Tube power amplifiers always include a matching network to match the high impedance of the tube to the antenna system impedance. As always, impedance match is all about maximum power transfer.

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When the cathode is simply the filament (a "directly-heated cathode"), the voltage drop across the filament (e.g., 6.3 volts AC) is in series with the cathode DC reference voltage: as an example, while one side of the filament might be at a certain DC voltage, the other extremity is at some other value, a value influenced by the AC voltage impressed on the filament. Electron flow is affected by an AC variation, hum results.

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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400 watts out at 50% efficiency supposes that 800 watts DC are needed. Power is voltage times current ; thus, voltage is power divided by current ; 800 watts divided by 0.4 ampere = 2000 volts.

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A grounded-grid amplifier runs with the grid at ground potential. The cathode is above RF ground and serves as the input. A DC bias is applied to the cathode via an RF choke. Positive voltage (B+) is supplied to the plate via an RF choke. The plate is the output, a blocking capacitor passes the RF out to the matching network. A transformer provides AC filament voltage. The heater (in an indirectly-heated cathode tube) is bypassed to ground so radiofrequency does not stray out on the filament supply lines. [ If a tube is directly-heated (no separate cathode), filament voltage is brought through a filament choke. The side of the choke connected to the transformer is bypassed to ground with two capacitors. ]

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Running a VHF or UHF power amplifier without shielding presents a safety risk in terms of RF exposure.

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Key words: STAGES. Resonant circuits in the coupling between stages help convey only the operating frequency. Larger coupling capacitors would pass the harmonics more readily.

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A simple two-stage CW transmitter comprises an oscillator and a Class-C power amplifier. A transformer at the output of the oscillator serves the dual purpose of tuned circuit and coupling to the next stage. The DC supply to the final amplifier is bypassed to ground with a capacitor and decoupled through an RF choke so RF is kept out of the supply.

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A simple two-stage CW transmitter comprises an oscillator and a Class-C power amplifier. A transformer at the output of the oscillator serves the dual purpose of tuned circuit and coupling to the next stage. The DC supply to the final amplifier is bypassed to ground with a capacitor and decoupled through an RF choke so RF is kept out of the supply.

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A simple two-stage CW transmitter comprises an oscillator and a Class-C power amplifier. A transformer at the output of the oscillator serves the dual purpose of tuned circuit and coupling to the next stage. The DC supply to the final amplifier is bypassed to ground with a capacitor and decoupled through an RF choke so RF is kept out of the supply.

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Keying a subsequent stage provides the oscillator with a fairly constant load (isolation) and allows it to run continuously for better stability.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Undesired positive feedback in an RF amplifier causes parasitic oscillations: the amplifier becomes an oscillator. Inter-electrode capacitance (e.g., plate-to-grid), coupling from output to input, stray inductance or capacitance can start up oscillations. Neutralization is the process of cancelling positive-feedback paths. To test a tube amplifier for parasitic oscillations, connect nothing to the input and output terminals, apply DC power, monitor grid and plate current while slowly varying the controls on the output tuning network; if grid current develops or plate current changes, oscillations are present.

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One method of producing SSB is a Balanced Modulator followed by a filter. The modulator takes in a fixed-frequency RF signal and mixes it with audio from the speech amplifier. The modulator is said to be balanced because the two original inputs are not present at the output: carrier suppression has taken place. Present, however, are a lower and upper sideband. A subsequent filter selects one of the sidebands to complete the creation of a single sideband suppressed-carrier signal. Note that there is no RF output when no audio is applied.

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One method of producing SSB is a Balanced Modulator followed by a filter. The modulator takes in a fixed-frequency RF signal and mixes it with audio from the speech amplifier. The modulator is said to be balanced because the two original inputs are not present at the output: carrier suppression has taken place. Present, however, are a lower and upper sideband. A subsequent filter selects one of the sidebands to complete the creation of a single sideband suppressed-carrier signal. Note that there is no RF output when no audio is applied.

