impedance match has been attained

Question 45

B-006-005-002 What does an SWR reading of less than 1.5:1 mean? (a) An impedance match which is too low (b) A fairly good impedance match (c) A serious impedance mismatch, something may be wrong with the antenna system (d) An antenna gain of 1.5

Answer 45

B-006-005-002 What does an SWR reading of less than 1.5:1 mean? (b) A fairly good impedance match

Question 46

B-006-005-003 What kind of SWR reading may mean poor electrical contact between parts of an antenna system? (a) A negative reading (b) No reading at all (c) A very low reading (d) A jumpy reading

Answer 46

B-006-005-003 What kind of SWR reading may mean poor electrical contact between parts of an antenna system? (d) A jumpy reading

Question 47

B-006-005-004 What does a very high SWR reading mean? (a) The antenna is the wrong length for the operating frequency, or the transmission line may be open or short circuited (b) The transmitter is putting out more power than normal, showing that it is about to go bad (c) There is a large amount of solar radiation, which means very poor radio conditions (d) The signals coming from the antenna are unusually strong, which means very good radio condition

Answer 47

B-006-005-004 What does a very high SWR reading mean? (a) The antenna is the wrong length for the operating frequency, or the transmission line may be open or short circuited

Question 48

B-006-005-005 What does standing-wave ratio mean? (a) The ratio of maximum to minimum inductances on a transmission line (b) The ratio of maximum to minimum voltages on a transmission line (c) The ratio of maximum to minimum resistances on a transmission line (d) The ratio of maximum to minimum impedances on a transmission line

Answer 48

B-006-005-005 What does standing-wave ratio mean? (b) The ratio of maximum to minimum voltages on a transmission line

Question 49

B-006-005-006 If your antenna transmission line gets hot when you are transmitting, what might this mean? (a) You should transmit using less power (b) The SWR may be too high, or the transmission line loss may be high (c) The conductors in the transmission line are not insulated very well (d) The transmission line is too long

Answer 49

B-006-005-006 If your antenna transmission line gets hot when you are transmitting, what might this mean? (b) The SWR may be too high, or the transmission line loss may be high

Question 50

B-006-005-007 If the characteristic impedance of the transmission line does not match the antenna input impedance then: (a) standing waves are produced in the transmission line (b) heat is produced at the junction (c) the SWR reading falls to 1:1 (d) the antenna will not radiate any signal

Answer 50

B-006-005-007 If the characteristic impedance of the transmission line does not match the antenna input impedance then: (a) standing waves are produced in the transmission line

Question 51

B-006-005-008 The result of the presence of standing waves on a transmission line is: (a) perfect impedance match between transmitter and transmission line (b) reduced transfer of RF energy to the antenna (c) maximum transfer of energy to the antenna from the transmitter (d) lack of radiation from the transmission line

Answer 51

B-006-005-008 The result of the presence of standing waves on a transmission line is: (b) reduced transfer of RF energy to the antenna

Question 52

B-006-005-009 An SWR meter measures the degree of match between transmission line and antenna by: (a) measuring radiated RF energy (b) measuring the conductor temperature (c) inserting a diode in the transmission line (d) comparing forward and reflected voltage

Answer 52

B-006-005-009 An SWR meter measures the degree of match between transmission line and antenna by: (d) comparing forward and reflected voltage

Question 53

B-006-005-010 A resonant antenna having a feed point impedance of 200 ohms is connected to a transmission line which has an impedance of 50 ohms. What will the standing wave ratio of this system be? (a) 6:1 (b) 3:1 (c) 5:1 (d) 4:1

Answer 53

B-006-005-010 A resonant antenna having a feed point impedance of 200 ohms is connected to a transmission line which has an impedance of 50 ohms. What will the standing wave ratio of this system be? (d) 4:1

Question 54

B-006-005-011 The type of transmission line best suited to operating at a high standing wave ratio is: (a) 75 ohm twin-lead (b) 600 ohm open wire line (c) coaxial line (d) 300 ohm twin-lead

Answer 54

B-006-005-011 The type of transmission line best suited to operating at a high standing wave ratio is: (b) 600 ohm open wire line

Question 55

B-006-006-001 What device might allow use of an antenna on a band it was not designed for? (a) An antenna tuner (b) An SWR meter (c) A low pass filter (d) A high pass filter

Answer 55

B-006-006-001 What device might allow use of an antenna on a band it was not designed for? (a) An antenna tuner

Question 56

B-006-006-002 What does an antenna tuner do? (a) It helps a receiver automatically tune in stations that are far away (b) It switches an antenna system to a transmitter when sending, and to a receiver when listening (c) It matches a transceiver to a mismatched antenna system (d) It switches a transceiver between different kinds of antennas connected to one transmission line

Answer 56

B-006-006-002 What does an antenna tuner do? (c) It matches a transceiver to a mismatched antenna system

Question 57

B-006-006-003 What would you use to connect a coaxial cable of 50 ohms impedance to an antenna of 17 ohms impedance? (a) An impedance-matching device (b) An SWR meter (c) A low pass filter (d) A terminating resistor

