2008 Extra Class Question Pool Converted to plain text by Handihams on 03 January 2008. The 2008 Element 4 (Extra Class) question pool is hereby released to public use. This pool will become effective for examinations given on or after July 1, 2008, and will remain active until replaced by a subsequent version. As of this writing, this pool is scheduled to be in service until June 30, 2012. Whenever possible, we have included references to the FCC rules for most of the questions in section E1. The citations are included only as a guideline, and while the QPC has made reasonable efforts to insure accuracy, we do not guarantee that such citations are accurate and/or complete. Any graphics required for the questions are included at the end of this document, or are available as a separate file from NCVEC.ORG To assist in viewing fine details of some of the drawings associated with certain questions, we recommend increasing the "zoom" factor to 200% (or larger) when viewing the associated graphic. While every effort was made to insure the accuracy of the material herein, this material was prepared by ordinary human beings, and there is always the possibility that a few typographical or other errors may remain. Users are authorized to make whatever typographic corrections that may be needed, keeping in mind that the basic meaning of a question, answer, or distractor must remain intact. The QPC would appreciate notification of any such errors. There are 741 questions in the pool as released. Please refer any questions to the QPC, by e-mail, to QPC@NCVEC.ORG 20 December 2008 Jim Wiley, KL7CC Chairman, NCVEC Question Pool Committee Anchorage VEC QPC members: Roland Anders, K3RA, Laurel VEC Perry Green, WY1O, ARRL VEC Larry Pollock, NB5X, W5YI VEC The QPC would like to make special note of the assistance provided by: Tom Fuszard, KF9PU, Milwaukee VEC Gordon West, WB6NOA Ward Silver, N0AX, ARRL John Johnson, W3BE WCARS VEC GLAARG VEC Michael Fox, W6MJF Pete Trotter, Master Publishing We also acknowledge assistance from: The ARRL (several persons) Proof-readers from many different VECs Interested hams everywhere who submitted questions and comments, many of which were adopted into this new pool ELEMENT 4 - EXTRA CLASS QUESTION POOL Valid July 1, 2008 through June 30, 2012 SYLLABUS SUBELEMENT E1 -– COMMISSION’S RULES [6 Exam Questions -- 6 Groups] E1A Operating Standards: frequency privileges for Extra Class amateurs; emission standards; automatic message forwarding; frequency sharing; FCC license actions; stations aboard ships or aircraft E1B Station restrictions and special operations: restrictions on station location; general operating restrictions, spurious emissions, control operator reimbursement; antenna structure restrictions; RACES operations E1C Station control: definitions and restrictions pertaining to local, automatic and remote control operation; control operator responsibilities for remote and automatically controlled stations E1D Amateur Satellite service: definitions and purpose; license requirements for space stations; available frequencies and bands; telecommand and telemetry operations; restrictions, and special provisions; notification requirements E1E Volunteer examiner program: definitions, qualifications, preparation and administration of exams; accreditation; question pools; documentation requirements E1F Miscellaneous rules: external RF power amplifiers; Line A; national quiet zone; business communications; compensated communications; spread spectrum; auxiliary stations; reciprocal operating privileges; IARP and CEPT licenses; third party communications with foreign countries; special temporary authority SUBELEMENT E2 - OPERATING PRACTICES AND PROCEDURES [5 Exam Questions - 5 Groups] E2A Amateur radio in space: amateur satellites; orbital mechanics; frequencies and modes; satellite hardware; satellite operations E2B Television practices: fast scan television standards and techniques; slow scan television standards and techniques E2C Operating methods, part 1: contest and DX operating; spread-spectrum transmissions; automatic HF forwarding; selecting an operating frequency E2D Operating methods, part 2: VHF and UHF digital modes; packet clusters; Automatic Position Reporting System (APRS) E2E Operating methods, part 3: operating HF digital modes; error correction SUBELEMENT E3 -- RADIO WAVE PROPAGATION [3 Exam Questions -- 3 Groups] E3A Propagation and technique, part 1: Earth-Moon-Earth communications; meteor scatter E3B Propagation and technique, part 2: transequatorial; long path; gray line; multi-path propagation E3C Propagation and technique, part 3: Auroral propagation; selective fading; radio-path horizon; take-off angle over flat or sloping terrain; earth effects on propagation; less common propagation modes SUBELEMENT E4 -- AMATEUR RADIO TECHNOLOGY AND MEASUREMENTS [5 Exam Questions -- 5 Groups] E4A Test equipment: analog and digital instruments; spectrum and network analyzers, antenna analyzers; oscilloscopes; testing transistors; RF measurements E4B Measurement technique and limitations: instrument accuracy and performance limitations; probes; techniques to minimize errors; measurement of "Q"; instrument calibration E4C Receiver performance characteristics, part 1: phase noise, capture effect, noise floor, image rejection, MDS, signal-to-noise-ratio; selectivity E4D Receiver performance characteristics, part 2: blocking dynamic range, intermodulation and cross-modulation interference; 3rd order intercept; desensitization; preselection E4E Noise suppression: system noise; electrical appliance noise; line noise; locating noise sources; DSP noise reduction; noise blankers SUBELEMENT E5 -- ELECTRICAL PRINCIPLES [4 Exam Questions -- 4 Groups] E5A Resonance and Q: characteristics of resonant circuits: series and parallel resonance; Q; half-power bandwidth; phase relationships in reactive circuits E5B Time constants and phase relationships: R/L/C time constants: definition; time constants in RL and RC circuits; phase angle between voltage and current; phase angles of series and parallel circuits E5C Impedance plots and coordinate systems: plotting impedances in polar coordinates; rectangular coordinates E5D AC and RF energy in real circuits: skin effect; electrostatic and electromagnetic fields; reactive power; power factor; coordinate systems SUBELEMENT E6 -- CIRCUIT COMPONENTS [6 Exam Questions -- 6 Groups] E6A Semiconductor materials and devices: semiconductor materials (germanium, silicon, P-type, N-type); transistor types: NPN, PNP, junction, power; field-effect transistors: enhancement mode; depletion mode; MOS; CMOS; N-channel; P-channel E6B Semiconductor diodes E6C Integrated circuits: TTL digital integrated circuits; CMOS digital integrated circuits; gates E6D Optical devices and toroids: vidicon and cathode-ray tube devices; charge-coupled devices (CCDs); liquid crystal displays (LCDs); toroids: permeability, core material, selecting, winding E6E Piezoelectric crystals and MMICS: quartz crystals (as used in oscillators and filters); monolithic amplifiers (MMICs) E6F Optical components and power systems: photoconductive principles and effects, photovoltaic systems, optical couplers, optical sensors, and optoisolators SUBELEMENT E7 -- PRACTICAL CIRCUITS [8 Exam Questions -- 8 Groups] E7 Digital circuits: digital circuit principles and logic circuits: classes of logic elements; positive and negative logic; frequency dividers; truth tables E7B Amplifiers: Class of operation; vacuum tube and solid-state circuits; distortion and intermodulation; spurious and parasitic suppression; microwave amplifiers E7C Filters and matching networks: filters and impedance matching networks: types of networks; types of filters; filter applications; filter characteristics; impedance matching; DSP filtering E7D Power supplies and voltage regulators E7E Modulation and demodulation: reactance, phase and balanced modulators; detectors; mixer stages; DSP modulation and demodulation; software defined radio systems E7F Frequency markers and counters: frequency divider circuits; frequency marker generators; frequency counters E7G Active filters and op-amps: active audio filters; characteristics; basic circuit design; operational amplifiers E7H Oscillators and signal sources: types of oscillators; synthesizers and phase-locked loops; direct digital synthesizers SUBELEMENT E8 -- SIGNALS AND EMISSIONS [4 Exam Questions -- 4 Groups] E8A AC waveforms: sine, square, sawtooth and irregular waveforms; AC measurements; average and PEP of RF signals; pulse and digital signal waveforms E8B Modulation and demodulation: modulation methods; modulation index and deviation ratio; pulse modulation; frequency and time division multiplexing E8C Digital signals: digital communications modes; CW; information rate vs. bandwidth; spread-spectrum communications; modulation methods E8D Waves, measurements, and RF grounding: peak-to-peak values, polarization; RF grounding SUBELEMENT E9 -– ANTENNAS AND TRANSMISSION LINES [8 Exam Questions -- 8 Groups] E9A Isotropic and gain antennas: definition; used as a standard for comparison; radiation pattern; basic antenna parameters: radiation resistance and reactance, gain, beamwidth, efficiency E9B Antenna patterns: E and H plane patterns; gain as a function of pattern; antenna design (computer modeling of antennas); Yagi antennas E9C Wire and phased vertical antennas: beverage antennas; terminated and resonant rhombic antennas; elevation above real ground; ground effects as related to polarization; take-off angles E9D Directional antennas: gain; satellite antennas; antenna beamwidth; losses; SWR bandwidth; antenna efficiency; shortened and mobile antennas; grounding E9E Matching: matching antennas to feed lines; power dividers E9F Transmission lines: characteristics of open and shorted feed lines: 1/8 wavelength; 1/4 wavelength; 1/2 wavelength; feed lines: coax versus open-wire; velocity factor; electrical length; transformation characteristics of line terminated in impedance not equal to characteristic impedance E9G The Smith chart E9F Transmission lines: characteristics of open and shorted feed lines: 1/8 wavelength; 1/4 wavelength; 1/2 wavelength; feed lines: coax versus open-wire; velocity factor; electrical length; transformation characteristics of line terminated in impedance not equal to characteristic impedance SUBELEMENT E0 -– [1 exam question -– 1 group] E0A Safety: amateur radio safety practices; RF radiation hazards; hazardous materials ELEMENT 4 - EXTRA CLASS QUESTION POOL Valid July 1, 2008 through June 30, 2012 741 questions total SUBELEMENT E1 -– COMMISSION’S RULES [6 Exam Questions -- 6 Groups] E1A Operating Standards: frequency privileges for Extra Class amateurs; emission standards; automatic message forwarding; frequency sharing; FCC license actions; stations aboard ships or aircraft E1A01 (D) When using a transceiver that displays the carrier frequency of phone signals, which of the following displayed frequencies will result in a normal USB emission being within the band? D. 3 kHz below the upper band edge E1A02 (D) When using a transceiver that displays the carrier frequency of phone signals, which of the following displayed frequencies will result in a normal LSB emission being within the band? D. 3 kHz above the lower band edge E1A03 (C) With your transceiver displaying the carrier frequency of phone signals, you hear a DX station's CQ on 14.349 MHz USB. Is it legal to return the call using upper sideband on the same frequency? C. No, my sidebands will extend beyond the band edge E1A04 (C) With your transceiver displaying the carrier frequency of phone signals, you hear a DX station's CQ on 3.601 MHz LSB. Is it legal to return the call using lower sideband on the same frequency? C. No, my sidebands will extend beyond the edge of the phone band segment E1A05 (C) Which is the only amateur band that does not permit the transmission of phone or image emissions? C. 30 meters E1A06 (B) What is the maximum power output permitted on the 60 meter band? B. 50 watts PEP effective radiated power relative to a dipole E1A07 (D) What is the only amateur band where transmission on specific channels rather than a range of frequencies is permitted? D. 60 meter band E1A08 (C) What is the only emission type permitted to be transmitted on the 60 meter band by an amateur station? C. Single sideband, upper sideband only E1A09 (A) Which frequency bands contain at least one segment authorized only to control operators holding an Amateur Extra Class operator license? A. 80/75, 40, 20 and 15 meters E1A10 (B) If a station in a message forwarding system inadvertently forwards a message that is in violation of FCC rules, who is primarily accountable for the rules violation? B. The control operator of the originating station E1A11 (A) What is the first action you should take if your digital message forwarding station inadvertently forwards a communication that violates FCC rules? A. Discontinue forwarding the communication as soon as you become aware of it E1A12 (A) If an amateur station is installed on board a ship or aircraft, what condition must be met before the station is operated? A. Its operation must be approved by the master of the ship or the pilot in command of the aircraft E1A13 (B) When a US-registered vessel is in international waters, what type of FCC-issued license or permit is required to transmit amateur communications from an on-board amateur transmitter? B. Any amateur license or reciprocal permit for alien amateur licensee E1B Station restrictions and special operations: restrictions on station location; general operating restrictions, spurious emissions, control operator reimbursement; antenna structure restrictions; RACES operations E1B01 (D) Which of the following constitutes a spurious emission? D. An emission outside its necessary bandwidth that can be reduced or eliminated without affecting the information transmitted E1B02 (D) Which of the following factors might cause the physical location of an amateur station apparatus or antenna structure to be restricted? D. The location is significant to our environment, American history, architecture, or culture. E1B03 (A) Within what distance must an amateur station protect an FCC monitoring facility from harmful interference? A. 1 mile E1B04 (C) What must be done before placing an amateur station within an officially designated wilderness area or wildlife preserve, or an area listed in the National Register of Historical Places? C. An Environmental Assessment must be submitted to the FCC E1B05 (B) What height restrictions apply to an amateur station antenna structure not close to a public use airport unless the FAA is notified and it is registered with the FCC? B. It must be no higher than 200 feet above ground level at its site E1B06 (A) Which of the following additional rules apply if you are installing an amateur station antenna at a site within 20,000 feet of a public use airport? A. You may have to notify the Federal Aviation Administration and register it with the FCC E1B07 (A) Whose approval is required before erecting an amateur station antenna located at or near a public use airport if the antenna would exceed a certain height depending upon the antenna’s distance from the nearest active runway? A. The FAA must be notified and it must be registered with the FCC E1B08 (D) On what frequencies may the operation of an amateur station be restricted if its emissions cause interference to the reception of a domestic broadcast station on a receiver of good engineering design? D. On the interfering amateur service transmitting frequencies E1B09 (B) What is the Radio Amateur Civil Emergency Service (RACES)? B. A radio service of amateur stations for civil defense communications during periods of local, regional, or national civil emergencies E1B10 (C) Which amateur stations may be operated in RACES? C. Any FCC-licensed amateur station certified by the responsible civil defense organization for the area served E1B11 (A) What frequencies are normally authorized to an amateur station participating in RACES? A. All amateur service frequencies otherwise authorized to the control operator E1B12 (B) What are the frequencies authorized to an amateur station participating in RACES during a period when the President's War Emergency Powers are in force? B. Specific amateur service frequency segments authorized in FCC Part 214 E1B13 (C) What communications are permissible