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Text File | 1992-10-04 | 20KB | 784 lines

;/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\: ; : ; AMATEUR RADIO STUDY GUIDE v1.00 : ; : ; Copyright (c) 1992 David Drzyzga - All Rights Reserved : ; : ; Based on a program coded in BASIC by Russ Revels : ; : ;/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\/\: ; ; You can include comments an the file anywhere you want ; just like these comments. You cannot put a comment in ; the middle of a line though. ; ; When modifying this file, there are several things you ; must be aware of: ; ; -> Any line of text in this file cannot exceed 65 characters! ; this is the 65th character^ ; ; No harm will be done, but nothing over 65 characters will ; be read by the program. ; ; -> Do not make questions more than 20 lines long, or you ; will receive an 'out of memory' error when you execute ; the program. ; ; -> You can add or delete questions as you please, just be ; sure to follow the format of the existing questions. ; ; ; (4AE-1.1) What is reactive power? A. Wattless, non-productive power * (4AE-1.2) What is the term for an out-of-phase, non-productive power associated with inductors and capacitors? D. Reactive power * (4AE-1.3) What is the term for energy that is stored in an electromagnetic or electrostatic field? A. Potential energy * (4AE-1.4) What is responsible for the phenomenon when voltages across reactances in series can often be larger than the voltages applied to them? B. Resonance * (4AE-2.1) What is resonance in an electrical circuit? C. The frequency at which capacitive reactance equals inductive reactance * (4AE-2.2) Under what conditions does resonance occur in an electrical circuit? B. When inductive and capacitive reactances are equal * (4AE-2.3) What is the term for the phenomena which occurs in an electrical circuit when the inductive reactance equals the capacitive reactance? D. Resonance * (4AE-2.4) What is the approximate magnitude of the impedance of a series R-L-C circuit at resonance? B. Approximately equal to the circuit resistance * (4AE-2.5) What is the approximate magnitude of the impedance of a parallel R-L-C circuit at resonance? A. High, as compared to the circuit resistance * (4AE-2.6) What is the characteristic of the current flow in a series R-L-C circuit at resonance? B. It is at a maximum * (4AE-2.7) What is the characteristic of the current flow in a parallel R-L-C circuit at resonance? B. The current circulating in the parallel elements is at a maximum * (4AE-3.1) What is the skin effect? A. The phenomenon where RF current flows in a thinner layer of the conductor, close to the surface, as frequency increases * (4AE-3.2) What is the term for the phenomenon where most of an RF current flows along the surface of the conductor? C. Skin effect * (4AE-3.3) Where does practically all of RF current flow in a conductor? A. Along the surface * (4AE-3.4) Why does practically all of an RF current flow within a few thousandths-of-an-inch of the conductor's surface? A. Because of skin effect * (4AE-3.5) Why is the resistance of a conductor different for RF current than for DC? C. Because of skin effect * (4AE-4.1) What is a magnetic field? B. A force set up when current flows through a conductor * (4AE-4.2) In what direction is the magnetic field about a conductor when current is flowing? D. In a direction determined by the left hand rule * (4AE-4.3) What device is used to store electrical energy in an electrostatic field? C. A capacitor * (4AE-4.4) What is the term used to express the amount of electrical energy stored in an electrostatic field? B. Joules * (4AE-4.5) What factors determine the capacitance of a capacitor? B. Area of the plates, distance between the plates and the dielectric constant of the material between the plates * (4AE-4.6) What is the dielectric constant for air? A. Approximately 1 * (4AE-4.7) What determines the strength of the magnetic field around a conductor? D. The amount of current * (4AE-5.1) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 50 microhenrys and C is 40 picofarads? C. 3.56 MHz * (4AE-5.2) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 40 microhenrys and C is 200 picofarads? B. 1.78 MHz * (4AE-5.3) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 50 microhenrys and C is 10 picofarads? C. 7.12 MHz * (4AE-5.4) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 25 microhenrys and C is 10 picofarads? A. 10.1 MHz * (4AE-5.5) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 3 microhenrys and C is 40 picofarads? B. 14.5 MHz * (4AE-5.6) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 4 microhenrys and C is 20 picofarads? D. 17.8 MHz * (4AE-5.7) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 8 microhenrys and C is 7 picofarads? C. 21.3 MHz * (4AE-5.8) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 3 microhenrys and C is 15 picofarads? A. 23.7 MHz * (4AE-5.9) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 4 microhenrys and C is 8 picofarads? B. 28.1 MHz * (4AE-5.10) What is the resonant frequency of the circuit in Figure 4E-5-1 when L is 1 microhenry and C is 9 picofarads? C. 53.1 MHz * (4AE-5.11) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 1 microhenry and C is 10 picofarads? A. 50.3 MHz * (4AE-5.12) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 2 microhenrys and C is 15 picofarads? B. 29.1 MHz * (4AE-5.13) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 5 microhenrys and C is 9 picofarads? C. 23.7 MHz * (4AE-5.14) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 2 microhenrys and C is 30 picofarads? D. 20.5 MHz * (4AE-5.15) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 15 microhenrys and C is 5 picofarads? A. 18.4 MHz * (4AE-5.16) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 3 microhenrys and C is 40 picofarads? B. 14.5 MHz * (4AE-5.17) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 40 microhenrys and C is 6 picofarads? C. 10.3 MHz * (4AE-5.18) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 10 microhenrys and C is 50 picofarads? D. 7.12 MHz * (4AE-5.19) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 200 microhenrys and C is 10 picofarads? A. 3.56 MHz * (4AE-5.20) What is the resonant frequency of the circuit in Figure 4AE-5-2 when L is 90 microhenrys and C is 100 picofarads? B. 1.68 MHz * (4AE-5.21) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 1.8 MHz and a Q of 95? A. 18.9 kHz * (4AE-5.22) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 3.6 MHz and a Q of 218? D. 16.5 kHz * (4AE-5.23) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 7.1 MHz and a Q of 150? C. 47.3 kHz * (4AE-5.24) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 12.8 MHz and a Q of 218? D. 58.7 kHz * (4AE-5.25) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 14.25 MHz and a Q of 150? A. 95 kHz * (4AE-5.26) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 21.15 MHz and a Q of 95? D. 222.6 kHz * (4AE-5.27) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 10.1 MHz and a Q of 225? B. 44.9 kHz * (4AE-5.28) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 18.1 MHz and a Q of 195? A. 92.8 kHz * (4AE-5.29) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 3.7 MHz and a Q of 118? C. 31.4 kHz * (4AE-5.30) What is the half-power bandwidth of a parallel resonant circuit which has a resonant frequency of 14.25 MHz and a Q of 187? D. 76.2 kHz * (4AE-5.31) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 14.128 MHz, the inductance is 2.7 microhenrys and the resistance is 18,000 ohms? A. 75.1 * (4AE-5.32) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 14.128 MHz, the inductance is 4.7 microhenrys and the resistance is 18,000 ohms? B. 43.1 * (4AE-5.33) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 4.468 MHz, the inductance is 47 microhenrys and the resistance is 180 ohms? C. 0.136 * (4AE-5.34) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 14.225 MHz, the inductance is 3.5 microhenrys and the resistance is 10,000 ohms? D. 31.9 * (4AE-5.35) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 7.125 MHz, the inductance is 8.2 microhenrys and the resistance is 1,000 ohms? D. 2.73 * (4AE-5.36) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 7.125 MHz, the inductance is 10.1 microhenrys and the resistance is 100 ohms? A. 0.221 * (4AE-5.37) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 7.125 MHz, the inductance is 12.6 microhenrys and the resistance is 22,000 ohms? B. 39 * (4AE-5.38) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 3.625 MHz, the inductance is 3 microhenrys and the resistance is 2,200 ohms? B. 32.2 * (4AE-5.39) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 3.625 MHz, the inductance is 42 microhenrys and the resistance is 220 ohms? D. 0.23 * (4AE-5.40) What is the Q of the circuit in Figure 4AE-5-3 when the resonant frequency is 3.625 MHz, the inductance is 43 microhenrys and the resistance is 1,800 ohms? A. 1.84 * (4AE-6.1) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 25 ohms, R is 100 ohms, and Xl is 100 ohms? A. 36.9 degrees with the voltage leading the current * (4AE-6.2) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 25 ohms, R is 100 ohms, and Xl is 50 ohms? B. 14 degrees with the voltage leading the current * (4AE-6.3) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 500 ohms, R is 1000 ohms, and Xl is 250 ohms? C. 14.1 degrees with the voltage lagging the current * (4AE-6.4) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 75 ohms, R is 100 ohms, and Xl is 100 ohms? B. 14 degrees with the voltage leading the current * (4AE-6.5) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 50 ohms, R is 100 ohms, and Xl is 25 ohms? D. 14 degrees with the voltage lagging the current * (4AE-6.6) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 75 ohms, R is 100 ohms, and Xl is 50 ohms? B. 14 degrees with the voltage lagging the current * (4AE-6.7) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 100 ohms, R is 100 ohms, and X1 is 75 ohms? A. 14 degrees with the voltage lagging the current * (4AE-6.8) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 250 ohms, R is 1000 ohms, and Xl is 500 ohms? D. 14.04 degrees with the voltage leading the current * (4AE-6.9) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 50 ohms, R is 100 ohms, and Xl is 75 ohms? D. 14 degrees with the voltage leading the current * (4AE-6.10) What is the phase angle between the voltage across and the current through the circuit in Figure 4AE-6, when Xc is 100 ohms, R is 100 ohms, and X1 is 25 ohms? C. 36.9 degrees with the voltage lagging the