Answer 57

B-006-006-003 What would you use to connect a coaxial cable of 50 ohms impedance to an antenna of 17 ohms impedance? (a) An impedance-matching device

Question 58

B-006-006-004 When will a power source deliver maximum output to the load? (a) When the impedance of the load is equal to the impedance of the source (b) When air wound transformers are used instead of iron-core transformers (c) When the power-supply fuse rating equals the primary winding current (d) When the load resistance is infinite

Answer 58

B-006-006-004 When will a power source deliver maximum output to the load? (a) When the impedance of the load is equal to the impedance of the source

Question 59

B-006-006-005 What happens when the impedance of an electrical load is equal to the internal impedance of the power source? (a) The electrical load is shorted (b) The source delivers maximum power to the load (c) No current can flow through the circuit (d) The source delivers minimum power to the load

Answer 59

B-006-006-005 What happens when the impedance of an electrical load is equal to the internal impedance of the power source? (b) The source delivers maximum power to the load

Question 60

B-006-006-006 Why is impedance matching important? (a) So the load will draw minimum power from the source (b) To ensure that there is less resistance than reactance in the circuit (c) To ensure that the resistance and reactance in the circuit are equal (d) So the source can deliver maximum power to the load

Answer 60

B-006-006-006 Why is impedance matching important? (d) So the source can deliver maximum power to the load

Question 61

B-006-006-007 To obtain efficient power transmission from a transmitter to an antenna requires: (a) high load impedance (b) low load resistance (c) inductive impedance (d) matching of impedances

Answer 61

B-006-006-007 To obtain efficient power transmission from a transmitter to an antenna requires: (d) matching of impedances

Question 62

B-006-006-008 To obtain efficient transfer of power from a transmitter to an antenna, it is important that there is a: (a) high load impedance (b) proper method of balance (c) matching of impedance (d) low load resistance

Answer 62

B-006-006-008 To obtain efficient transfer of power from a transmitter to an antenna, it is important that there is a: (c) matching of impedance

Question 63

B-006-006-009 If an antenna is correctly matched to a transmitter, the length of transmission line: (a) must be a full wavelength long (b) must be an odd number of quarter-wave (c) must be an even number of half-waves (d) will have no effect on the matching

Answer 63

B-006-006-009 If an antenna is correctly matched to a transmitter, the length of transmission line: (d) will have no effect on the matching

Question 64

B-006-006-010 The reason that an RF transmission line should be matched at the transmitter end is to: (a) ensure that the radiated signal has the intended polarization (b) transfer the maximum amount of power to the antenna (c) prevent frequency drift (d) overcome fading of the transmitted signal

Answer 64

B-006-006-010 The reason that an RF transmission line should be matched at the transmitter end is to: (b) transfer the maximum amount of power to the antenna

Question 65

B-006-006-011 If the centre impedance of a folded dipole is approximately 300 ohms, and you are using RG8U (50 ohms) coaxial lines, what is the ratio required to have the line and the antenna matched? (a) 2:1 (b) 4:1 (c) 10:1 (d) 6:1

Answer 65

B-006-006-011 If the centre impedance of a folded dipole is approximately 300 ohms, and you are using RG8U (50 ohms) coaxial lines, what is the ratio required to have the line and the antenna matched? (d) 6:1

Question 66

B-006-007-001 What does horizontal wave polarization mean? (a) The electric and magnetic lines of force of a radio wave are perpendicular to the Earth's surface (b) The electric lines of force of a radio wave are parallel to the Earth's surface (c) The electric lines of force of a radio wave are perpendicular to the Earth's surface (d) The magnetic lines of force of a radio wave are parallel to the Earth's surface

Answer 66

B-006-007-001 What does horizontal wave polarization mean? (b) The electric lines of force of a radio wave are parallel to the Earth's surface

Question 67

B-006-007-002 What does vertical wave polarization mean? (a) The electric lines of force of a radio wave are perpendicular to the Earth's surface (b) The magnetic lines of force of a radio wave are perpendicular to the Earth's surface (c) The electric and magnetic lines of force of a radio wave are parallel to the Earth's surface (d) The electric lines of force of a radio wave are parallel to the Earth's surface

Answer 67

B-006-007-002 What does vertical wave polarization mean? (a) The electric lines of force of a radio wave are perpendicular to the Earth's surface

Question 68

B-006-007-003 What electromagnetic wave polarization does a Yagi antenna have when its elements are parallel to the Earth's surface? (a) Helical (b) Horizontal (c) Vertical (d) Circular

Answer 68

B-006-007-003 What electromagnetic wave polarization does a Yagi antenna have when its elements are parallel to the Earth's surface? (b) Horizontal

Question 69

B-006-007-004 What electromagnetic wave polarization does a half-wavelength antenna have when it is perpendicular to the Earth's surface? (a) Vertical (b) Circular (c) Horizontal (d) Parabolical