in RACES? C. Authorized civil defense emergency communications affecting the immediate safety of life and property E1C LOCAL, REMOTE AND AUTOMATIC CONTROL – 10 questions Definitions and restrictions pertaining to local, automatic and remote control operation; amateur radio and the Internet; control operator responsibilities for remote and automatically controlled stations E1C01 (D) What is a remotely controlled station? D. A station controlled indirectly through a control link E1C02 (A) What is meant by automatic control of a station? A. The use of devices and procedures for control so that the control operator does not have to be present at a control point E1C03 (B) How do the control operator responsibilities of a station under automatic control differ from one under local control? B. Under automatic control the control operator is not required to be present at the control point E1C04 (B) [97.109] When may an automatically controlled station retransmit third party communications? B. Only when transmitting RTTY or data emissions E1C05 (A) When may an automatically controlled station originate third party communications? A. Never E1C06 (C) Which of the following statements concerning remotely controlled amateur stations is true? C. A control operator must be present at the control point E1C07 (C) What is meant by local control? C. Direct manipulation of the transmitter by a control operator E1C08 (B) What is the maximum permissible duration of a remotely controlled station’s transmissions if its control link malfunctions? B. 3 minutes E1C09 (D) Which of these frequencies are available for automatically controlled ground-station repeater operation? D. 29.500 - 29.700 MHz E1C10 (B) What types of amateur stations may automatically retransmit the radio signals of other amateur stations? B. Only auxiliary, repeater or space stations E1D Amateur Satellite service: definitions and purpose; license requirements for space stations; available frequencies and bands; telecommand and telemetry operations; restrictions, and special provisions; notification requirements E1D01 (A) What is the definition of the term telemetry? A. One-way transmission of measurements at a distance from the measuring instrument E1D02 (C) What is the amateur-satellite service? C. A radio communications service using amateur stations on satellites E1D03 (B) What is a telecommand station in the amateur satellite service? B. An amateur station that transmits communications to initiate, modify or terminate certain functions of a space station E1D04 (A) What is an Earth station in the amateur satellite service? A. An amateur station within 50 km of the Earth's surface for communications with amateur stations by means of objects in space E1D05 (C) What class of licensee is authorized to be the control operator of a space station? C. A holder of any class of license E1D06 (A) Which of the following special provisions must a space station incorporate in order to comply with space station requirements? A. The space station must be capable of effecting a cessation of transmissions by telecommand when so ordered by the FCC E1D07 (A) Which amateur service HF bands have frequencies authorized to space stations? A. Only 40m, 20m, 17m, 15m, 12m and 10m E1D08 (D) Which VHF amateur service bands have frequencies available for space stations? D. 2 meters E1D09 (B) Which amateur service UHF bands have frequencies available for a space station? B. 70 cm, 23 cm, 13 cm E1D10 (B) Which amateur stations are eligible to be telecommand stations? B. Any amateur station so designated by the space station licensee E1D11 (D) Which amateur stations are eligible to operate as Earth stations? D. Any amateur station, subject to the privileges of the class of operator license held by the control operator E1D12 (B) Who must be notified before launching an amateur space station? B. The FCC’s International Bureau, Washington, DC E1E Volunteer examiner program: definitions, qualifications, preparation and administration of exams; accreditation; question pools; documentation requirements E1E01 (D) What is the minimum number of qualified VEs required to administer an Element 4 amateur operator license examination? D. 3 E1E02 (C) Where are the questions for all written US amateur license examinations listed? C. In the VEC-maintained question pool E1E03 (A) Who is responsible for maintaining the question pools from which all amateur license examination questions must be taken? A. All of the VECs E1E04 (C) What is a Volunteer Examiner Coordinator? C. An organization that has entered into an agreement with the FCC to coordinate amateur operator license examinations E1E05 (B) What is a VE? B. An amateur operator who is approved by a VEC to administer amateur operator license examinations E1E06 (A) What is a VE team? A. A group of at least three VEs who administer examinations for an amateur operator license E1E07 (C) Which of the following persons seeking to become VEs cannot be accredited? C. Persons who have ever had an amateur operator or amateur station license suspended or revoked E1E08 (D) Which of the following best describes the Volunteer Examiner accreditation process? D. The procedure by which a VEC confirms that the VE applicant meets FCC requirements to serve as an examiner E1E09 (A) Where must the VE team be while administering an examination? A. All of the administering VEs must be present where they can observe the examinees throughout the entire examination E1E10 (C) Who is responsible for the proper conduct and necessary supervision during an amateur operator license examination session? C. Each administering VE E1E11 (B) What should a VE do if a candidate fails to comply with the examiner’s instructions during an amateur operator license examination? B. Immediately terminate the candidate’s examination E1E12 (C) To which of the following examinees may a VE not administer an examination? A. Employees of the VE B. Friends of the VE C. The VE’s close relatives as listed in the FCC rules D. All these answers are correct E1E13 (A) What may be the penalty for a VE who fraudulently administers or certifies an examination? A. Revocation of the VE’s amateur station license grant and the suspension of the VE’s amateur operator license grant E1E14 (C) What must the VE team do with the examinee’s test papers once they have finished the examination? C. The VE team must collect and grade them immediately E1E15 (B) What must the VE team do if an examinee scores a passing grade on all examination elements needed for an upgrade or new license? B. Three VEs must certify that the examinee is qualified for the license grant and that they have complied with the VE requirements E1E16 (A) What must the VE team do with the application form if the examinee does not pass the exam? A. Return the application document to the examinee E1E17 (A) What are the consequences of failing to appear for re-administration of an examination when so directed by the FCC? A. The licensee's license will be cancelled E1E18 (A) For which types of out-of-pocket expenses may VEs and VECs be reimbursed? A. Preparing, processing, administering and coordinating an examination for an amateur radio license E1E19 (A) How much reimbursement may the VE team and VEC accept for preparing, processing, administering and coordinating an examination? A. Actual out-of-pocket expenses E1E20 (C) What is the minimum age to be a volunteer examiner? C. 18 years old E1F Miscellaneous rules: external RF power amplifiers; Line A; national quiet zone; business communications; compensated communications; spread spectrum; auxiliary stations; reciprocal operating privileges; IARP and CEPT licenses; third party communications with foreign countries; special temporary authority E1F01 (B) On what frequencies are spread spectrum transmissions permitted? B. Only on amateur frequencies above 222 MHz E1F02 (A) Which of the following operating arrangements allows an FCC-licensed US citizen to operate in many European countries, and alien amateurs from many European countries to operate in the US? A. CEPT agreement E1F03 (B) Which of the following operating arrangements allow an FCC-licensed US citizen and many Central and South American amateur operators to operate in each other’s countries? B. IARP agreement E1F04 (B) What does it mean if an external RF amplifier is listed on the FCC database as certificated for use in the amateur service? B. That particular RF amplifier may be marketed for use in the amateur service E1F05 (A) Under what circumstances may a dealer sell an external RF power amplifier capable of operation below 144 MHz if it has not been granted FCC certification? A. It was purchased in used condition from an amateur operator and is sold to another amateur operator for use at that operator's station E1F06 (A) Which of the following geographic descriptions approximately describes "Line A"? A. A line roughly parallel to and south of the US-Canadian border E1F07 (D) Amateur stations may not transmit in which of the following frequency segments if they are located north of Line A? D. 420 - 430 MHz E1F08 (C) What is the National Radio Quiet Zone? C. An area surrounding the National Radio Astronomy Observatory E1F09 (D) When may the control operator of a repeater accept payment for providing communication services to another party? D. Under no circumstances E1F10 (D) When may an amateur station send a message to a business? D. When neither the amateur nor his or her employer has a pecuniary interest in the communications E1F11 (A) Which of the following types of amateur-operator-to-amateur-operator communications are prohibited? A. Communications transmitted for hire or material compensation, except as otherwise provided in the rules E1F12 (D) FCC-licensed amateur stations may use spread spectrum (SS) emissions to communicate under which of the following conditions? A. When the other station is in an area regulated by the FCC B. When the other station is in a country permitting SS communications C. When the transmission is not used to obscure the meaning of any communication D. All of these choices are correct E1F13 (C) What is the maximum transmitter power for an amateur station transmitting spread spectrum communications? C. 100 W E1F14 (D) Which of the following best describes one of the standards that must be met by an external RF power amplifier if it is to qualify for a grant of FCC certification? D. It must satisfy the FCC's spurious emission standards when operated at its full output power E1F15 (B) Who may be the control operator of an auxiliary station? B. Only Technician, General, Advanced or Amateur Extra Class operators E1F16 (C) What types of communications may be transmitted to amateur stations in foreign countries? C. Communications incidental to the purpose of the amateur service and remarks of a personal nature E1F17 (A) Under what circumstances might the FCC issue a "Special Temporary Authority" (STA) to an amateur station? A. To provide for experimental amateur communications SUBELEMENT E2 - OPERATING PRACTICES AND PROCEDURES [5 Exam Questions - 5 Groups] E2A Amateur radio in space: amateur satellites; orbital mechanics; frequencies and modes; satellite hardware; satellite operations E2A01 (C) What is the direction of an ascending pass for an amateur satellite? C. From south to north E2A02 (A) What is the direction of a descending pass for an amateur satellite? A. From north to south E2A03 (C) What is the orbital period of a satellite? C. The time it takes for a satellite to complete one revolution around the Earth E2A04 (B) What is meant by the term “mode” as applied to an amateur radio satellite? B. The satellite's uplink and downlink frequency bands E2A05 (D) What do the letters in a satellite's mode designator specify? D. The uplink and downlink frequencies E2A06 (A) On what band would a satellite receive signals if it were operating in mode U/V? A. 432 MHz E2A07 (D) Which of the following types of signals can be relayed through a linear transponder? A. FM and CW B. SSB and SSTV C. PSK and Packet D. All these answers are correct E2A08 (B) What is the primary reason for satellite users to limit their transmit ERP? B. Because the satellite transmitter output power is limited E2A09 (A) What do the terms L band and S band specify with regard to satellite communications? A. The 23 centimeter and 13 centimeter bands E2A10 (A) Why may the received signal from an amateur satellite exhibit a rapidly repeating fading effect? A. Because the satellite is rotating E2A11 (B) What type of antenna can be used to minimize the effects of spin modulation and Faraday rotation? B. A circularly polarized antenna E2A12 (D) What is one way to predict the location of a satellite at a given time? D. By calculations using the Keplerian elements for the specified satellite E2A13 (B) What type of satellite appears to stay in one position in the sky? B. Geosynchronous E2A14 (B) What happens to a satellite's transmitted signal due to the Doppler Effect? B. The signal frequency shifts lower as the satellite passes overhead E2B Television practices: fast scan television standards and techniques; slow scan television standards and techniques E2B01 (A) How many times per second is a new frame transmitted in a fast-scan (NTSC) television system A. 30 E2B02 (C) How many horizontal lines make up a fast-scan (NTSC) television frame? C. 525 E2B03 (D) How is an interlace scanning pattern generated in a fast-scan (NTSC) television system? D. By scanning odd numbered lines in one field and even numbered ones in the next E2B04 (B) What is blanking in a video signal? B. Turning off the scanning beam while it is traveling from right to left or from bottom to top E2B05 (C) Which of the following is an advantage of using vestigial sideband for standard fast scan TV transmissions? C. Vestigial sideband reduces bandwidth while allowing for simple video detector circuitry E2B06 (A) What is vestigial sideband modulation? A. Amplitude modulation in which one complete sideband and a portion of the other sideband is transmitted E2B07 (B) What is the name of the video signal component that carries color information? B. Chroma E2B08 (D) Which of the following is a common method of transmitting accompanying audio with amateur fast-scan television? A Frequency-modulated sub-carrier B. A separate VHF or UHF audio link C. Frequency modulation of the video carrier D. All of these choices are correct E2B09 (D) What hardware, other than a transceiver with SSB capability and a suitable computer, is needed to decode SSTV based on Digital Radio Mondiale (DRM)? D. No other hardware is needed E2B10 (A) Which of the following is an acceptable bandwidth for Digital Radio Mondiale (DRM) based voice or SSTV digital transmissions made on the HF amateur bands? A. 3 KHz E2B11 (B) What is the function of the Vertical Interval Signaling (VIS) code transmitted as part of an SSTV transmission? B. To identify the SSTV mode being used E2B12 (D) How are analog slow-scan television images typically transmitted on the HF bands? D. Varying tone frequencies representing the video are transmitted using single sideband E2B13 (C) How many lines are commonly used in each frame on an amateur slow-scan color television picture? C. 128 or 256 E2B14 (A) What aspect of an amateur slow-scan television signal encodes the brightness of the picture? A. Tone frequency E2B15 (A) What signals SSTV receiving equipment to begin a new picture line? A. Specific tone frequencies E2B16 (D) Which of the following is the video standard used by North American Fast Scan ATV stations? D. NTSC E2B17 (A) Which of the following is NOT a characteristic of FMTV (Frequency-Modulated Amateur Television) as compared to vestigial sideband AM television? A. Immunity from fading due to limiting E2B18 (B) What is the approximate bandwidth of a slow-scan TV signal? B. 3 kHz E2B19 (D) On which of the following frequencies is one likely to find FMTV transmissions? D. 1255 MHz E2B20 (C) What special operating frequency restrictions are imposed on slow scan TV transmissions? C. They are restricted to phone band segments and their bandwidth can be no greater than that of a voice signal of the same modulation type E2B21 (B) If 100 IRE units correspond to the most-white level in the NTSC standard video format, what is the level of the most-black signal? B. 7.5 IRE units E2C Operating methods, part 1: contest and DX operating; spread-spectrum transmissions; automatic HF