current * (4AE-7.1) Why would the rate at which electrical energy is used in a circuit be less than the product of the magnitudes of the AC voltage and current? A. Because there is a phase angle that is greater than zero between the current and voltage * (4AE-7.2) In a circuit where the AC voltage and current are out of phase, how can the true power be determined? A. By multiplying the apparent power times the power factor * (4AE-7.3) What does the power factor equal in an R-L circuit having a 60 degree phase angle between the voltage and the current? C. 0.5 * (4AE-7.4) What does the power factor equal in an R-L circuit having a 45 degree phase angle between the voltage and the current? D. 0.707 * (4AE-7.5) What does the power factor equal in an R-L circuit having a 30 degree phase angle between the voltage and the current? C. 0.866 * (4AE-7.6) How many watts are being consumed in a circuit having a power factor of 0.2 when the input is 100-VAC and 4-amperes is being drawn? B. 80 watts * (4AE-7.7) How many watts are being consumed in a circuit having a power factor of 0.6 when the input is 200-VAC and 5-amperes is being drawn? D. 600 watts * (4AE-8.1) What is the effective radiated power of a station in repeater operation with 50 watts transmitter power output, 4 dB feedline loss, 3 dB duplexer and circulator loss, and 6 dB antenna gain? B. 39.7 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.2) What is the effective radiated power of a station in repeater operation with 50 watts transmitter power output, 5 dB feedline loss, 4 dB duplexer and circulator loss, and 7 dB antenna gain? C. 31.5 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.3) What is the effective radiated power of a station in repeater operation with 75 watts transmitter power output, 4 dB feedline loss, 3 dB duplexer and circulator loss, and 10 dB antenna gain? D. 150 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.4) What is the effective radiated power of a station in repeater operation with 75 watts transmitter power output, 5 dB operation feedline loss, 4 dB duplexer and circulator loss, and 6 dB antenna gain? A. 37.6 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.5) What is the effective radiated power of a station in repeater operation with 100 watts transmitter power output, 4 dB feedline loss, 3 dB duplexer and circulator loss, and 7 dB antenna gain? D. 100 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.6) What is the effective radiated power of a station in repeater operation with 100 watts transmitter power output, 5 dB feedline loss, 4 dB duplexer and circulator loss, and 10 dB antenna gain? B. 126 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.7) What is the effective radiated power of a station in repeater operation with 120 watts transmitter power output, 5 dB feedline loss, 4 dB duplexer and circulator loss, and 6 dB antenna gain? C. 60 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.8) What is the effective radiated power of a station in repeater operation with 150 watts transmitter power output, 4 dB feedline loss, 3 dB duplexer and circulator loss, and 7 dB antenna gain? D. 150 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.9) What is the effective radiated power of a station in repeater operation with 200 watts transmitter power output, 4 dB feedline loss, 4 dB duplexer and circulator loss, and 10 dB antenna gain? A. 317 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-8.10) What is the effective radiated power of a station in repeater operation with 200 watts transmitter power output, 4 dB feedline loss, 3 dB duplexer and circulator loss, and 6 dB antenna gain? D. 159 watts, assuming the antenna gain is referenced to a half-wave dipole * (4AE-9.1) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 8-volts, R1 is 8 kilohms, and R2 is 8 kilohms? B. R3 = 4 kilohms and V2 = 4 volts * (4AE-9.2) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 8-volts, R1 is 16 kilohms, and R2 is 8 kilohms? C. R3 = 5.33 kilohms and V2 = 2.67 volts * (4AE-9.3) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 8-volts, R1 is 8 kilohms, and R2 is 16 kilohms? C. R3 = 5.33 kilohms and V2 = 5.33 volts * (4AE-9.4) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 10-volts, R1 is 10 kilohms, and R2 is 10 kilohms? D. R3 = 5 kilohms and V2 = 5 volts * (4AE-9.5) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 10-volts, R1 is 20 kilohms, and R2 is 10 kilohms? C. R3 = 6.67 kilohms and V2 = 3.33 volts * (4AE-9.6) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 10-volts, R1 is 10 kilohms, and R2 is 20 kilohms? A. R3 = 6.67 kilohms and V2 = 6.67 volts * (4AE-9.7) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 12-volts, R1 is 10 kilohms, and R2 is 10 kilohms? B. R3 = 5 kilohms and V2 = 6 volts * (4AE-9.8) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 12-volts, R1 is 20 kilohms, and R2 is 10 kilohms? B. R3 = 6.67 kilohms and V2 = 4 volts * (4AE-9.9) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 12-volts, R1 is 10 kilohms, and R2 is 20 kilohms? C. R3 = 6.67 kilohms and V2 = 8 volts * (4AE-9.10) In Figure 4AE-9, what values of V2 and R3 result in the same voltage and current characteristics as when V1 is 12-volts, R1 is 20 kilohms, and R2 is 20 kilohms? C. R3 = 10 kilohms and V2 = 6 volts *