Answer 69

B-006-007-004 What electromagnetic wave polarization does a half-wavelength antenna have when it is perpendicular to the Earth's surface? (a) Vertical

Question 70

B-006-007-005 Polarization of an antenna is determined by: (a) the height of the antenna (b) the type of antenna (c) the magnetic field (d) the orientation of the electric field relative to the Earth's surface

Answer 70

B-006-007-005 Polarization of an antenna is determined by: (d) the orientation of the electric field relative to the Earth's surface

Question 71

B-006-007-006 An isotropic antenna is: (a) an infinitely long piece of wire (b) a dummy load (c) a hypothetical point source (d) a half-wave reference dipole

Answer 71

B-006-007-006 An isotropic antenna is: (c) a hypothetical point source

Question 72

B-006-007-007 What is the antenna radiation pattern for an isotropic radiator? (a) A parabola (b) A cardioid (c) A unidirectional cardioid (d) A sphere

Answer 72

B-006-007-007 What is the antenna radiation pattern for an isotropic radiator? (d) A sphere

Question 73

B-006-007-008 VHF signals from a mobile station using a vertical whip antenna will normally be best received using a: (a) vertical ground-plane antenna (b) random length of wire (c) horizontal ground-plane antenna (d) horizontal dipole antenna

Answer 73

B-006-007-008 VHF signals from a mobile station using a vertical whip antenna will normally be best received using a: (a) vertical ground-plane antenna

Question 74

B-006-007-009 A dipole antenna will emit a vertically polarized wave if it is: (a) fed with the correct type of RF (b) mounted vertically (c) too near to the ground (d) parallel with the ground

Answer 74

B-006-007-009 A dipole antenna will emit a vertically polarized wave if it is: (b) mounted vertically

Question 75

B-006-007-010 If an electromagnetic wave leaves an antenna vertically polarized, it will arrive at the receiving antenna, by ground wave: (a) polarized at right angles to original (b) horizontally polarized (c) polarized in any plane (d) vertically polarized

Answer 75

B-006-007-010 If an electromagnetic wave leaves an antenna vertically polarized, it will arrive at the receiving antenna, by ground wave: (d) vertically polarized

Question 76

B-006-007-011 Compared with a horizontal antenna, a vertical antenna will receive a vertically polarized radio wave: (a) at weaker strength (b) at greater strength (c) without any comparative difference (d) if the antenna changes the polarization

Answer 76

B-006-007-011 Compared with a horizontal antenna, a vertical antenna will receive a vertically polarized radio wave: (b) at greater strength

Question 77

B-006-008-001 If an antenna is made longer, what happens to its resonant frequency? (a) It decreases (b) It increases (c) It stays the same (d) It disappears

Answer 77

B-006-008-001 If an antenna is made longer, what happens to its resonant frequency? (a) It decreases

Question 78

B-006-008-002 If an antenna is made shorter, what happens to its resonant frequency? (a) It stays the same (b) It increases (c) It disappears (d) It decreases

Answer 78

B-006-008-002 If an antenna is made shorter, what happens to its resonant frequency? (b) It increases

Question 79

B-006-008-003 The wavelength for a frequency of 25 MHz is: (a) 15 metres (49.2 ft) (b) 12 metres (39.4 ft) (c) 4 metres (13.1 ft) (d) 32 metres (105 ft)

Answer 79

B-006-008-003 The wavelength for a frequency of 25 MHz is: (b) 12 metres (39.4 ft)

Question 80

B-006-008-004 The velocity of propagation of radio frequency energy in free space is: (a) 3000 kilometres per second (b) 150 kilometres per second (c) 300 000 kilometres per second (d) 186 000 kilometres per second

Answer 80

B-006-008-004 The velocity of propagation of radio frequency energy in free space is: (c) 300 000 kilometres per second

Question 81

B-006-008-005 Adding a series inductance to an antenna would: (a) increase the resonant frequency (b) have little effect (c) decrease the resonant frequency (d) have no change on the resonant frequency

Answer 81

B-006-008-005 Adding a series inductance to an antenna would: (c) decrease the resonant frequency

Question 82

B-006-008-006 The resonant frequency of an antenna may be increased by: (a) lowering the radiating element (b) increasing the height of the radiating element (c) lengthening the radiating element (d) shortening the radiating element

Answer 82

B-006-008-006 The resonant frequency of an antenna may be increased by: (d) shortening the radiating element

Question 83

B-006-008-007 The speed of a radio wave: (a) is infinite in space (b) is always less than half speed of light (c) varies directly with frequency (d) is the same as the speed of light

Answer 83

B-006-008-007 The speed of a radio wave: (d) is the same as the speed of light

Question 84

B-006-008-008 At the end of suspended antenna wire, insulators are used. These act to: (a) limit the electrical length of the antenna (b) increase the effective antenna length (c) allow the antenna to be more easily held vertically (d) prevent any loss of radio waves by the antenna

Answer 84

B-006-008-008 At the end of suspended antenna wire, insulators are used. These act to: (a) limit the electrical length of the antenna