forwarding; selecting an operating frequency E2C01 (A) Which of the following is true about contest operating? A. Operators are permitted to make contacts even if they do not submit a log E2C02 (A) Which of the following best describes “self spotting” in regards to contest operating? A. The generally prohibited practice of posting one’s own call sign and frequency on a call sign spotting network E2C03 (A) From which of the following bands is amateur radio contesting generally excluded? A. 30 meters E2C04 (D) On which of the following frequencies is an amateur radio contest contact generally discouraged? D. 146.52 MHz E2C05 (B) Which of the following frequencies would generally be acceptable for U.S. stations to work other U.S. stations in a phone contest? B. 14.310 MHz E2C06 (C) During a VHF/UHF contest, in which band segment would you expect to find the highest level of activity? C. In the weak signal segment of the band, with most of the activity near the calling frequency E2C07 (A) What is the Cabrillo format? A. A standard for organizing information in contest log files E2C08 (A) Why are received spread-spectrum signals resistant to interference? A. Signals not using the spectrum-spreading algorithm are suppressed in the receiver E2C09 (D) How does the spread-spectrum technique of frequency hopping (FH) work? D. The frequency of the transmitted signal is changed very rapidly according to a particular sequence also used by the receiving station E2C10 (D) Why might a phone DX station state that he is listening on another frequency? A. Because the DX station may be transmitting on a frequency that is prohibited to some responding stations B. To separate the calling stations from the DX station C. To reduce interference, thereby improving operating efficiency D. All of these choices are correct E2C11 (A) How should you generally sign your call when attempting to contact a DX station working a “pileup” or in a contest? A. Send your full call sign once or twice E2C12 (B) In North America during low sunspot activity, when signals from Europe become weak and fluttery across an entire HF band two to three hours after sunset, what might help to contact other European DX stations? B. Switch to a lower frequency HF band E2D Operating methods, part 2: VHF and UHF digital modes; packet clusters; Automatic Position Reporting System (APRS) E2D01 (B) What does “command mode” mean in packet operations? B. The TNC is ready to receive instructions via the keyboard E2D02 (A) What is the definition of “baud”? A. The number of data symbols transmitted per second E2D03 (A) Which of the follow is true when comparing HF and 2-meter packet operations? A. HF packet typically uses FSK with a data rate of 300 baud; 2-meter packet uses AFSK with a data rate of 1200 baud E2D04 (C) What is the purpose of digital store-and-forward functions on an Amateur satellite? C. To store digital messages in the satellite for later download by other stations E2D05 (B) Which of the following techniques is normally used by low-earth orbiting digital satellites to relay messages around the world? B. Store-and-forward E2D06 (B) Which of the following is a commonly used 2-meter APRS frequency? B. 144.39 MHz E2D07 (A) Which of the following digital protocols is used by APRS? A. AX.25 E2D08 (D) Which of the following types of packet frames is used to transmit APRS beacon data? D. Unnumbered Information frames E2D09 (D) Under clear communications conditions, which of these digital communications modes has the fastest data throughput? D. 300-baud packet E2D10 (C) How can an APRS station be used to help support a public service communications activity? C. An APRS station with a GPS unit can automatically transmit information to show a mobile station's position during the event E2D11 (D) Which of the following data sources are needed to accurately transmit your geographical location over the APRS network? A. The NMEA-0183 formatted data from a Global Positioning System (GPS) satellite receiver B. The latitude and longitude of your location, preferably in degrees, minutes and seconds, entered into the APRS computer software C. The NMEA-0183 formatted data from a LORAN navigation system D. Any of these choices is correct E2E Operating methods, part 3: operating HF digital modes; error correction E2E01 (B) What is a common method of transmitting data emissions below 30 MHz? B. FSK/AFSK E2E02 (A) What do the letters FEC mean as they relate to digital operation? A. Forward Error Correction E2E03 (C) How is Forward Error Correction implemented? C. By transmitting extra data that may be used to detect and correct transmission errors E2E04 (A) What is indicated when one of the ellipses in an FSK crossed-ellipse display suddenly disappears? A. Selective fading has occurred E2E05 (D) How does ARQ accomplish error correction? D. If errors are detected, a retransmission is requested E2E06 (C) What is the most common data rate used for HF packet communications? C. 300 baud E2E07 (B) What is the typical bandwidth of a properly modulated MFSK16 signal? B. 316 Hz E2E08 (B) Which of the following HF digital modes can be used to transfer binary files? B. PACTOR E2E09 (D) Which of the following HF digital modes uses variable-length coding for bandwidth efficiency? D. PSK31 E2E10 (C) Which of the following HF digital modes use error-correction coding? C. QPSK E2E11 (D) What is the Baudot code? D. The International Telegraph Alphabet Number 2 (ITA2) which uses five data bits E2E12 (C) Which of these digital communications modes has the narrowest bandwidth? C. PSK31 SUBELEMENT E3 -- RADIO WAVE PROPAGATION [3 Exam Questions -- 3 Groups] E3A Propagation and technique, part 1: Earth-Moon-Earth communications (EME); meteor scatter E3A01 (D) What is the approximate maximum separation along the surface of the Earth between two stations communicating by moonbounce? D. 12,000 miles, as long as both can “see” the moon E3A02 (B) What characterizes libration fading of an earth-moon-earth signal? B. A fluttery irregular fading E3A03 (A) When scheduling EME contacts, which of these conditions will generally result in the least path loss? A. When the moon is at perigee E3A04 (D) What type of receiving system is desirable for EME communications? D. Equipment with very low noise figures E3A05 (A) What transmit and receive time sequencing is normally used on 144 MHz when attempting an EME contact? A. Two-minute sequences, where one station transmits for a full two minutes and then receives for the following two minutes E3A06 (C) What transmit and receive time sequencing is normally used on 432 MHz when attempting an EME contact? C. Two-and-one-half minute sequences, where one station transmits for a full 2.5 minutes and then receives for the following 2.5 minutes E3A07 (B) What frequency range would you normally tune to find EME stations in the 2 meter band? B. 144.000 - 144.100 MHz E3A08 (D) What frequency range would you normally tune to find EME stations in the 70 cm band? D. 432.000 - 432.100 MHz E3A09 (A) When a meteor strikes the Earth's atmosphere, a cylindrical region of free electrons is formed at what layer of the ionosphere? A. The E layer E3A10 (C) Which range of frequencies is well suited for meteor-scatter communications? C. 28 - 148 MHz E3A11 (C) What transmit and receive time sequencing is normally used on 144 MHz when attempting a meteor-scatter contact? C. 15-second sequences, where one station transmits for 15 seconds and then receives for the following 15 seconds E3B Propagation and technique, part 2: transequatorial; long path; gray line; multi-path propagation E3B01 (A) What is transequatorial propagation? A. Propagation between two points at approximately the same distance north and south of the magnetic equator E3B02 (C) What is the approximate maximum range for signals using transequatorial propagation? C. 5000 miles E3B03 (C) What is the best time of day for transequatorial propagation? C. Afternoon or early evening E3B04 (A) What type of propagation is probably occurring if an HF beam antenna must be pointed in a direction 180 degrees away from a station to receive the strongest signals? A. Long-path E3B05 (C) Which amateur bands typically support long-path propagation? C. 160 to 10 meters E3B06 (B) Which of the following amateur bands most frequently provides long-path propagation? B. 20 meters E3B07 (D) Which of the following could account for hearing an echo on the received signal of a distant station? D. Receipt of a signal by more than one path E3B08 (D) What type of propagation is probably occurring if radio signals travel along the terminator between daylight and darkness? D. Gray-line E3B09 (A) At what time of day is gray-line propagation most prevalent? A. At sunrise and sunset E3B10 (B) What is the cause of gray-line propagation? B. At twilight, solar absorption drops greatly, while atmospheric ionization is not weakened enough to reduce the MUF E3B11 (C) What communications are possible during gray-line propagation? C. Contacts up to 8,000 to 10,000 miles on three or four HF bands E3C Propagation and technique, part 3: Auroral propagation; selective fading; radio-path horizon; take-off angle over flat or sloping terrain; earth effects on propagation; less common propagation modes E3C01 (D) What effect does auroral activity have on radio communications? D. CW signals have a fluttery tone E3C02 (C) What is the cause of auroral activity? C. The emission of charged particles from the sun E3C03 (D) Where in the ionosphere does auroral activity occur? D. At E-region height E3C04 (A) Which emission mode is best for auroral propagation? A. CW E3C05 (B) What causes selective fading? B. Phase differences in the received signal caused by different paths E3C06 (A) How much farther does the VHF/UHF radio-path horizon distance exceed the geometric horizon? A. By approximately 15% of the distance E3C07 (B) How does the radiation pattern of a 3-element, horizontally polarized beam antenna vary with height above ground? B. The main lobe takeoff angle decreases with increasing height E3C08 (B) What is the name of the high-angle wave in HF propagation that travels for some distance within the F2 region? B. Pedersen ray E3C09 (C) What effect is usually responsible for propagating a VHF signal over 500 miles? C. Tropospheric ducting E3C10 (B) How does the performance of a horizontally polarized antenna mounted on the side of a hill compare with the same antenna mounted on flat ground? B. The main lobe takeoff angle decreases in the downhill direction E3C11 (B) From the contiguous 48 states, in which approximate direction should an antenna be pointed to take maximum advantage of auroral propagation? B. North E3C12 (B) As the frequency of a signal is increased, how does its ground wave propagation change? B. It decreases E3C13 (A) What type of polarization does most ground-wave propagation have? A. Vertical E3C14 (D) Why does the radio-path horizon distance exceed the geometric horizon? D. Radio waves may be bent SUBELEMENT E4 -- AMATEUR RADIO TECHNOLOGY AND MEASUREMENTS [5 Exam Questions -- 5 Groups] E4A Test equipment: analog and digital instruments; spectrum and network analyzers, antenna analyzers; oscilloscopes; testing transistors; RF measurements E4A01 (C) How does a spectrum analyzer differ from a conventional oscilloscope? C. A spectrum analyzer displays signals in the frequency domain; an oscilloscope displays signals in the time domain E4A02 (D) Which of the following parameters would a typical spectrum analyzer display on the horizontal axis? D. Frequency E4A03 (A) Which of the following parameters would a typical spectrum analyzer display on the vertical axis? A. Amplitude E4A04 (A) Which of the following test instruments is used to display spurious signals from a radio transmitter? A. A spectrum analyzer E4A05 (B) Which of the following test instruments is used to display intermodulation distortion products in an SSB transmission? B. A spectrum analyzer E4A06 (D) Which of the following could be determined with a spectrum analyzer? D. All of these choices are correct E4A07 (B) Which of the following is an advantage of using an antenna analyzer vs. a SWR bridge to measure antenna SWR? B. Antenna analyzers typically do not need an external RF source E4A08 (D) Which of the following instruments would be best for measuring the SWR of a beam antenna? D. An antenna analyzer E4A09 (C) Which of the following is most important when adjusting PSK31 transmitting levels? C. ALC level E4A10 (D) Which of the following is a useful test for a functioning NPN transistor in an active circuit where the transistor should be biased "on" ? D. Measure base-to-emitter voltage with a voltmeter; it should be approximately 0.6 to 0.7 volts E4A11 (A) Which of the following test instruments can be used to indicate pulse conditions in a digital logic circuit? A. A logic probe E4A12 (B) Which of the following procedures is an important precaution to follow when connecting a spectrum analyzer to a transmitter output? B. Attenuate the transmitter output going to the spectrum analyzer E4B Measurement technique and limitations: instrument accuracy and performance limitations; probes; techniques to minimize errors; measurement of "Q"; instrument calibration E4B01 (B) Which of the following is a characteristic of a good harmonic frequency marker? B. Frequency stability E4B02 (B) Which of the following factors most affects the accuracy of a frequency counter? B. Time base accuracy E4B03 (C) What is an advantage of using a bridge circuit to measure impedance? C. The measurement is based on obtaining a null in voltage, which can be done very precisely E4B04 (C) If a frequency counter with a specified accuracy of +/- 1.0 ppm reads 146,520,000 Hz, what is the most the actual frequency being measured could differ from the reading? C. 146.52 Hz E4B05 (A) If a frequency counter with a specified accuracy of +/- 0.1 ppm reads 146,520,000 Hz, what is the most the actual frequency being measured could differ from the reading? A. 14.652 Hz E4B06 (D) If a frequency counter with a specified accuracy of +/- 10 ppm reads 146,520,000 Hz, what is the most the actual frequency being measured could differ from the reading? D. 1465.20 Hz E4B07 (D) How much power is being absorbed by the load when a directional power meter connected between a transmitter and a terminating load reads 100 watts forward power and 25 watts reflected power? D. 75 watts E4B08 (A) Which of the following is good practice when using an oscilloscope probe? A. Keep the ground connection of the probe as short as possible E4B09 (C) Which of the following is a characteristic of a good DC voltmeter? C. High impedance input E4B10 (D) What is indicated if the current reading on an RF ammeter placed in series with the antenna feedline of a transmitter increases as the transmitter is tuned to resonance? D. There is more power going into the antenna E4B11 (B) Which of the following describes a method to measure intermodulation distortion in an SSB transmitter? B. Modulate the transmitter with two non-harmonically related audio frequencies and observe the RF output with a spectrum analyzer E4B12 (D) How should a portable SWR analyzer be connected when measuring antenna resonance and feedpoint impedance? D. Connect the antenna feed line directly to the analyzer's connector E4B13 (A) What is the significance of voltmeter sensitivity expressed in ohms per volt? A. The full scale reading of the voltmeter multiplied by its ohms per volt rating will provide the input impedance of the voltmeter E4B14 (A) How is the compensation of an oscilloscope probe typically adjusted? A. A square wave is observed and the probe is adjusted until the horizontal portions of the displayed wave is as nearly flat as possible E4B15 (B) What happens if a dip-meter is too tightly coupled to a tuned circuit being checked? B. A less accurate reading results E4B16 (B) Which of these factors limits the accuracy of a D'Arsonval-type meter? B. Coil impedance E4B17 (C) Which of the following can be used as a relative measurement of the Q for a series-tuned circuit? C. The bandwidth of the circuit's frequency response E4C Receiver performance characteristics, part 1: phase noise, capture effect, noise floor, image rejection, MDS, signal-to-noise-ratio; selectivity E4C01 (D) What is the effect of excessive phase noise in the local oscillator section of a receiver? D. It can cause strong signals on nearby frequencies to interfere with