Question 85

B-006-008-009 To lower the resonant frequency of an antenna, the operator should: (a) shorten it (b) ground one end (c) lengthen it (d) centre feed it with TV ribbon transmission line

Answer 85

B-006-008-009 To lower the resonant frequency of an antenna, the operator should: (c) lengthen it

Question 86

B-006-008-010 One solution to multiband operation with a shortened radiator is the "trap dipole" or trap vertical. These "traps" are actually: (a) large wire-wound resistors (b) a coil and capacitor in parallel (c) coils wrapped around a ferrite rod (d) hollow metal cans

Answer 86

B-006-008-010 One solution to multiband operation with a shortened radiator is the "trap dipole" or trap vertical. These "traps" are actually: (b) a coil and capacitor in parallel

Question 87

B-006-008-011 The wavelength corresponding to a frequency of 2 MHz is: (a) 360 m (1181 ft) (b) 1500 m (4921 ft) (c) 150 m (492 ft) (d) 30 m (98 ft)

Answer 87

B-006-008-011 The wavelength corresponding to a frequency of 2 MHz is: (c) 150 m (492 ft)

Question 88

B-006-009-001 What is a parasitic beam antenna? (a) An antenna where the driven element obtains its radio energy by induction or radiation from director elements (b) An antenna where some elements obtain their radio energy by induction or radiation from a driven element (c) An antenna where all elements are driven by direct connection to the transmission line (d) An antenna where wave traps are used to magnetically couple the elements

Answer 88

B-006-009-001 What is a parasitic beam antenna? (b) An antenna where some elements obtain their radio energy by induction or radiation from a driven element

Question 89

B-006-009-002 How can the bandwidth of a parasitic beam antenna be increased? (a) Use traps on the elements (b) Use tapered-diameter elements (c) Use larger diameter elements (d) Use closer element spacing

Answer 89

B-006-009-002 How can the bandwidth of a parasitic beam antenna be increased? (c) Use larger diameter elements

Question 90

B-006-009-003 If a parasitic element slightly shorter than a horizontal dipole antenna is placed parallel to the dipole 0.1 wavelength from it and at the same height, what effect will this have on the antenna's radiation pattern? (a) A major lobe will develop in the horizontal plane, parallel to the two elements (b) A major lobe will develop in the vertical plane, away from the ground (c) The radiation pattern will not be affected (d) A major lobe will develop in the horizontal plane, from the dipole toward the parasitic element

Answer 90

B-006-009-003 If a parasitic element slightly shorter than a horizontal dipole antenna is placed parallel to the dipole 0.1 wavelength from it and at the same height, what effect will this have on the antenna's radiation pattern? (d) A major lobe will develop in the horizontal plane, from the dipole toward the parasitic element

Question 91

B-006-009-004 If a parasitic element slightly longer than a horizontal dipole antenna is placed parallel to the dipole 0.1 wavelength from it and at the same height, what effect will this have on the antenna's radiation pattern? (a) A major lobe will develop in the horizontal plane, from the parasitic element toward the dipole (b) A major lobe will develop in the horizontal plane, parallel to the two elements (c) A major lobe will develop in the vertical plane, away from the ground (d) The radiation pattern will not be affected

Answer 91

B-006-009-004 If a parasitic element slightly longer than a horizontal dipole antenna is placed parallel to the dipole 0.1 wavelength from it and at the same height, what effect will this have on the antenna's radiation pattern? (a) A major lobe will develop in the horizontal plane, from the parasitic element toward the dipole

Question 92

B-006-009-005 The property of an antenna, which defines the range of frequencies to which it will respond, is called its: (a) front-to-back ratio (b) bandwidth (c) impedance (d) polarization

Answer 92

B-006-009-005 The property of an antenna, which defines the range of frequencies to which it will respond, is called its: (b) bandwidth

Question 93

B-006-009-006 Approximately how much gain does a half-wave dipole have over an isotropic radiator? (a) 1.5 dB (b) 3.0 dB (c) 6.0 dB (d) 2.1 dB

Answer 93

B-006-009-006 Approximately how much gain does a half-wave dipole have over an isotropic radiator? (d) 2.1 dB

Question 94

B-006-009-007 What is meant by antenna gain? (a) The numerical ratio of the signal in the forward direction to the signal in the back direction (b) The numerical ratio of the amount of power radiated by an antenna compared to the transmitter output power (c) The numerical ratio relating the radiated signal strength of an antenna to that of another antenna (d) The power amplifier gain minus the transmission line losses

Answer 94

B-006-009-007 What is meant by antenna gain? (c) The numerical ratio relating the radiated signal strength of an antenna to that of another antenna

Question 95

B-006-009-008 What is meant by antenna bandwidth? (a) The frequency range over which the antenna may be expected to perform well (b) Antenna length divided by the number of elements (c) The angle between the half-power radiation points (d) The angle formed between two imaginary lines drawn through the ends of the elements