reception of weak signals E4C02 (C) Which of the following is the result of the capture effect in an FM receiver? C. The strongest signal received is the only demodulated signal E4C03 (C) What is the term for the blocking of one FM phone signal by another, stronger FM phone signal? C. Capture effect E4C04 (D) What is meant by the noise floor of a receiver? D. The equivalent input noise power when the antenna is replaced with a matched dummy load E4C05 (B) What does a value of -174 dBm/Hz represent with regard to the noise floor of a receiver? B. The theoretical noise at the input of a perfect receiver at room temperature E4C06 (D) The thermal noise value of a receiver is -174 dBm/Hz. What is the theoretically best minimum detectable signal for a 400 Hz bandwidth receiver? D. -148 dBm E4C07 (B) What does the MDS of a receiver represent? B. The minimum discernible signal E4C08 (B) How might lowering the noise figure affect receiver performance? B. It would increase signal to noise ratio E4C09 (D) Which of the following is most likely to be the limiting condition for sensitivity in a modern communications receiver operating at 14 MHz? D. Atmospheric noise E4C10 (B) Which of the following is a desirable amount of selectivity for an amateur RTTY HF receiver? B. 300 Hz E4C11 (B) Which of the following is a desirable amount of selectivity for an amateur single-sideband phone receiver? B. 2.4 kHz E4C12 (D) What is an undesirable effect of using too wide a filter bandwidth in the IF section of a receiver? D. Undesired signals may be heard E4C13 (C) How does a narrow band roofing filter affect receiver performance? C. It improves dynamic range by keeping strong signals near the receive frequency out of the IF stages E4C14 (D) Which of these choices is a desirable amount of selectivity for an amateur VHF FM receiver? D. 15 kHz E4C15 (D) What is the primary source of noise that can be heard from an HF-band receiver with an antenna connected? D. Atmospheric noise E4D Receiver performance characteristics, part 2: blocking dynamic range, intermodulation and cross-modulation interference; 3rd order intercept; desensitization; preselection E4D01 (A) What is meant by the blocking dynamic range of a receiver? A. The difference in dB between the level of an incoming signal which will cause 1 dB of gain compression, and the level of the noise floor E4D02 (A) Which of the following describes two types of problems caused by poor dynamic range in a communications receiver? A. Cross modulation of the desired signal and desensitization from strong adjacent signals E4D03 (B) How can intermodulation interference between two repeaters occur? B. When the repeaters are in close proximity and the signals mix in one or both transmitter final amplifiers E4D04 (B) What is an effective way to reduce or eliminate intermodulation interference between two repeater transmitters operating in close proximity to one another? B. By installing a properly terminated circulator at the output of the transmitter E4D05 (A) If a receiver tuned to 146.70 MHz receives an intermodulation-product signal whenever a nearby transmitter transmits on 146.52 MHz, what are the two most likely frequencies for the other interfering signal? A. 146.34 MHz and 146.61 MHz E4D06 (D) If the signals of two transmitters mix together in one or both of their final amplifiers, and unwanted signals at the sum and difference frequencies of the original signals are generated, what is this called? D. Intermodulation interference E4D07 (D) Which of the following describes the most significant effect of an off-frequency signal when it is causing cross-modulation interference to a desired signal? D. The off-frequency unwanted signal is heard in addition to the desired signal E4D08 (C) What causes intermodulation in an electronic circuit? C. Nonlinear circuits or devices E4D09 (C) What is the purpose of the preselector in a communications receiver? C. To improve rejection of unwanted signals E4D10 (C) What does a third-order intercept level of 40 dBm mean with respect to receiver performance? C. A pair of 40 dBm signals will theoretically generate the same output on the third order intermodulation frequency as on the input frequency E4D11 (A) Why are third-order intermodulation products within a receiver of particular interest compared to other products? A. The third-order product of two signals which are in the band is itself likely to be within the band E4D12 (A) What is the term for the reduction in receiver sensitivity caused by a strong signal near the received frequency? A. Desensitization E4D13 (B) Which of the following can cause receiver desensitization? B. Strong adjacent-channel signals E4D14 (A) Which of the following is a way to reduce the likelihood of receiver desensitization? A. Decrease the RF bandwidth of the receiver E4E Noise suppression: system noise; electrical appliance noise; line noise; locating noise sources; DSP noise reduction; noise blankers E4E01 (A) Which of the following types of receiver noise can often be reduced by use of a receiver noise blanker? A. Ignition Noise E4E02 (D) Which of the following types of receiver noise can often be reduced with a DSP noise filter? A. Broadband “white” noise B. Ignition noise C. Power line noise D. All of these choices are correct E4E03 (B) Which of the following signals might a receiver noise blanker be able to remove from desired signals? B. Signals which appear correlated across a wide bandwidth E4E04 (D) How can conducted and radiated noise caused by an automobile alternator be suppressed? D. By connecting the radio's power leads directly to the battery and by installing coaxial capacitors in line with the alternator leads E4E05 (B) How can noise from an electric motor be suppressed? B. By installing a brute-force AC-line filter in series with the motor leads E4E06 (B) What is a major cause of atmospheric static? B. Thunderstorms E4E07 (C) How can you determine if line-noise interference is being generated within your home? C. By turning off the AC power line main circuit breaker and listening on a battery-operated radio E4E08 (A) What type of signal is picked up by electrical wiring near a radio transmitter? A. A common-mode signal at the frequency of the radio transmitter E4E09 (C) What undesirable effect can occur when using an IF type noise blanker? C. Nearby signals may appear to be excessively wide even if they meet emission standards E4E10 (D) What is a common characteristic of interference caused by a "touch controlled" electrical device? A. The interfering signal sounds like AC hum on an AM receiver or a carrier modulated by 60 Hz FM on a SSB or CW receiver B. The interfering signal may drift slowly across the HF spectrum C. The interfering signal can be several kHz in width and usually repeats at regular intervals across a HF band D. All of these answers are correct E4E11 (B) What is the most likely cause if you are hearing combinations of local AM broadcast signals inside one or more of the MF or HF ham bands? B. Nearby corroded metal joints are mixing and re-radiating the BC signals E4E12 (A) What is one disadvantage of using some automatic DSP notch-filters when attempting to copy CW signals? A. The DSP filter can remove the desired signal at the same time as it removes interfering signals E4E13 (D) What might be the cause of a loud "roaring" or "buzzing" AC line type of interference that comes and goes at intervals? A. Arcing contacts in a thermostatically controlled device B. A defective doorbell or doorbell transformer inside a nearby residence C. A malfunctioning illuminated advertising display D. All of these answers are correct E4E14 (C) What is one type of electrical interference that might be caused by the operation of a nearby personal computer? C. The appearance of unstable modulated or unmodulated signals at specific frequencies SUBELEMENT E5 -- ELECTRICAL PRINCIPLES [4 Exam Questions -- 4 Groups] E5A Resonance and Q: characteristics of resonant circuits: series and parallel resonance; Q; half-power bandwidth; phase relationships in reactive circuits E5A01 (A) What can cause the voltage across reactances in series to be larger than the voltage applied to them? A. Resonance E5A02 (C) What is resonance in an electrical circuit? C. The frequency at which the capacitive reactance equals the inductive reactance E5A03 (D) What is the magnitude of the impedance of a series R-L-C circuit at resonance? D. Approximately equal to circuit resistance E5A04 (A) What is the magnitude of the impedance of a circuit with a resistor, an inductor and a capacitor all in parallel, at resonance? A. Approximately equal to circuit resistance E5A05 (B) What is the magnitude of the current at the input of a series R-L-C circuit as the frequency goes through resonance? B. Maximum E5A06 (B) (Was E5A08; edited] What is the magnitude of the circulating current within the components of a parallel L-C circuit at resonance? B. It is at a maximum E5A07 (A) What is the magnitude of the current at the input of a parallel R-L-C circuit at resonance? A. Minimum E5A08 (C) What is the phase relationship between the current through and the voltage across a series resonant circuit? C. The voltage and current are in phase E5A09 (C) What is the phase relationship between the current through and the voltage across a parallel resonant circuit? C. The voltage and current are in phase E5A10 (A) What is the half-power bandwidth of a parallel resonant circuit that has a resonant frequency of 1.8 MHz and a Q of 95? A. 18.9 kHz E5A11 (C) What is the half-power bandwidth of a parallel resonant circuit that has a resonant frequency of 7.1 MHz and a Q of 150? C. 47.3 kHz E5A12 (C) What is the half-power bandwidth of a parallel resonant circuit that has a resonant frequency of 3.7 MHz and a Q of 118? C. 31.4 kHz E5A13 (B) What is the half-power bandwidth of a parallel resonant circuit that has a resonant frequency of 14.25 MHz and a Q of 187? B. 76.2 kHz E5A14 (C) What is the resonant frequency of a series RLC circuit if R is 22 ohms, L is 50 microhenrys and C is 40 picofarads? C. 3.56 MHz E5A15 (B) What is the resonant frequency of a series RLC circuit if R is 56 ohms, L is 40 microhenrys and C is 200 picofarads? B. 1.78 MHz E5A16 (D) What is the resonant frequency of a parallel RLC circuit if R is 33 ohms, L is 50 microhenrys and C is 10 picofarads? D. 7.12 MHz E5A17 (A) What is the resonant frequency of a parallel RLC circuit if R is 47 ohms, L is 25 microhenrys and C is 10 picofarads? A. 10.1 MHz E5B Time constants and phase relationships: R/L/C time constants: definition; time constants in RL and RC circuits; phase angle between voltage and current; phase angles of series and parallel circuits E5B01(B) What is the term for the time required for the capacitor in an RC circuit to be charged to 63.2% of the supply voltage? B. One time constant E5B02 (D) What is the term for the time it takes for a charged capacitor in an RC circuit to discharge to 36.8% of its initial value of stored charge? D. One time constant E5B03 (D) The capacitor in an RC circuit is discharged to what percentage of the starting voltage after two time constants? D. 13.5% E5B04 (D) What is the time constant of a circuit having two 220-microfarad capacitors and two 1-megohm resistors all in parallel? D. 220 seconds E5B05 (A) How long does it take for an initial charge of 20 V DC to decrease to 7.36 V DC in a 0.01-microfarad capacitor when a 2-megohm resistor is connected across it? A. 0.02 seconds E5B06 (C) How long does it take for an initial charge of 800 V DC to decrease to 294 V DC in a 450-microfarad capacitor when a 1-megohm resistor is connected across it? C. 450 seconds E5B07 (C) What is the phase angle between the voltage across and the current through a series R-L-C circuit if XC is 500 ohms, R is 1 kilohm, and XL is 250 ohms? C. 14.0 degrees with the voltage lagging the current E5B08 (A) What is the phase angle between the voltage across and the current through a series R-L-C circuit if XC is 100 ohms, R is 100 ohms, and XL is 75 ohms? A. 14 degrees with the voltage lagging the current E5B09 (D) What is the relationship between the current through and the voltage across a capacitor? D. Current leads voltage by 90 degrees E5B10 (A) What is the relationship between the current through an inductor and the voltage across an inductor? A. Voltage leads current by 90 degrees E5B11 (B) What is the phase angle between the voltage across and the current through a series RLC circuit if XC is 25 ohms, R is 100 ohms, and XL is 50 ohms? B. 14 degrees with the voltage leading the current E5B12 (C) What is the phase angle between the voltage across and the current through a series RLC circuit if XC is 75 ohms, R is 100 ohms, and XL is 50 ohms? C. 14 degrees with the voltage lagging the current E5B13 (D) What is the phase angle between the voltage across and the current through a series RLC circuit if XC is 250 ohms, R is 1 kilohm, and XL is 500 ohms? D. 14.04 degrees with the voltage leading the current E5C Impedance plots and coordinate systems: plotting impedances in polar coordinates; rectangular coordinates E5C01 (B) In polar coordinates, what is the impedance of a network consisting of a 100-ohm-reactance inductor in series with a 100-ohm resistor? B. 141 ohms at an angle of 45 degrees E5C02 (D) In polar coordinates, what is the impedance of a network consisting of a 100-ohm-reactance inductor, a 100-ohm-reactance capacitor, and a 100-ohm resistor all connected in series? D. 100 ohms at an angle of 0 degrees E5C03 (A) In polar coordinates, what is the impedance of a network consisting of a 300-ohm-reactance capacitor, a 600-ohm-reactance inductor, and a 400-ohm resistor, all connected in series? A. 500 ohms at an angle of 37 degrees E5C04 (D) In polar coordinates, what is the impedance of a network consisting of a 400-ohm-reactance capacitor in series with a 300-ohm resistor? D. 500 ohms at an angle of -53.1 degrees E5C05 (A) In polar coordinates, what is the impedance of a network consisting of a 400-ohm-reactance inductor in parallel with a 300-ohm resistor? A. 240 ohms at an angle of 36.9 degrees E5C06 (D) In polar coordinates, what is the impedance of a network consisting of a 100-ohm-reactance capacitor in series with a 100-ohm resistor? D. 141 ohms at an angle of -45 degrees E5C07 (C) In polar coordinates, what is the impedance of a network comprised of a 100-ohm-reactance capacitor in parallel with a 100-ohm resistor? C. 71 ohms at an angle of -45 degrees E5C08 (B) In polar coordinates, what is the impedance of a network comprised of a 300-ohm-reactance inductor in series with a 400-ohm resistor? B. 500 ohms at an angle of 37 degrees E5C09 (A) When using rectangular coordinates to graph the impedance of a circuit, what does the horizontal axis represent? A. The voltage or current associated with the resistive component E5C10 (B) When using rectangular coordinates to graph the impedance of a circuit, what does the vertical axis represent? B. The voltage or current associated with the reactive component E5C11 (C) What do the two numbers represent that are used to define a point on a graph using rectangular coordinates? C. The coordinate values along the horizontal and vertical axes E5C12 (D) If you plot the impedance of a circuit using the rectangular coordinate system and find the impedance point falls on the right side of the graph on the horizontal line, what do you know about the circuit? D. It is equivalent to a pure resistance E5C13 (D) What coordinate system is often used to display the resistive, inductive, and/or capacitive reactance components of an impedance? D. Rectangular coordinates E5C14 (D) What coordinate system is often used to display the phase angle of a circuit containing resistance, inductive and/or capacitive reactance? D. Rectangular coordinates E5C15 (A) In polar coordinates, what is the impedance of a circuit of 100 -j100 ohms impedance? A. 141 ohms at an angle of -45 degrees E5C16 (B) In polar coordinates, what is the impedance of a circuit that has an admittance of 7.09 millisiemens at 45 degrees? B. 141 ohms at an angle of -45 degrees E5C17 (C) In rectangular coordinates, what is the impedance of a circuit that has an admittance of 5 millisiemens at -30 degrees? C. 173 + j100 ohms E5C18 (B) In polar coordinates, what is the impedance of a series circuit consisting of a resistance of 4 ohms, an inductive reactance of 4 ohms, and a capacitive reactance of 1 ohm? B. 5 ohms