Answer 95

B-006-009-008 What is meant by antenna bandwidth? (a) The frequency range over which the antenna may be expected to perform well

Question 96

B-006-009-009 In free space, what is the radiation characteristic of a half-wave dipole? (a) Maximum radiation from the ends, minimum broadside (b) Minimum radiation from the ends, maximum broadside (c) Omnidirectional (d) Maximum radiation at 45 degrees to the plane of the antenna

Answer 96

B-006-009-009 In free space, what is the radiation characteristic of a half-wave dipole? (b) Minimum radiation from the ends, maximum broadside

Question 97

B-006-009-010 The gain of an antenna, especially on VHF and above, is quoted in dBi. The "i" in this expression stands for: (a) isotropic (b) ideal (c) ionosphere (d) interpolated

Answer 97

B-006-009-010 The gain of an antenna, especially on VHF and above, is quoted in dBi. The "i" in this expression stands for: (a) isotropic

Question 98

B-006-009-011 The front-to-back ratio of a beam antenna is: (a) the forward power of the major lobe to the power in the backward direction both being measured at the 3 dB points (b) undefined (c) the ratio of the forward power at the 3 dB points to the power radiated in the backward direction (d) the ratio of the maximum forward power in the major lobe to the maximum backward power radiation

Answer 98

B-006-009-011 The front-to-back ratio of a beam antenna is: (d) the ratio of the maximum forward power in the major lobe to the maximum backward power radiation

Question 99

B-006-010-001 How do you calculate the length in metres (feet) of a quarter-wavelength antenna using frequencies below 30MHz? (a) Divide 468 (1532) by the antenna's operating frequency in MHz (b) Divide 71.5 (234) by the antenna's operating frequency in MHz (c) Divide 300 (982) by the antenna's operating frequency in MHz (d) Divide 150 (491) by the antenna's operating frequency in MHz

Answer 99

B-006-010-001 How do you calculate the length in metres (feet) of a quarter-wavelength antenna using frequencies below 30MHz? (b) Divide 71.5 (234) by the antenna's operating frequency in MHz

Question 100

B-006-010-002 If you made a quarter-wavelength vertical antenna for 21.125 MHz, how long would it be? (a) 3.6 metres (11.8 ft) (b) 3.36 metres (11.0 ft) (c) 7.2 metres (23.6 ft) (d) 6.76 metres (22.2 ft)

Answer 100

B-006-010-002 If you made a quarter-wavelength vertical antenna for 21.125 MHz, how long would it be? (b) 3.36 metres (11.0 ft)

Question 101

B-006-010-003 If you made a half-wavelength vertical antenna for 223 MHz, how long would it be? (a) 67 cm (26.4 in) (b) 128 cm (50.4 in) (c) 105 cm (41.3 in) (d) 134.6 cm (53 in)

Answer 101

B-006-010-003 If you made a half-wavelength vertical antenna for 223 MHz, how long would it be? (a) 67 cm (26.4 in)

Question 102

B-006-010-004 Why is a 5/8-wavelength vertical antenna better than a 1/4-wavelength vertical antenna for VHF or UHF mobile operations? (a) A 5/8-wavelength antenna has less corona loss (b) A 5/8-wavelength antenna is easier to install on a car (c) A 5/8-wavelength antenna can handle more power (d) A 5/8-wavelength antenna has more gain

Answer 102

B-006-010-004 Why is a 5/8-wavelength vertical antenna better than a 1/4-wavelength vertical antenna for VHF or UHF mobile operations? (d) A 5/8-wavelength antenna has more gain

Question 103

B-006-010-005 If a magnetic-base whip antenna is placed on the roof of a car, in what direction does it send out radio energy? (a) It goes out equally well in all horizontal directions (b) Most of it is aimed high into the sky (c) Most of it goes equally in two opposite directions (d) Most of it goes in one direction

Answer 103

B-006-010-005 If a magnetic-base whip antenna is placed on the roof of a car, in what direction does it send out radio energy? (a) It goes out equally well in all horizontal directions

Question 104

B-006-010-006 What is an advantage of downward sloping radials on a ground plane antenna? (a) It increases the radiation angle (b) It brings the feed point impedance closer to 300 ohms (c) It brings the feed point impedance closer to 50 ohms (d) It lowers the radiation angle

Answer 104

B-006-010-006 What is an advantage of downward sloping radials on a ground plane antenna? (c) It brings the feed point impedance closer to 50 ohms

Question 105

B-006-010-007 What happens to the feed point impedance of a ground-plane antenna when its radials are changed from horizontal to downward-sloping? (a) It decreases (b) It increases (c) It stays the same (d) It approaches zero

Answer 105

B-006-010-007 What happens to the feed point impedance of a ground-plane antenna when its radials are changed from horizontal to downward-sloping? (b) It increases

Question 106

B-006-010-008 Which of the following transmission lines will give the best match to the base of a quarter-wave ground-plane antenna? (a) 50 ohms coaxial cable (b) 300 ohms balanced transmission line (c) 75 ohms balanced transmission line (d) 300 ohms coaxial cable

Answer 106

B-006-010-008 Which of the following transmission lines will give the best match to the base of a quarter-wave ground-plane antenna? (a) 50 ohms coaxial cable

Question 107

B-006-010-009 The main characteristic of a vertical antenna is that it will: (a) be very sensitive to signals coming from horizontal antennas (b) require few insulators (c) be easy to feed with TV ribbon transmission line (d) receive signals equally well from all compass points around it

Answer 107

B-006-010-009 The main characteristic of a vertical antenna is that it will: (d) receive signals equally well from all compass points around it

Question 108

B-006-010-010 Why is a loading coil often used with an HF mobile vertical antenna? (a) To lower the losses (b) To tune out capacitive reactance (c) To lower the Q (d) To filter out electrical noise

Answer 108

B-006-010-010 Why is a loading coil often used with an HF mobile vertical antenna? (b) To tune out capacitive reactance

Question 109

B-006-010-011 What is the main reason why so many VHF base and mobile antennas are 5/8 of a wavelength? (a) The angle of radiation is high giving excellent local coverage (b) It is easy to match the antenna to the transmitter (c) It's a convenient length on VHF (d) The angle of radiation is low

Answer 109

B-006-010-011 What is the main reason why so many VHF base and mobile antennas are 5/8 of a wavelength? (d) The angle of radiation is low

Question 110

B-006-011-001 How many directly driven elements do most Yagi antennas have? (a) Two (b) One (c) Three (d) None

Answer 110

B-006-011-001 How many directly driven elements do most Yagi antennas have? (b) One

Question 111

B-006-011-002 Approximately how long is the driven element of a Yagi antenna for 14.0 MHz? (a) 5.21 metres (17 feet) (b) 10.21 metres (33.5 feet) (c) 10.67 metres (35 feet) (d) 20.12 metres (66 feet)

Answer 111

B-006-011-002 Approximately how long is the driven element of a Yagi antenna for 14.0 MHz? (b) 10.21 metres (33.5 feet)

Question 112

B-006-011-003 Approximately how long is the director element of a Yagi antenna for 21.1 MHz? (a) 5.18 metres (17 feet) (b) 3.2 metres (10.5 feet) (c) 12.8 metres (42 feet) (d) 6.4 metres (21 feet)

Answer 112

B-006-011-003 Approximately how long is the director element of a Yagi antenna for 21.1 MHz? (d) 6.4 metres (21 feet)

Question 113

B-006-011-004 Approximately how long is the reflector element of a Yagi antenna for 28.1 MHz? (a) 4.88 metres (16 feet) (b) 10.67 metres (35 feet) (c) 2.66 metres (8.75 feet) (d) 5.33 metres (17.5 feet)

Answer 113

B-006-011-004 Approximately how long is the reflector element of a Yagi antenna for 28.1 MHz? (d) 5.33 metres (17.5 feet)

Question 114

B-006-011-005 What is one effect of increasing the boom length and adding directors to a Yagi antenna? (a) SWR increases (b) Weight decreases (c) Gain increases (d) Wind load decreases

Answer 114

B-006-011-005 What is one effect of increasing the boom length and adding directors to a Yagi antenna? (c) Gain increases

Question 115

B-006-011-006 What are some advantages of a Yagi with wide element spacing? (a) High gain, lower loss and a low SWR (b) High front-to-back ratio and lower input resistance (c) High gain, less critical tuning and wider bandwidth (d) Shorter boom length, lower weight and wind resistance

Answer 115

B-006-011-006 What are some advantages of a Yagi with wide element spacing? (c) High gain, less critical tuning and wider bandwidth

Question 116

B-006-011-007 Why is a Yagi antenna often used for radiocommunications on the 20-metre band? (a) It helps reduce interference from other stations off to the side or behind (b) It provides excellent omnidirectional coverage in the horizontal plane (c) It is smaller, less expensive and easier to erect than a dipole or vertical antenna (d) It provides the highest possible angle of radiation for the HF bands

Answer 116

B-006-011-007 Why is a Yagi antenna often used for radiocommunications on the 20-metre band? (a) It helps reduce interference from other stations off to the side or behind

Question 117

B-006-011-008 What does "antenna front-to-back ratio" mean in reference to a Yagi antenna? (a) The relative position of the driven element with respect to the reflectors and directors (b) The power radiated in the major radiation lobe compared to the power radiated 90 degrees away from that direction (c) The number of directors versus the number of reflectors (d) The power radiated in the major radiation lobe compared to the power radiated in exactly the opposite direction

Answer 117

B-006-011-008 What does "antenna front-to-back ratio" mean in reference to a Yagi antenna? (d) The power radiated in the major radiation lobe compared to the power radiated in exactly the opposite direction

Question 118

B-006-011-009 What is a good way to get maximum performance from a Yagi antenna? (a) Optimize the lengths and spacing of the elements (b) Use RG-58 transmission line (c) Use a reactance bridge to measure the antenna performance from each direction around the antenna (d) Avoid using towers higher than 9 metres (30 feet) above the ground