at an angle of 37 degrees E5C22 (A) In rectangular coordinates, what is the impedance of a network comprised of a 10-microhenry inductor in series with a 40-ohm resistor at 500 MHz? A. 40 + j31,400 E5D AC and RF energy in real circuits: skin effect; electrostatic and electromagnetic fields; reactive power; power factor; coordinate systems E5D01 (A) What is the result of skin effect? A. As frequency increases, RF current flows in a thinner layer of the conductor, closer to the surface E5D02 (C) Why is the resistance of a conductor different for RF currents than for direct currents? C. Because of skin effect E5D03 (C) What device is used to store electrical energy in an electrostatic field? C. A capacitor E5D04 (B) What unit measures electrical energy stored in an electrostatic field? B. Joule E5D05 (B) What is a magnetic field? B. The space through which a magnetic force acts E5D06 (D) In what direction is the magnetic field oriented about a conductor in relation to the direction of electron flow? D. In a direction determined by the left-hand rule E5D07 (D) What determines the strength of a magnetic field around a conductor? D. The amount of current E5D08 (B) What is the term for energy that is stored in an electromagnetic or electrostatic field? B. Potential energy E5D09 (D) What is the term for an out-of-phase, nonproductive power associated with inductors and capacitors? D. Reactive power E5D10 (B) In a circuit that has both inductors and capacitors, what happens to reactive power? B. It is repeatedly exchanged between the associated magnetic and electric fields, but is not dissipated E5D11 (A) How can the true power be determined in an AC circuit where the voltage and current are out of phase? A. By multiplying the apparent power times the power factor E5D12 (C) What is the power factor of an R-L circuit having a 60 degree phase angle between the voltage and the current? C. 0.5 E5D13 (B) How many watts are consumed in a circuit having a power factor of 0.2 if the input is 100-V AC at 4 amperes? B. 80 watts E5D14 (B) How much power is consumed in a circuit consisting of a 100 ohm resistor in series with a 100 ohm inductive reactance drawing 1 ampere? B. 100 Watts E5D15 (A) What is reactive power? A. Wattless, nonproductive power E5D16 (D) What is the power factor of an RL circuit having a 45 degree phase angle between the voltage and the current? D. 0.707 E5D17 (C) was [E5H14] What is the power factor of an RL circuit having a 30 degree phase angle between the voltage and the current? C. 0.866 E5D18 (D) How many watts are consumed in a circuit having a power factor of 0.6 if the input is 200V AC at 5 amperes? D. 600 watts E5D19 (B) How many watts are consumed in a circuit having a power factor of 0.71 if the apparent power is 500 watts? B. 355 W SUBELEMENT E6 -- CIRCUIT COMPONENTS [6 Exam Questions -- 6 Groups] E6A Semiconductor materials and devices: semiconductor materials (germanium, silicon, P-type, N-type); transistor types: NPN, PNP, junction, power; field-effect transistors: enhancement mode; depletion mode; MOS; CMOS; N-channel; P-channel E6A01 (C) In what application is gallium arsenide used as a semiconductor material in preference to germanium or silicon? C. At microwave frequencies E6A02 (A) What type of semiconductor material contains more free electrons than pure germanium or silicon crystals? A. N-type E6A03 (C) What are the majority charge carriers in P-type semiconductor material? C. Holes E6A04 (C) What is the name given to an impurity atom that adds holes to a semiconductor crystal structure? C. Acceptor impurity E6A05 (C) What is the alpha of a bipolar junction transistor? C. The change of collector current with respect to emitter current E6A06 (B) What is meant by the beta of a bipolar junction transistor? B. The change in collector current with respect to base current E6A08 (D) What term indicates the frequency at which a transistor grounded base current gain has decreased to 0.7 of the gain obtainable at 1 kHz? D. Alpha cutoff frequency E6A09 (A) What is a depletion-mode FET? A. An FET that exhibits a current flow between source and drain when no gate voltage is applied E6A10 (B) {Was E6A09] In Figure E6-2, what is the schematic symbol for an N-channel dual-gate MOSFET? B. 4 E6A11 (A) In Figure E6-2, what is the schematic symbol for a P-channel junction FET? A. 1 E6A12 (D) Why do many MOSFET devices have built-in gate-protective Zener diodes? D. To reduce the chance of the gate insulation being punctured by static discharges or excessive voltages E6A13 (C) What do the initials CMOS stand for? C. Complementary metal-oxide semiconductor E6A14 (C) How does DC input impedance at the gate of a field-effect transistor compare with the DC input impedance of a bipolar transistor? C. An FET has high input impedance; a bipolar transistor has low input impedance E6A15 (B) What two elements widely used in semiconductor devices exhibit both metallic and nonmetallic characteristics? B. Silicon and germanium E6A16 (B) What type of semiconductor material contains fewer free electrons than pure germanium or silicon crystals? B. P-type E6A17 (B) What are the majority charge carriers in N-type semiconductor material? B. Free electrons E6A18 (D) What are the names of the three terminals of a field-effect transistor? D. Gate, drain, source E6B Semiconductor diodes E6B01 (B) What is the principal characteristic of a Zener diode? B. A constant voltage under conditions of varying current E6B02 (C) What is the principal characteristic of a tunnel diode? C. A negative resistance region E6B03 (D) What is an important characteristic of a Schottky Barrier diode as compared to an ordinary silicon diode when used as a power supply rectifier? D. Less forward voltage drop E6B04 (C) What special type of diode is capable of both amplification and oscillation? C. Tunnel E6B05 (A) What type of semiconductor device varies its internal capacitance as the voltage applied to its terminals varies? A. Varactor diode E6B06 (D) In Figure E6-3, what is the schematic symbol for a varactor diode? D. 1 E6B07 (D) What is a common use of a hot-carrier diode? D. As a VHF / UHF mixer or detector E6B08 (B) What limits the maximum forward current rating in a junction diode? B. Junction temperature E6B09 (A) Which of the following describes a type of semiconductor diode? A. Metal-semiconductor junction E6B10 (C) What is a common use for point contact diodes? C. As an RF detector E6B11 (B) In Figure E6-3, what is the schematic symbol for a light-emitting diode? B. 5 E6B12 (D) How are junction diodes rated? D. Maximum forward current and PIV E6B13 (C) What is one common use for PIN diodes? C. As an RF switch E6B14 (B) What type of bias is required for an LED to produce luminescence? B. Forward bias E6C Integrated circuits: TTL digital integrated circuits; CMOS digital integrated circuits; gates E6C01 (C) What is the recommended power supply voltage for TTL series integrated circuits? C. 5 volts E6C02 (A) What logic state do the inputs of a TTL device assume if they are left open? A. A logic-high state E6C03 (A) What level of input voltage is a logic "high" in a TTL device operating with a positive 5-volt power supply? A. 2.0 to 5.5 volts E6C04 (C) What level of input voltage is a logic "low" in a TTL device operating with a positive 5-volt power-supply? C. 0.0 to 0.8 volts E6C05 (D) Which of the following is an advantage of CMOS logic devices over TTL devices? D. Lower power consumption E6C06 (C) Why do CMOS digital integrated circuits have high immunity to noise on the input signal or power supply? C. The input switching threshold is about one-half the power supply voltage E6C07 (A) In Figure E6-5, what is the schematic symbol for an AND gate? A. 1 E6C08 (B) In Figure E6-5, what is the schematic symbol for a NAND gate? B. 2 E6C09 (B) In Figure E6-5, what is the schematic symbol for an OR gate? B. 3 E6C10 (D) In Figure E6-5, what is the schematic symbol for a NOR gate? D. 4 E6C11 (C) In Figure E6-5, what is the schematic symbol for the NOT operation (inverter)? C. 5 E6D Optical devices and toroids: vidicon and cathode-ray tube devices; charge-coupled devices (CCDs); liquid crystal displays (LCDs); toroids: permeability, core material, selecting, winding E6D01 (D) How is the electron beam deflected in a vidicon? D. By varying electromagnetic fields E6D02 (D) What is cathode ray tube (CRT) persistence? D. The length of time the image remains on the screen after the beam is turned off E6D03 (A) If a cathode ray tube (CRT) is designed to operate with an anode voltage of 25,000 volts, what will happen if the anode voltage is increased to 35,000 volts? A. The image size will decrease E6D04 (B) Exceeding what design rating can cause a cathode ray tube (CRT) to generate X-rays? B. The anode voltage E6D05 (C) Which of the following is true of a charge-coupled device (CCD)? C. It samples an analog signal and passes it in stages from the input to the output E6D06 (A) What function does a charge-coupled device (CCD) serve in a modern video camera? A. It stores photogenerated charges as signals corresponding to pixels E6D07 (B) What is a liquid-crystal display (LCD)? B. A display that uses a crystalline liquid to change the way light is refracted E6D08 (D) What material property determines the inductance of a toroidal inductor with a 10-turn winding? D. Core permeability E6D09 (B) What is the usable frequency range of inductors that use toroidal cores, assuming a correct selection of core material for the frequency being used? B. From less than 20 Hz to approximately 300 MHz E6D10 (B) What is one important reason for using powdered-iron toroids rather than ferrite toroids in an inductor? B. Powdered-iron toroids generally have better temperature stability E6D11 (C) What devices are commonly used as VHF and UHF parasitic suppressors at the input and output terminals of transistorized HF amplifiers? C. Ferrite beads E6D12 (A) What is a primary advantage of using a toroidal core instead of a solenoidal core in an inductor? A. Toroidal cores contain most of the magnetic field within the core material E6D13 (C) How many turns will be required to produce a 1-mH inductor using a ferrite toroidal core that has an inductance index (A L) value of 523 millihenrys/1000 turns? C. 43 turns E6D14 (A) How many turns will be required to produce a 5-microhenry inductor using a powdered-iron toroidal core that has an inductance index (A L) value of 40 microhenrys/100 turns? A. 35 turns E6D15 (D) What type of CRT deflection is better when high-frequency waves are to be displayed on the screen? D. Electrostatic E6D16 (C) Which is NOT true of a charge-coupled device (CCD)? C. It is commonly used as an analog-to-digital converter E6D17 (A) What is the principle advantage of liquid-crystal display (LCD) devices over other types of display devices? A. They consume less power E6D18 (C) What is one reason for using ferrite toroids rather than powdered-iron toroids in an inductor? C. Ferrite toroids generally require fewer turns to produce a given inductance value E6E Piezoelectric crystals and MMICS: quartz crystals (as used in oscillators and filters); monolithic amplifiers (MMICs) E6E01 (B) Which of these filter bandwidths would be a good choice for use in a SSB radiotelephone transmitter? B. 2.4 kHz at -6 dB E6E02 (C) Which of these filter bandwidths would be a good choice for use with standard double-sideband AM transmissions? C. 6 kHz at -6 dB E6E03 (D) What is a crystal lattice filter? D. A filter with narrow bandwidth and steep skirts made using quartz crystals E6E04 (D) What technique is used to construct low-cost, high-performance crystal ladder filters? D. Measure crystal frequencies and carefully select units with a frequency variation of less than 10% of the desired filter bandwidth E6E05 (A) Which of the following factors has the greatest effect in helping determine the bandwidth and response shape of a crystal ladder filter? A. The relative frequencies of the individual crystals E6E06 (A) What is the one aspect of the piezoelectric effect? A. Physical deformation of a crystal by the application of a voltage E6E07 (A) What is the characteristic impedance of circuits in which almost all MMICs are designed to work? A. 50 ohms E6E08 (B) What is the typical noise figure of a monolithic microwave integrated circuit (MMIC) amplifier? B. Approximately 3.5 to 6 dB E6E09 (D) What type of amplifier device consists of a small pill-type package with an input lead, an output lead and 2 ground leads? D. A monolithic microwave integrated circuit (MMIC) E6E10 (B) What typical construction technique is used when building an amplifier for the microwave bands containing a monolithic microwave integrated circuit (MMIC)? B. Microstrip construction E6E11 (A) How is the operating bias voltage normally supplied to the most common type of monolithic microwave integrated circuit (MMIC)? A. Through a resistor and/or RF choke connected to the amplifier output lead E6E12 (B) What supply voltage do monolithic microwave integrated circuits (MMIC) amplifiers typically require? B. 12 volts DC E6E13 (C) What is the most common package for inexpensive monolithic microwave integrated circuit (MMIC) amplifiers? C. Plastic packages E6F Optical components and power systems: photoconductive principles and effects, photovoltaic systems, optical couplers, optical sensors, and optoisolators E6F01 (B) What is photoconductivity? B. The increased conductivity of an illuminated semiconductor E6F02 (A) What happens to the conductivity of a photoconductive material when light shines on it? A. It increases E6F03 (D) What is the most common configuration for an optocoupler? D. An LED and a phototransistor E6F04 (A) Which of the following is an optoisolator? A. An LED and a phototransistor E6F05 (B) What is an optical shaft encoder? B. An array of optocouplers whose light transmission path is controlled by a rotating wheel E6F06 (D) What characteristic of a crystalline solid will photoconductivity change? D. The resistance E6F07 (C) Which material will exhibit the greatest photoconductive effect when illuminated by visible light? C. Cadmium sulfide E6F08 (B) Which material will exhibit the greatest photoconductive effect when illuminated by infrared light? B. Lead sulfide E6F09 (A) Which of the following materials is affected the most by photoconductivity? A. A crystalline semiconductor E6F10 (B) What characteristic of optoisolators is often used in power supplies? B. They have very high impedance between the light source and the phototransistor E6F11 (C) What characteristic of optoisolators makes them suitable for use with a triac to form the solid-state equivalent of a mechanical relay for a 120 V AC household circuit? C. Optoisolators provide a very high degree of electrical isolation between a control circuit and a power circuit E6F12 (D) Which of the following types of photovoltaic cell has the highest efficiency? D. Gallium arsenide E6F13 (B) What is the most common type of photovoltaic cell used for electrical power generation? B. Silicon E6F14 (B) B) What of the following is the approximate open-circuit voltage produced by a fully-illuminated silicon photovoltaic cell? B. 0.5 V E6F15 (C) What absorbs the energy from light falling on a photovoltaic cell? C. Electrons SUBELEMENT E7 -- PRACTICAL CIRCUITS [8 Exam Questions -- 8 Groups] E7 Digital circuits: digital circuit principles and logic circuits: classes of logic elements; positive and negative logic; frequency dividers; truth tables E7A01 (C) What is a bistable circuit? C. A flip-flop E7A02 (C) How many output level changes are obtained for every two trigger pulses applied to the input of a "T" flip-flop circuit? C. Two E7A03 (B) Which of the following can divide the frequency of pulse train by 2? B. A flip-flop E7A04 (B) How many flip-flops are required to divide a signal frequency by 4? B. 2 E7A05 (D) Which of the following is a circuit that continuously alternates between two unstable states without an external clock? D. Astable Multivibrator E7A06 (A) What is a characteristic of a monostable multivibrator? A. It switches momentarily to the opposite binary state and then returns, after a set time, to its original state E7A07 (B) What logical operation does an AND gate perform? B. It produces a logic "1" at its output only if all inputs are logic "1" E7A08 (D) What logical operation does a NAND gate perform? D. It produces a logic "0" at its output only when all inputs are logic "1" E7A09 (A) What logical operation does an OR gate perform? A. It produces a logic "1" at its output if any or all inputs are logic "1" E7A10 (C) What logical operation does a NOR gate perform? C. It produces a logic "0" at its output if any or all inputs are logic "1" E7A11 (C) What is a truth table? C. A list of inputs and corresponding outputs for a digital device E7A12 (D) What is the name for logic which represents a logic "1" as a high voltage? D. Positive Logic E7A13 (C) What is the name for logic which represents a logic "0" as a high voltage? C. Negative logic E7B Amplifiers: Class of operation; vacuum tube and solid-state circuits; distortion and intermodulation; spurious and parasitic suppression; microwave amplifiers E7B01 (A) For what portion of a signal cycle does a Class AB amplifier operate? A. More than 180 degrees but less than 360 degrees E7B02 (C) Which class of amplifier, of the types shown, provides the highest efficiency? C. Class C E7B03 (A) Where on the load line of a Class A common emitter amplifier would bias normally be set? A. Approximately half-way between saturation and cutoff E7B04 (C) What can be done to prevent unwanted oscillations in a power amplifier? C. Install parasitic suppressors and/or neutralize the stage E7B05 (B) Which of the following amplifier types reduces or eliminates even-order harmonics? B. Push-pull E7B06 (D) Which of the following is a likely result when a Class C rather than a class AB amplifier is used to amplify a single-sideband phone single? D. The signal may become distorted and occupy excessive bandwidth E7B07 (C) How can a vacuum-tube power amplifier be neutralized? C. By feeding back an out-of-phase component of the output to the input E7B08 (D) Which of the following describes how the loading capacitor and tuning capacitor are to be adjusted when tuning a vacuum tube RF power amplifier that employs a pi-network output circuit? D. The tuning capacitor is adjusted for minimum plate current, while the loading capacitor is adjusted for maximum permissible plate current E7B09 (B) In Figure E7-1, what is the purpose of R1 and R2? B. Fixed bias E7B10 (D) In Figure E7-1, what is the purpose of R3? D. Self bias E7B11 (C) What type of circuit is shown in Figure E7-1? C. Common emitter amplifier E7B12 (A) In Figure E7-2, what is the purpose of R? A. Emitter load E7B13 (A) In Figure E7-2, what is the purpose of C2? A. Output coupling E7B14 (C) What is one way to prevent thermal runaway in a transistor amplifier? C. Use degenerative emitter feedback E7B15 (A) What is the effect of intermodulation products in a linear power amplifier? A. Transmission of spurious signals E7B16 (A) Why are third-order intermodulation distortion products of particular concern in linear power amplifiers? A. Because they are relatively close in frequency to the desired signal E7B17 (C) Which of the following is a characteristic of a grounded-grid amplifier? C. Low input impedance E7B18 (D) What is a klystron? D. A VHF, UHF, or microwave vacuum tube that uses velocity modulation E7B19 (B) What is a parametric amplifier? B. A low-noise VHF or UHF amplifier relying on varying reactance for amplification E7B20 (A) Which of the following devices is generally best suited for UHF or microwave power amplifier applications? A. FET E7C Filters and matching networks: filters and impedance matching networks: types of networks; types of filters; filter applications; filter characteristics; impedance matching; DSP filtering E7C01 (D) How are the capacitors and inductors of a low-pass filter Pi-network arranged between the network's input and output? D. A capacitor is in parallel with the input, another capacitor is in parallel with the output, and an inductor is in series between the two E7C02 (C) A T-network with series capacitors and a parallel (shunt) inductor has which of the following properties? C. It transforms impedance and is a high-pass filter E7C03 (A) What advantage does a Pi-L-network have over a Pi-network for impedance matching between the final amplifier of a vacuum-tube type transmitter and an antenna? A. Greater harmonic suppression E7C04 (C) How does a network transform a complex impedance to a resistive impedance? C. It cancels the reactive part of an impedance and transforms the resistive part to the desired value E7C05 (D) Which filter type is described as having ripple in the passband and a sharp cutoff? D. A Chebyshev filter E7C06 (C) What are the distinguishing features of an elliptical filter? C. Extremely sharp cutoff, with one or more infinitely deep notches in the stop band E7C07 (B) What kind of audio filter would you use to attenuate an interfering carrier signal while receiving an SSB transmission? B. A notch filter E7C08 (A) What kind of digital signal processing audio filter might be used to remove unwanted noise from a received SSB signal? A. An adaptive filter E7C09 (C) What type of digital signal processing filter might be used in generating an SSB signal? C. A Hilbert-transform filter E7C10 (B) Which of the following filters would be the best choice for use in a 2-meter repeater duplexer? B. A cavity filter E7C11 (D) Which of the following is the common name for a filter network which is equivalent to two L networks back-to-back? D. Pi E7C12 (B) What is a Pi-L network, as used when matching a vacuum-tube final amplifier to a 50-ohm unbalanced output? B. A network consisting of two series inductors and two shunt capacitors E7C13 (A) What is one advantage of a Pi matching network over an L matching network? A. Q of Pi networks can be varied depending on the component values chosen E7C14 (C) Which of these modes is most affected by non-linear phase response in a receiver IF filter? C. Digital E7D Power supplies and voltage regulators E7D01 (D) What is one characteristic of a linear electronic voltage regulator? D. The conduction of a control element is varied to maintain a constant output voltage E7D02 (C) What is one characteristic of a switching electronic voltage regulator? C. The control device’s duty cycle is controlled to produce a constant average output voltage E7D03 (A) What device is typically used as a stable reference voltage in a linear voltage regulator? A. A Zener diode E7D04 (B) Which of the following types of linear regulator makes the most efficient use of the primary power source? B. A series regulator E7D05 (D) Which of the following types of linear voltage regulator places a constant load on the unregulated voltage source? D. A shunt regulator E7D06 (C) What is the purpose of Q1 in the circuit shown in Figure E7-3? C. It increases the current-handling capability of the regulator E7D07 (A) What is the purpose of C2 in the circuit shown in Figure E7-3? A. It bypasses hum around D1 E7D08 (C) What type of circuit is shown in Figure E7-3? C. Linear voltage regulator E7D09 (D) What is the purpose of C1 in the circuit shown in Figure E7-3? D. It filters the supply voltage E7D10 (A) What is the purpose of C3 in the circuit shown in Figure E7-3? A. It prevents self-oscillation E7D11 (C) What is the purpose of R1 in the circuit shown in Figure E7-3? C. It supplies current to D1 E7D12 (D) What is the purpose of R2 in the circuit shown in Figure E7-3? D. It provides a constant minimum load for Q1 E7D13 (B) What is the purpose of D1 in the circuit shown in Figure E7-3? B. To provide a voltage reference E7D14 (C) What is one purpose of a "bleeder" resistor in a conventional (unregulated) power supply? C. To improve output voltage regulation E7D15 (D) What is the purpose of a "step-start" circuit in a high-voltage power supply? D. To allow the filter capacitors to charge gradually E7D16 (D) When several electrolytic filter capacitors are connected in series to increase the operating voltage of a power supply filter circuit, why should resistors be connected across each capacitor? A. To equalize, as much as possible, the voltage drop across each capacitor B. To provide a safety bleeder to discharge the capacitors when the supply is off C. To provide a minimum load current to reduce voltage excursions at light loads D. All of these answers are correct E7D17 (C) What is the primary reason that a high-frequency inverter type high-voltage power supply can be both less expensive and lighter in weight than a conventional power supply? C. The high frequency inverter design uses much smaller transformers and filter components for an equivalent power output E7E Modulation and demodulation: reactance, phase and balanced modulators; detectors; mixer stages; DSP modulation and demodulation; software defined radio systems E7E01 (B) Which of the following can be used to generate FM-phone emissions? B. A reactance modulator on the oscillator E7E02 (D) What is the function of a reactance modulator? D. To produce PM signals by using an electrically variable inductance or capacitance E7E03 (C) What is the fundamental principle of a phase modulator? C. It varies the tuning of an amplifier tank circuit to produce PM signals E7E04 (A) What is one way a single-sideband phone signal can be generated? A. By using a balanced modulator followed by a filter E7E05 (D) What circuit is added to an FM transmitter to proportionally attenuate the lower audio frequencies? D. A pre-emphasis network E7E06 (A) What circuit is added to an FM receiver to restore attenuated lower audio frequencies? A. A de-emphasis network E7E07 (D) What is one result of the process of mixing two signals? D. The creation of new signals at the sum and difference frequencies E7E08 (C) What are the principal frequencies that appear at the output of a mixer circuit? C. The original frequencies, and the sum and difference frequencies E7E09 (A) What occurs when an excessive amount of signal energy reaches a mixer circuit? A. Spurious mixer products are generated E7E10 (B) What is the process of detection? B. The recovery of information from a modulated RF signal E7E11 (A) How does a diode detector function? A. By rectification and filtering of RF signals E7E12 (C) Which of the following types of detector is well suited for demodulating SSB signals? C. Product detector E7E13 (D) What is a frequency discriminator? D. A circuit for detecting FM signals E7E14 (D) Which of the following describes a common means of generating a SSB signal when using digital signal processing? D. The phasing or quadrature method E7E15 (C) What is meant by “direct conversion” when referring to a software defined receiver? C. Incoming RF is mixed to “baseband” for analog-to-digital conversion and subsequent processing E7F Frequency markers and counters: frequency divider circuits; frequency marker generators; frequency counters E7F01 (D) What is the purpose of a prescaler circuit? D. It divides a higher frequency signal so a low-frequency counter can display the operating frequency E7F02 (B) Which of the following would be used to reduce a signal’s frequency by a factor of ten? B. A prescaler E7F03 (A) What is the function of a decade counter digital IC? A. It produces one output pulse for every ten input pulses E7F04 (C) What additional circuitry must be added to a 100-kHz crystal-controlled marker generator so as to provide markers at 50 and 25 kHz? C. Two flip-flops E7F05 (B) Which of the following circuits can be combined to produce a 100 kHz fundamental signal with harmonics at 100 kHz intervals? B. A 1 MHz oscillator and a decade counter E7F06 (D) Which of these choices best describes a crystal marker generator? D. A crystal-controlled oscillator that generates a series of reference signals at known frequency intervals E7F07 (D) Which type of circuit would be a good choice for generating a series harmonically related receiver calibration signals? D. A crystal oscillator followed by a frequency divider E7F08 (C) What is one purpose of a marker generator? C. To provide a means of calibrating a receiver's frequency settings E7F09 (A) What determines the accuracy of a frequency counter? A. The accuracy of the time base E7F10 (C) How does a conventional frequency counter determine the frequency of a signal? C. It counts the number of input pulses occurring within a specific period of time E7F11 (A) What is the purpose of a frequency counter? A. To provide a digital representation of the frequency of a signal E7F12 (B) What alternate method of determining frequency, other than by directly counting input pulses, is used by some frequency counters? B. Period measurement E7F13 (C) What is an advantage of a period-measuring frequency counter over a direct-count type? C. It provides improved resolution of signals within a comparable time period E7G Active filters and op-amps: active audio filters; characteristics; basic circuit design; operational amplifiers E7G01 (B) What determines the gain and frequency characteristics of an op-amp RC active filter? B. The values of capacitors and resistors external to the op-amp E7G02 (C) What causes ringing in a filter? C. The frequency and phase response of the filter E7G03 (D) What are the advantages of using an op-amp instead of LC elements in an audio filter? D. Op-amps exhibit gain rather than insertion loss E7G04 (C) Which of the following capacitor types is best suited for use in high-stability op-amp RC active filter circuits? C. Polystyrene E7G05 (A) How can unwanted ringing and audio instability be prevented in a multi-section op-amp RC audio filter circuit? A. Restrict both gain and Q E7G06 (A) What steps are typically followed when selecting the external components for an op-amp RC active filter? A. Standard capacitor values are chosen first, the resistances are calculated, and resistors of the nearest standard value are used E7G07 (D) Which of the following is the most appropriate use of an op-amp RC active filter? D. As an audio receiving filter E7G08 (D) Which of the following is a type of active op-amp filter circuit? D. Sallen-Key E7G09 (C) What voltage gain can be expected from the circuit in Figure E7-4 when R1 is 10 ohms and RF is 470 ohms? C. 47 E7G10 (D) How does the gain of a theoretically ideal operational amplifier vary with frequency? D. It does not vary with frequency E7G11 (D) What will be the voltage of the circuit shown in Figure E7-4 if R1 is 1000 ohms, RF is 10,000 ohms, and 0.23 volts is applied to the input? D. -2.3 volts E7G12 (C) What voltage gain can be expected from the circuit in Figure E7-4 when R1 is 1800 ohms and RF is 68 kilohms? C. 38 E7G13 (B) What voltage gain can be expected from the circuit in Figure E7-4 when R1 is 3300 ohms and RF is 47 kilohms? B. 14 E7G14 (A) What is an operational amplifier? A. A high-gain, direct-coupled differential amplifier whose characteristics are determined by components external to the amplifier E7G15 (C) What is meant by the term "op-amp input-offset voltage"? C. The potential between the amplifier input terminals of the op-amp in a closed-loop condition E7G16 (D) What is the typical input impedance of an integrated circuit op-amp? D. Very high E7G17 (A) What is the typical output impedance of an integrated circuit op-amp? A. Very low E7H Oscillators and signal sources: types of oscillators; synthesizers and phase-locked loops; direct digital synthesizers E7H01 (D) What are three major oscillator circuits often used in Amateur Radio equipment? D. Colpitts, Hartley and Pierce E7H02 (C) What condition must exist for a circuit to oscillate? C. It must have a positive feedback loop with a gain greater than 1 E7H03 (A) How is positive feedback supplied in a Hartley oscillator? A. Through a tapped coil E7H04 (C) How is positive feedback supplied in a Colpitts oscillator? C. Through a capacitive divider E7H05 (D) How is positive feedback supplied in a Pierce oscillator? D. Through a quartz crystal E7H06 (B) Which type of oscillator circuits are commonly used in VFOs? B. Colpitts and Hartley E7H07(C) What is a magnetron oscillator? C. A UHF or microwave oscillator consisting of a diode vacuum tube with a specially shaped anode, surrounded by an external magnet E7H08 (A) What is a Gunn diode oscillator? A. An oscillator based on the negative resistance properties of properly-doped semiconductors E7H09 (C) What type of frequency synthesizer circuit uses a stable voltage-controlled oscillator, programmable divider, phase detector, loop filter and a reference frequency source? C. A phase locked loop synthesizer E7H10 (A) What type of frequency synthesizer circuit uses a phase accumulator, lookup table, digital to analog converter and a low-pass anti-alias filter? A. A