Answer 118

B-006-011-009 What is a good way to get maximum performance from a Yagi antenna? (a) Optimize the lengths and spacing of the elements

Question 119

B-006-011-010 The spacing between the elements on a three-element Yagi antenna, representing the best overall choice, is _____ of a wavelength. (a) 0.10 (b) 0.50 (c) 0.75 (d) 0.20

Answer 119

B-006-011-010 The spacing between the elements on a three-element Yagi antenna, representing the best overall choice, is _____ of a wavelength. (d) 0.20

Question 120

B-006-011-011 If the forward gain of a six-element Yagi is about 10 dBi, what would the gain of two of these antennas be if they were "stacked"? (a) 13 dBi (b) 7 dBi (c) 20 dBi (d) 10 dBi

Answer 120

B-006-011-011 If the forward gain of a six-element Yagi is about 10 dBi, what would the gain of two of these antennas be if they were "stacked"? (a) 13 dBi

Question 121

B-006-012-001 If you made a half-wavelength dipole antenna for 28.150 MHz, how long would it be? (a) 10.5 metres (34.37 ft) (b) 28.55 metres (93.45 ft) (c) 5.08 metres (16.62 ft) (d) 10.16 metres (33.26 ft)

Answer 121

B-006-012-001 If you made a half-wavelength dipole antenna for 28.150 MHz, how long would it be? (c) 5.08 metres (16.62 ft)

Question 122

B-006-012-002 What is one disadvantage of a random wire antenna? (a) You may experience RF feedback in your station (b) It usually produces vertically polarized radiation (c) It must be longer than 1 wavelength (d) You must use an inverted T matching network for multi-band operation

Answer 122

B-006-012-002 What is one disadvantage of a random wire antenna? (a) You may experience RF feedback in your station

Question 123

B-006-012-003 What is the low angle radiation pattern of an ideal half-wavelength dipole HF antenna in free space installed parallel to the Earth? (a) It is a circle (equal radiation in all directions) (b) It is a figure-eight, perpendicular to the antenna (c) It is two smaller lobes on one side of the antenna, and one larger lobe on the other side (d) It is a figure-eight, off both ends of the antenna

Answer 123

B-006-012-003 What is the low angle radiation pattern of an ideal half-wavelength dipole HF antenna in free space installed parallel to the Earth? (b) It is a figure-eight, perpendicular to the antenna

Question 124

B-006-012-004 The impedances in ohms at the feed point of the dipole and folded dipole in free space are, respectively: (a) 73 and 150 (b) 73 and 300 (c) 52 and 100 (d) 52 and 200

Answer 124

B-006-012-004 The impedances in ohms at the feed point of the dipole and folded dipole in free space are, respectively: (b) 73 and 300

Question 125

B-006-012-005 A horizontal dipole transmitting antenna, installed at an ideal height so that the ends are pointing North/South, radiates: (a) mostly to the South and North (b) mostly to the South (c) equally in all directions (d) mostly to the East and West

Answer 125

B-006-012-005 A horizontal dipole transmitting antenna, installed at an ideal height so that the ends are pointing North/South, radiates: (d) mostly to the East and West

Question 126

B-006-012-006 How does the bandwidth of a folded dipole antenna compare with that of a simple dipole antenna? (a) It is greater (b) It is essentially the same (c) It is less than 50% (d) It is 0.707 times the bandwidth

Answer 126

B-006-012-006 How does the bandwidth of a folded dipole antenna compare with that of a simple dipole antenna? (a) It is greater

Question 127

B-006-012-007 What is a disadvantage of using an antenna equipped with traps? (a) It may radiate harmonics more readily (b) It is too sharply directional at lower frequencies (c) It must be neutralized (d) It can only be used for one band

Answer 127

B-006-012-007 What is a disadvantage of using an antenna equipped with traps? (a) It may radiate harmonics more readily

Question 128

B-006-012-008 What is an advantage of using a trap antenna? (a) It has high directivity at the higher frequencies (b) It has high gain (c) It minimizes harmonic radiation (d) It may be used for multi-band operation

Answer 128

B-006-012-008 What is an advantage of using a trap antenna? (d) It may be used for multi-band operation

Question 129

B-006-012-009 If you were to cut a half wave dipole for 3.75 MHz, what would be its approximate length? (a) 32 meters (105 ft) (b) 45 meters (145 ft) (c) 38 meters (125 ft) (d) 75 meters (245 ft)

Answer 129

B-006-012-009 If you were to cut a half wave dipole for 3.75 MHz, what would be its approximate length? (c) 38 meters (125 ft)

Question 130

B-006-013-001 What is a cubical quad antenna? (a) A center-fed wire 1/2-electrical wavelength long (b) Two or more parallel four-sided wire loops, each approximately one-electrical wavelength long (c) A vertical conductor 1/4-electrical wavelength high, fed at the bottom (d) Four straight, parallel elements in line with each other, each approximately 1/2-electrical wavelength long

Answer 130

B-006-013-001 What is a cubical quad antenna? (b) Two or more parallel four-sided wire loops, each approximately one-electrical wavelength long

Question 131

B-006-013-002 What is a delta loop antenna? (a) A large copper ring or wire loop, used in direction finding (b) An antenna whose elements are each a three sided loop whose total length is approximately one electrical wavelength (c) An antenna system made of three vertical antennas, arranged in a triangular shape (d) An antenna made from several triangular coils of wire on an insulating form

Answer 131

B-006-013-002 What is a delta loop antenna? (b) An antenna whose elements are each a three sided loop whose total length is approximately one electrical wavelength

Question 132

B-006-013-003 Approximately how long is each side of a cubical quad antenna driven element for 21.4 MHz? (a) 0.36 metres (1.17 feet) (b) 14.33 metres (47 feet) (c) 143 metres (469 feet) (d) 3.54 metres (11.7 feet)

Answer 132

B-006-013-003 Approximately how long is each side of a cubical quad antenna driven element for 21.4 MHz? (d) 3.54 metres (11.7 feet)

Question 133

B-006-013-004 Approximately how long is each side of a cubical quad antenna driven element for 14.3 MHz? (a) 21.43 metres (70.3 feet) (b) 5.36 metres (17.6 feet) (c) 53.34 metres (175 feet) (d) 7.13 metres (23.4 feet)

Answer 133

B-006-013-004 Approximately how long is each side of a cubical quad antenna driven element for 14.3 MHz? (b) 5.36 metres (17.6 feet)

Question 134

B-006-013-005 Approximately how long is each leg of a symmetrical delta loop antenna driven element for 28.7 MHz? (a) 2.67 metres (8.75 feet) (b) 7.13 metres (23.4 feet) (c) 3.32 metres (10.89 feet) (d) 10.67 metres (35 feet)

Answer 134

B-006-013-005 Approximately how long is each leg of a symmetrical delta loop antenna driven element for 28.7 MHz? (c) 3.32 metres (10.89 feet)

Question 135

B-006-013-006 Which statement about two-element delta loops and quad antennas is true? (a) They perform very well only at HF (b) They are effective only when constructed using insulated wire (c) They compare favourably with a three-element Yagi (d) They perform poorly above HF

Answer 135

B-006-013-006 Which statement about two-element delta loops and quad antennas is true? (c) They compare favourably with a three-element Yagi

Question 136

B-006-013-007 Compared to a dipole antenna, what are the directional radiation characteristics of a cubical quad antenna? (a) The quad has more directivity in the horizontal plane but less directivity in the vertical plane (b) The quad has less directivity in the horizontal plane but more directivity in the vertical plane (c) The quad has more directivity in both horizontal and vertical planes (d) The quad has less directivity in both horizontal and vertical planes

Answer 136

B-006-013-007 Compared to a dipole antenna, what are the directional radiation characteristics of a cubical quad antenna? (c) The quad has more directivity in both horizontal and vertical planes

Question 137

B-006-013-008 Moving the feed point of a multi-element quad antenna from a side parallel to the ground to a side perpendicular to the ground will have what effect? (a) It will change the antenna polarization from vertical to horizontal (b) It will significantly decrease the antenna feed point impedance (c) It will change the antenna polarization from horizontal to vertical (d) It will significantly increase the antenna feed point impedance

Answer 137

B-006-013-008 Moving the feed point of a multi-element quad antenna from a side parallel to the ground to a side perpendicular to the ground will have what effect? (c) It will change the antenna polarization from horizontal to vertical

Question 138

B-006-013-009 What does the term "antenna front-to-back ratio" mean in reference to a delta loop antenna? (a) The power radiated in the major radiation lobe compared to the power radiated in exactly the opposite direction (b) The relative position of the driven element with respect to the reflectors and directors (c) The power radiated in the major radiation lobe compared to the power radiated 90 degrees away from that direction (d) The number of directors versus the number of reflectors

Answer 138

B-006-013-009 What does the term "antenna front-to-back ratio" mean in reference to a delta loop antenna? (a) The power radiated in the major radiation lobe compared to the power radiated in exactly the opposite direction

Question 139

B-006-013-010 The cubical "quad" or "quad" antenna consists of two or more square loops of wire. The driven element has an approximate overall length of: (a) three-quarters of a wavelength (b) two wavelengths (c) one-half wavelength (d) one wavelength

Answer 139

B-006-013-010 The cubical "quad" or "quad" antenna consists of two or more square loops of wire. The driven element has an approximate overall length of: (d) one wavelength

Question 140

B-006-013-011 The delta loop antenna consists of two or more triangular structures mounted on a boom. The overall length of the driven element is approximately: (a) one-quarter of a wavelength (b) one wavelength (c) two wavelengths (d) one-half of a wavelength

Answer 140

B-006-013-011 The delta loop antenna consists of two or more triangular structures mounted on a boom. The overall length of the driven element is approximately: (b) one wavelength