direct digital synthesizer E7H11 (B) What information is contained in the lookup table of a direct digital frequency synthesizer? B. The amplitude values that represent a sine-wave output E7H12 (C) What are the major spectral impurity components of direct digital synthesizers? C. Spurs at discrete frequencies E7H13 (D) Which of these circuits would be classified as a principal component of a direct digital synthesizer (DDS)? D. Phase accumulator E7H14 (C) What circuit is often used in conjunction with a direct digital synthesizer (DDS) to expand the available tuning range? C. Phase locked loop E7H15 (A) What is the capture range of a phase-locked loop circuit? A. The frequency range over which the circuit can lock E7H16 (C) What is a phase-locked loop circuit? C. An electronic servo loop consisting of a phase detector, a low-pass filter and voltage-controlled oscillator E7H17 (D) Which of these functions can be performed by a phase-locked loop? D. Frequency synthesis, FM demodulation E7H18 (B) Why is a stable reference oscillator normally used as part of a phase locked loop (PLL) frequency synthesizer? B. Any phase variations in the reference oscillator signal will produce phase noise in the synthesizer output E7H19 (C) Why is a phase-locked loop often used as part of a variable frequency synthesizer for receivers and transmitters? C. It makes it possible for a VFO to have the same degree of stability as a crystal oscillator E7H20 (A) What are the major spectral impurity components of phase-locked loop synthesizers? A. Broadband noise SUBELEMENT E8 -- SIGNALS AND EMISSIONS [4 Exam Questions -- 4 Groups] E8A AC waveforms: sine, square, sawtooth and irregular waveforms; AC measurements; average and PEP of RF signals; pulse and digital signal waveforms E8A01 (A) What type of wave is made up of a sine wave plus all of its odd harmonics? A. A square wave E8A02 (C) What type of wave has a rise time significantly faster than its fall time (or vice versa)? C. A sawtooth wave E8A03 (A) What type of wave is made up of sine waves of a given fundamental frequency plus all its harmonics? A. A sawtooth wave E8A04 (C) What is the equivalent to the root-mean-square value of an AC voltage? C. The DC voltage causing the same amount of heating in a resistor as the corresponding RMS AC voltage E8A05 (D) What would be the most accurate way of measuring the RMS voltage of a complex waveform? D. By measuring the heating effect in a known resistor E8A06 (A) What is the approximate ratio of PEP-to-average power in a typical voice-modulated single-sideband phone signal? A. 2.5 to 1 E8A07 (B) What determines the PEP-to-average power ratio of a single-sideband phone signal? B. The characteristics of the modulating signal E8A08 (A) What is the period of a wave? A. The time required to complete one cycle E8A09 (C) What type of waveform is produced by human speech? C. Irregular E8A10 (B) Which of the following is a distinguishing characteristic of a pulse waveform? B. Narrow bursts of energy separated by periods of no signal E8A11 (D) What is one use for a pulse modulated signal? D. Digital data transmission E8A12 (D) What type of information can be conveyed using digital waveforms? A. Human speech B. Video signals C. Data D. All of these answers are correct E8A13 (C) What is an advantage of using digital signals instead of analog signals to convey the same information? C. Digital signals can be regenerated multiple times without error E8A14 (A) Which of these methods is commonly used to convert analog signals to digital signals? A. Sequential sampling E8A15 (B) What would the waveform of a digital data stream signal look like on a conventional oscilloscope? B. A series of pulses with varying patterns E8B Modulation and demodulation: modulation methods; modulation index and deviation ratio; pulse modulation; frequency and time division multiplexing E8B01 (D) What is the term for the ratio between the frequency deviation of an RF carrier wave, and the modulating frequency of its corresponding FM-phone signal? D. Modulation index E8B02 (D) How does the modulation index of a phase-modulated emission vary with RF carrier frequency (the modulated frequency)? D. It does not depend on the RF carrier frequency E8B03 (A) What is the modulation index of an FM-phone signal having a maximum frequency deviation of 3000 Hz either side of the carrier frequency, when the modulating frequency is 1000 Hz? A. 3 E8B04 (B) What is the modulation index of an FM-phone signal having a maximum carrier deviation of plus or minus 6 kHz when modulated with a 2-kHz modulating frequency? B. 3 E8B05 (D) What is the deviation ratio of an FM-phone signal having a maximum frequency swing of plus-or-minus 5 kHz and accepting a maximum modulation rate of 3 kHz? D. 1.67 E8B06 (A) What is the deviation ratio of an FM-phone signal having a maximum frequency swing of plus or minus 7.5 kHz and accepting a maximum modulation frequency of 3.5 kHz? A. 2.14 E8B07 (A) When using a pulse-width modulation system, why is the transmitter's peak power greater than its average power? A. The signal duty cycle is less than 100% E8B08 (D) What parameter does the modulating signal vary in a pulse-position modulation system? D. The time at which each pulse occurs E8B09 (A) How are the pulses of a pulse-modulated signal usually transmitted? A. A pulse of relatively short duration is sent; a relatively long period of time separates each pulse E8B10 (B) What is meant by deviation ratio? B. The ratio of the maximum carrier frequency deviation to the highest audio modulating frequency E8B11 (C) Which of these methods can be used to combine several separate analog information streams into a single analog radio frequency signal? C. Frequency division multiplexing E8B12 (B) Which of the following describes frequency division multiplexing? B. Two or more information streams are merged into a "baseband", which then modulates the transmitter E8B13 (B) What is time division multiplexing? B. Two or more signals are arranged to share discrete time slots of a digital data transmission E8C Digital signals: digital communications modes; CW; information rate vs. bandwidth; spread-spectrum communications; modulation methods E8C01 (D) Which one of the following digital codes consists of elements having unequal length? D. Morse code E8C02 (B) What are some of the differences between the Baudot digital code and ASCII? B. Baudot uses five data bits per character, ASCII uses seven; Baudot uses two characters as shift codes, ASCII has no shift code E8C03 (C) What is one advantage of using the ASCII code for data communications? C. It is possible to transmit both upper and lower case text E8C04 (D) What is one of the differences between MT63 and PSK31? A. MT63 is an FM signal; PSK31 is an AM signal B. MT63 uses the Baudot code; PSK31 uses Varicode C. MT63 requires less bandwidth for an equivalent bit rate than PSK31 D. MT63 incorporates error correction; PSK31 does not ~~ E8C05 (C) What technique is used to minimize the bandwidth requirements of a PSK-31 signal? C. Use of sinusoidal data pulses E8C06 (C) What is the necessary bandwidth of a 13-WPM international Morse code transmission? C. Approximately 52 Hz E8C07 (C) What is the necessary bandwidth of a 170-hertz shift, 300-baud ASCII transmission? C. 0.5 kHz E8C08 (A) What is the necessary bandwidth of a 4800-Hz frequency shift, 9600-baud ASCII FM transmission? A. 15.36 kHz E8C09 (D) What term describes a wide-bandwidth communications system in which the transmitted carrier frequency varies according to some predetermined sequence? D. Spread-spectrum communication E8C10 (A) Which of these techniques causes a digital signal to appear as wide-band noise to a conventional receiver? A. Spread-spectrum E8C11 (A) What spread-spectrum communications technique alters the center frequency of a conventional carrier many times per second in accordance with a pseudo-random list of channels? A. Frequency hopping E8C12 (B) What spread-spectrum communications technique uses a high speed binary bit stream to shift the phase of an RF carrier? B. Direct sequence E8C13 (D) What makes spread-spectrum communications resistant to interference? D. Only signals using the correct spreading sequence are received E8C14 (D) What is the advantage of including a parity bit with an ASCII character stream? D. Some types of errors can be detected E8C15 (B) What is one advantage of using JT-65 coding? B. Virtually perfect decoding of signals well below the noise E8D Waves, measurements, and RF grounding: peak-to-peak values, polarization; RF grounding E8D01 (A) What is the easiest voltage amplitude parameter to measure when viewing a pure sine wave signal on an oscilloscope? A. Peak-to-peak voltage E8D02 (B) [was E8D03; edited What is the relationship between the peak-to-peak voltage and the peak voltage amplitude in a symmetrical waveform? B. 2:1 E8D03 (A) What input-amplitude parameter is valuable in evaluating the signal-handling capability of a Class A amplifier? A. Peak voltage E8D04 (B) What is the PEP output of a transmitter that has a maximum peak of 30 volts to a 50-ohm load as observed on an oscilloscope? B. 9 watts E8D05 (D) If an RMS-reading AC voltmeter reads 65 volts on a sinusoidal waveform, what is the peak-to-peak voltage? D. 184 volts E8D06 (B) [replaces E8D07] What is the advantage of using a peak-reading wattmeter to monitor the output of a SSB phone transmitter? B. It gives a more accurate display of the PEP output when modulation is present E8D07 (C) What is an electromagnetic wave? C. A wave consisting of an electric field and a magnetic field oscillating at right angles to each other E8D08 (D) Which of the following best describes electromagnetic waves traveling in free space? D. Changing electric and magnetic fields propagate the energy E8D09 (B) What is meant by circularly polarized electromagnetic waves? B. Waves with a rotating electric field E8D10 (D) What is the polarization of an electromagnetic wave if its magnetic field is parallel to the surface of the Earth? D. Vertical E8D11 (A) What is the polarization of an electromagnetic wave if its magnetic field is perpendicular to the surface of the Earth? A. Horizontal E8D12 (A) At approximately what speed do electromagnetic waves travel in free space? A. 300 million meters per second E8D13 (D) What type of meter should be used to monitor the output signal of a voice-modulated single-sideband transmitter to ensure you do not exceed the maximum allowable power? D. A peak-reading wattmeter E8D14 (A) What is the average power dissipated by a 50-ohm resistive load during one complete RF cycle having a peak voltage of 35 volts? A. 12.2 watts E8D15 (D) If an RMS reading voltmeter reads 34 volts on a sinusoidal waveform, what is the peak voltage? D. 48 volts E8D16 (B) Which of the following is a typical value for the peak voltage at a common household electrical outlet? B. 170 volts E8D17 (C) Which of the following is a typical value for the peak-to-peak voltage at a common household electrical outlet? C. 340 volts E8D18 (A) Which of the following is a typical value for the RMS voltage at a common household electrical power outlet? A. 120-V AC E8D19 (A) What is the RMS value of a 340-volt peak-to-peak pure sine wave? A. 120-V AC SUBELEMENT E9 -– ANTENNAS AND TRANSMISSION LINES [8 Exam Questions -- 8 Groups] E9A Isotropic and gain antennas: definition; used as a standard for comparison; radiation pattern; basic antenna parameters: radiation resistance and reactance, gain, beamwidth, efficiency E9A01 (C) Which of the following describes an isotropic Antenna? C. A theoretical antenna used as a reference for antenna gain E9A02 (B) How much gain does a 1/2-wavelength dipole have compared to an isotropic antenna? B. 2.15 dB E9A03 (D) Which of the following antennas has no gain in any direction? D. Isotropic antenna E9A04 (A) Why would one need to know the feed point impedance of an antenna? A. To match impedances for maximum power transfer from a feed line E9A05 (B) Which of the following factors determine the radiation resistance of an antenna? B. Antenna height and conductor length/diameter ratio, and location of nearby conductive objects E9A06 (C) What is the term for the ratio of the radiation resistance of an antenna to the total resistance of the system? C. Antenna efficiency E9A07 (D) What is included in the total resistance of an antenna system? D. Radiation resistance plus ohmic resistance E9A08 (C) What is a folded dipole antenna? C. A dipole constructed from one wavelength of wire forming a very thin loop E9A09 (A) What is meant by antenna gain? A. The numerical ratio relating the radiated signal strength of an antenna in the direction of maximum radiation to that of a reference antenna E9A10 (B) What is meant by antenna bandwidth? B. The frequency range over which an antenna satisfies a performance requirement E9A11 (B) How is antenna efficiency calculated? B. (radiation resistance / total resistance) x 100% E9A12 (A) How can the efficiency of an HF quarter-wave grounded vertical antenna be improved? A. By installing a good radial system E9A13(C) [was E9A16; NEW] Which is the most important factor that determines ground losses for a ground-mounted vertical antenna operating in the 3-30 MHz range? C. Soil conductivity E9A14 (A) How much gain does an antenna have over a 1/2-wavelength dipole when it has 6 dB gain over an isotropic antenna? A. 3.85 dB E9A15 (B) How much gain does an antenna have over a 1/2-wavelength dipole when it has 12 dB gain over an isotropic antenna? B. 9.85 dB E9A16 (C) (was E9A20; edited) What is meant by the radiation resistance of an antenna? C. The value of a resistance that would dissipate the same amount of power as that radiated from an antenna E9B Antenna patterns: E and H plane patterns; gain as a function of pattern; antenna design (computer modeling of antennas); Yagi antennas E9B01 (C) What determines the free-space polarization of an antenna? C. The orientation of its electric field (E Field) E9B02 (B) In the antenna radiation pattern shown in Figure E9-1, what is the 3-dB beamwidth? B. 50 degrees E9B03 (B) In the antenna radiation pattern shown in Figure E9-1, what is the front-to-back ratio? B. 18 dB E9B04 (B) In the antenna radiation pattern shown in Figure E9-1, what is the front-to-side ratio? B. 14 dB E9B05 (D) What may occur when a directional antenna is operated at different frequencies within the band for which it was designed? D. The gain may exhibit significant variations E9B06 (B) What usually occurs if a Yagi antenna is designed solely for maximum forward gain? B. The front-to-back ratio decreases E9B07 (A) If the boom of a Yagi antenna is lengthened and the elements are properly retuned, what usually occurs? A. The gain increases E9B08 (C) How does the total amount of radiation emitted by a directional (gain) antenna compare with the total amount of radiation emitted from an isotropic antenna, assuming each is driven by the same amount of power? C. There is no difference between the two antennas E9B09 (A) How can the approximate beamwidth of a directional antenna be determined? A. Note the two points where the signal strength of the antenna is 3 dB less than maximum and compute the angular difference E9B10 (B) What type of computer program technique is commonly used for modeling antennas? B. Method of Moments E9B11 (A) What is the principle of a Method of Moments analysis? A. A wire is modeled as a series of segments, each having a distinct value of current E9B12 (C) What is a disadvantage of decreasing the number of wire segments in an antenna model below the guideline of 10 segments per half-wavelength? C. The computed feed-point impedance may be incorrect E9B13 (C) Which of the following is a disadvantage of NEC-based antenna modeling programs? C. Computing time increases as the number of wire segments is increased E9B14 (B) What does the abbreviation NEC stand for when applied to antenna modeling programs? B. Numerical Electromagnetics Code E9B15 (D) What type of information can be obtained by submitting the details of a proposed new antenna to a modeling program? A. SWR vs. frequency charts B. Polar plots of the far-field elevation and azimuth patterns C. Antenna gain D. All of these answers are correct E9C Wire and phased vertical antennas: beverage antennas; terminated and resonant rhombic antennas; elevation above real ground; ground effects as related to polarization; take-off angles E9C01 (D) What is the radiation pattern of two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed 180 degrees out of phase? D. A figure-8 oriented along the axis of the array E9C02 (A) What is the radiation pattern of two 1/4-wavelength vertical antennas spaced 1/4-wavelength apart and fed 90 degrees out of phase? A. A cardioid E9C03 (C) What is the radiation pattern of two 1/4-wavelength vertical antennas spaced 1/2-wavelength apart and fed in phase? C. A Figure-8 broadside to the axis of the array E9C04 (B) Which of the following describes a basic rhombic antenna? B. Bidirectional; four-sided, each side one or more wavelengths long; open at the end opposite the transmission line connection E9C05 (A) What are the main advantages of a terminated rhombic antenna? A. Wide frequency range, high gain and high front-to-back ratio E9C06 (C) What are the disadvantages of a terminated rhombic antenna for the HF bands? C. The antenna requires a large physical area and 4 separate supports E9C07 (B) What is the effect of a terminating resistor on a rhombic antenna? B. It changes the radiation pattern from bidirectional to unidirectional E9C08 (A) What type of antenna pattern over real ground is shown in Figure E9-2? A. Elevation E9C09 (C) What is the elevation angle of peak response in the antenna radiation pattern shown in Figure E9-2? C. 7.5 degrees E9C10 (B) What is the front-to-back ratio of the radiation pattern shown in Figure E9-2? B. 28 dB E9C11 (A) How many elevation lobes appear in the forward direction of the antenna radiation pattern shown in Figure E9-2? A. 4 E9C12 (D) How is the far-field elevation pattern of a vertically polarized antenna affected by being mounted over seawater versus rocky ground? D. The low-angle radiation increases E9C13 (D) When constructing a Beverage antenna, which of the following factors should be included in the design to achieve good performance at the desired frequency? D. It should be one or more wavelengths long E9C14 (B) How would the electric field be oriented for a Yagi with three elements mounted parallel to the ground? B. Horizontally E9C15 (A) What strongly affects the shape of the far-field, low-angle elevation pattern of a vertically polarized antenna? A. The conductivity and dielectric constant of the soil in the area of the antenna E9C16 (B) What is an advantage of using an elevated-radial counterpoise with a vertical antenna? B. It reduces near-field ground losses, compared to on-ground systems using more radials E9C17(C) What is the main effect of placing a vertical antenna over an imperfect ground? C. It reduces low-angle radiation E9D Directional antennas: gain; satellite antennas; antenna beamwidth; losses; SWR bandwidth; antenna efficiency; shortened and mobile antennas; grounding E9D01 (C) How does the gain of a parabolic dish antenna change when the operating frequency is doubled? C. Gain increases 6 dB E9D02 (C) What is one way to produce circular polarization when using linearly polarized antennas? C. Arrange two Yagis perpendicular to each other with the driven elements at the same point on the boom and fed 90 degrees out of phase E9D03 (D) How does the beamwidth of an antenna vary as the gain is increased? D. It decreases E9D04 (A) Why is it desirable for a ground-mounted satellite communications antenna system to be able to move in both azimuth and elevation? A. In order to track the satellite as it orbits the earth E9D05 (A) For a shortened vertical antenna, where should a loading coil be placed to minimize losses and produce the most effective performance? A. Near the center of the vertical radiator E9D06 (C) Why should an HF mobile antenna loading coil have a high ratio of reactance to resistance? C. To minimize losses E9D07 (A) What is a disadvantage of using a multiband trapped antenna? A. It might radiate harmonics E9D08 (B) What happens to the bandwidth of an antenna as it is shortened through the use of loading coils? B. It is decreased E9D09 (D) What is an advantage of using top loading in a shortened HF vertical antenna? D. Improved radiation efficiency E9D10 (A) What is the approximate feed-point impedance at the center of a folded dipole antenna? A. 300 ohms E9D11 (D) Why is a loading coil often used with an HF mobile antenna? D. To cancel capacitive reactance E9D12 (D) What is an advantage of using a trapped antenna? D. It may be used for multi-band operation E9D13 (B) What happens at the base feed-point of a fixed-length HF mobile antenna as the frequency of operation is lowered? B. The resistance decreases and the capacitive reactance increases E9D14(B) Which of the following types of conductor would be best for minimizing losses in a station's RF ground system? B. A thin, flat copper strap several inches wide E9D15 (C) Which of these choices would provide the best RF ground for your station? C. A connection to 3 or 4 interconnected ground rods driven into the Earth E9E Matching: matching antennas to feed lines; power dividers E9E01 (B) What system matches a high-impedance transmission line to a lower impedance antenna by connecting the line to the driven element in two places spaced a fraction of a wavelength each side of element center? B. The delta matching system E9E02 (A) What is the name of an antenna matching system that matches an unbalanced feed line to an antenna by feeding the driven element both at the center of the element and at a fraction of a wavelength to one side of center? A. The gamma match E9E03 (D) What is the name of the matching system that uses a short perpendicular section of transmission line connected to the feed line near the antenna? D. The stub match E90E04 (B) What is the purpose of the series capacitor in a gamma-type antenna matching network? B. To compensate for the inductive reactance of the matching network E9E05 (A) How must the driven element in a 3-element Yagi be tuned to use a hairpin matching system? A. The driven element reactance must be capacitive E9E06 (C) What is the equivalent lumped-constant network for a hairpin matching system on a 3-element Yagi? C. L network E9E07 (B) What parameter best describes the interactions at the load end of a mismatched transmission line? B. Reflection coefficient E9E08 (D) Which of the following measurements describes a mismatched transmission line? D. An SWR greater than 1:1 E9E09 (C) Which of these matching systems is an effective method of connecting a 50-ohm coaxial cable feed-line to a grounded tower so it can be used as a vertical antenna? C. Gamma match E9E10 (C) Which of these choices is an effective way to match an antenna with a 100-ohm terminal impedance to a 50-ohm coaxial cable feed-line? C. Insert a 1/4-wavelength piece of 75-ohm coaxial cable transmission line in series between the antenna terminals and the 50-ohm feed cable E9E11 (B) What is an effective way of matching a feed-line to a VHF or UHF antenna when the impedances of both the antenna and feed-line are unknown? B. Use the "universal stub" matching technique E9E12 (A) What is the primary purpose of a "phasing line" when used with an antenna having multiple driven elements? A. It ensures that each driven element operates in concert with the others to create the desired antenna pattern E9E13 (C) What is the purpose of a "Wilkinson divider"? C. It divides power equally among multiple loads while preventing changes in one load from disturbing power flow to the others E9F Transmission lines: characteristics of open and shorted feed lines: 1/8 wavelength; 1/4 wavelength; 1/2 wavelength; feed lines: coax versus open-wire; velocity factor; electrical length; transformation characteristics of line terminated in impedance not equal to characteristic impedance E9F01 (D) What is the velocity factor of a transmission line? D. The velocity of the wave in the transmission line divided by the velocity of light in a vacuum E9F02 (C) What determines the velocity factor in a transmission line? C. Dielectric materials used in the line E9F03 (D) Why is the physical length of a coaxial cable transmission line shorter than its electrical length? D. Electrical signals move more slowly in a coaxial cable than in air E9F04 (B) What is the typical velocity factor for a coaxial cable with solid polyethylene dielectric? B. 0.66 E9F05 (C) (was E9E10) What is the physical length of a coaxial transmission line that is electrically one-quarter wavelength long at 14.1 MHz? (Assume a velocity factor of 0.66.) C. 3.5 meters E9F06 (C) What is the physical length of a parallel conductor feed line that is electrically one-half wavelength long at 14.10 MHz? (Assume a velocity factor of 0.95.) C. 10 meters E9F07 (A) What characteristic will 450-ohm ladder line have at 50 MHz, as compared to 0.195-inch-diameter coaxial cable (such as RG-58)? A. Lower loss E9F08 (A) What is the term for the ratio of the actual speed at which a signal travels through a transmission line to the speed of light in a vacuum? A. Velocity factor E9F09 (B) What would be the physical length of a typical coaxial transmission line that is electrically one-quarter wavelength long at 7.2 MHz? (Assume a velocity factor of 0.66) B. 6.9 meters E9F10 (C) What kind of impedance does a 1/8-wavelength transmission line present to a generator when the line is shorted at the far end? C. An inductive reactance E9F11 (C) What kind of impedance does a 1/8-wavelength transmission line present to a generator when the line is open at the far end? C. A capacitive reactance E9F12 (B) What kind of impedance does a 1/4-wavelength transmission line present to a generator when the line is open at the far end? B. A very low impedance E9F13 (A) What kind of impedance does a 1/4-wavelength transmission line present to a generator when the line is shorted at the far end? A. A very high impedance E9F14 (B) What kind of impedance does a 1/2-wavelength transmission line present to a generator when the line is shorted at the far end? B. A very low impedance E9F15 (A) What kind of impedance does a 1/2-wavelength transmission line present to a generator when the line is open at the far end? A. A very high impedance E9F16 (D) What is the primary difference between foam-dielectric coaxial cable as opposed to solid-dielectric cable, assuming all other parameters are the same? A. Reduced safe operating voltage limits B. Reduced losses per unit of length C. Higher velocity factor D. All of these answers are correct E9G The Smith chart E9G01 (A) Which of the following can be calculated using a Smith chart? A. Impedance along transmission lines E9G02 (B) What type of coordinate system is used in a Smith chart? B. Resistance circles and reactance arcs E9G03 (C) Which of the following is often determined using a Smith chart? C. Impedance and SWR values in transmission lines E9G04 (C) What are the two families of circles and arcs that make up a Smith chart? C. Resistance and reactance E9G05 (A) What type of chart is shown in Figure E9-3? A. Smith chart E9G06 (B) On the Smith chart shown in Figure E9-3, what is the name for the large outer circle on which the reactance arcs terminate? B. Reactance axis E9G07 (D) On the Smith chart shown in Figure E9-3, what is the only straight line shown? D. The resistance axis E9G08 (C) What is the process of normalization with regard to a Smith chart? C. Reassigning impedance values with regard to the prime center E9G09 (A) What third family of circles is often added to a Smith chart during the process of solving problems? A. Standing-wave ratio circles E9G10 (D) What do the arcs on a Smith chart represent? D. Points with constant reactance E9G11 (B) How are the wavelength scales on a Smith chart calibrated? B. In fractions of transmission line electrical wavelength E9F Transmission lines: characteristics of open and shorted feed lines: 1/8 wavelength; 1/4 wavelength; 1/2 wavelength; feed lines: coax versus open-wire; velocity factor; electrical length; transformation characteristics of line terminated in impedance not equal to characteristic impedance E9H01 (D) What is the effective radiated power of a repeater station with 150 watts transmitter power output, 2-dB feed line loss, 2.2-dB duplexer loss and 7-dBd antenna gain? D. 286 watts E9H02 (A) What is the effective radiated power of a repeater station with 200 watts transmitter power output, 4-dB feed line loss, 3.2-dB duplexer loss, 0.8-dB circulator loss and 10-dBd antenna gain? A. 317 watts E9H03 (B) What is the effective radiated power of a repeater station with 200 watts transmitter power output, 2-dB feed line loss, 2.8-dB duplexer loss, 1.2-dB circulator loss and 7-dBd antenna gain? B. 252 watts E9H04 (C) What term describes station output (including the transmitter, antenna and everything in between), when considering transmitter power and system gains and losses? C. Effective radiated power E9H05 (A) What is the main drawback of a wire-loop antenna for direction finding? A. It has a bidirectional pattern E9H06 (C) What is the triangulation method of direction finding? C. Antenna headings from several different receiving stations are used to locate the signal source E9H07 (D) Why is an RF attenuator desirable in a receiver used for direction finding? D. It prevents receiver overload from extremely strong signals E9H08 (A) What is the function of a sense antenna? A. It modifies the pattern of a DF antenna array to provide a null in one direction E9H09 (C) What is a receiving loop antenna? C. One or more turns of wire wound in the shape of a large open coil E9H10 (D) How can the output voltage of a receiving loop antenna be increased? D. By increasing either the number of wire turns in the loop or the area of the loop structure E9H11 (B) Why is an antenna with a cardioid pattern desirable for a direction-finding system? B. The response characteristics of the cardioid pattern can assist in determining the direction of the desired station E9H12 (B) What is an advantage of using a shielded loop antenna for direction finding? B. It is electro-statically balanced with against ground, giving better nulls SUBELEMENT E0 -– [1 exam question -– 1 group] E0A Safety: amateur radio safety practices; RF radiation hazards; hazardous materials E0A01 (C) What, if any, are the differences between the radiation produced by radioactive materials and the electromagnetic energy radiated by an antenna? C. RF radiation does not have sufficient energy to break apart atoms and molecules; radiation from radioactive sources does E0A02 (B) When evaluating exposure levels from your station at a neighbor’s home, what must you do? B. Make sure signals from your station are less than the uncontrolled MPE limits E0A03 (D) Which of the following would be a practical way to estimate whether the RF fields produced by an amateur radio station are within permissible MPE limits? D. Use a computer-based antenna modeling program to calculate field strength at accessible locations E0A04 (C) When evaluating a site with multiple transmitters operating at the same time, the operators and licensees of which transmitters are responsible for mitigating over-exposure situations? C. Each transmitter that produces 5% or more of its maximum permissible exposure limit at accessible locations E0A05 (B) What is one of the potential hazards of using microwaves in the amateur radio bands? B. The high gain antennas commonly used can result in high exposure levels E0A06 (D) Why are there separate electric (E) and magnetic (H) field MPE limits? A. The body reacts to electromagnetic radiation from both the E and H fields B. Ground reflections and scattering make the field impedance vary with location C. E field and H field radiation intensity peaks can occur at different locations D. All of these answers are correct E0A07 (D) What is the "far-field" zone of an antenna? D. The area where the shape of the antenna pattern is independent of distance E0A08 (C) What does SAR measure? C. The rate at which RF energy is absorbed by the body E0A09 (C) Which insulating material commonly used as a thermal conductor for some types of electronic devices is extremely toxic if broken or crushed and the particles are accidentally inhaled? C. Beryllium Oxide E0A10 (A) What material found in some electronic components such as high-voltage capacitors and transformers is considered toxic? A. Polychlorinated biphenyls E0A11 (C) Which of these items might be a significant hazard when operating a klystron or cavity magnetron transmitter? C. Injury from radiation leaks that exceed the MPE limits end of question pool