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One method of producing SSB is a Balanced Modulator followed by a filter. The modulator takes in a fixed-frequency RF signal and mixes it with audio from the speech amplifier. The modulator is said to be balanced because the two original inputs are not present at the output: carrier suppression has taken place. Present, however, are a lower and upper sideband. A subsequent filter selects one of the sidebands to complete the creation of a single sideband suppressed-carrier signal. Note that there is no RF output when no audio is applied.

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Under noisy conditions, SSB can bring up to a 9 dB improvement over an AM signal of the same peak power. In AM, the Peak Envelope Power present in one of the two sidebands equals one fourth the carrier power: e.g., a 100-watt AM transmitter only packs 25 watts PEP in each sideband. SSB concentrates all the available power in one sideband alone: a 4 to 1 improvement or 6 dB. Using half the bandwidth on SSB reception, permits taking in only half of the noise at the receiver, an additional 3 dB improvement.

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A two-tone test permits verifying the linearity of an SSB transmitter. The test requires a generator producing two low-distortion non-harmonically related audio sine waves of equal amplitude. The frequencies must fall within the normal transmitter audio passband: e.g., 700 and 1900 Hz. A sample of the transmitter's output is observed on an oscilloscope while the tones are fed into the microphone input. Feeding an SSB transmitter with two equal-amplitude steady audio tones produces two equal-amplitude RF signals: total power is thus twice the power present in each RF signal.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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A two-tone test permits verifying the linearity of an SSB transmitter. The test requires a generator producing two low-distortion non-harmonically related audio sine waves of equal amplitude. The frequencies must fall within the normal transmitter audio passband: e.g., 700 and 1900 Hz. A sample of the transmitter's output is observed on an oscilloscope while the tones are fed into the microphone input. Feeding an SSB transmitter with two equal-amplitude steady audio tones produces two equal-amplitude RF signals: total power is thus twice the power present in each RF signal.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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A two-tone test permits verifying the linearity of an SSB transmitter. The test requires a generator producing two low-distortion non-harmonically related audio sine waves of equal amplitude. The frequencies must fall within the normal transmitter audio passband: e.g., 700 and 1900 Hz. A sample of the transmitter's output is observed on an oscilloscope while the tones are fed into the microphone input. Feeding an SSB transmitter with two equal-amplitude steady audio tones produces two equal-amplitude RF signals: total power is thus twice the power present in each RF signal.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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A two-tone test permits verifying the linearity of an SSB transmitter. The test requires a generator producing two low-distortion non-harmonically related audio sine waves of equal amplitude. The frequencies must fall within the normal transmitter audio passband: e.g., 700 and 1900 Hz. A sample of the transmitter's output is observed on an oscilloscope while the tones are fed into the microphone input. Feeding an SSB transmitter with two equal-amplitude steady audio tones produces two equal-amplitude RF signals: total power is thus twice the power present in each RF signal.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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A two-tone test permits verifying the linearity of an SSB transmitter. The test requires a generator producing two low-distortion non-harmonically related audio sine waves of equal amplitude. The frequencies must fall within the normal transmitter audio passband: e.g., 700 and 1900 Hz. A sample of the transmitter's output is observed on an oscilloscope while the tones are fed into the microphone input. Feeding an SSB transmitter with two equal-amplitude steady audio tones produces two equal-amplitude RF signals: total power is thus twice the power present in each RF signal.

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"Most well-designed balanced modulators can provide between 30 and 50 dB of carrier suppression. ...The filter roll-off can be used to obtain an additional 20 dB of carrier suppression." (ARRL Handbook 1985)

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Flattening of the peaks is an extreme form of distortion where the output of the transmitter is incapable of reproducing the original pattern of the audio input on voice peaks. This is generally caused by excessive audio input to the transmitter: too much audio causes the amplifier stage to exceed its linear operation range. The purpose of the ALC (Automatic Level Control) is to prevent overdrive.

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Automatic Level Control (ALC) serves to prevent overdriving an amplifier. The ALC circuit samples the envelope (peak) of the RF output to develop a DC control voltage used to control the gain of an earlier stage. AGC and AVC are receiver circuits.

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Audio compression maintains a high voice level despite variations in the voice signal incoming from a microphone. To produce a high average output without exceeding a certain peak value, low level signals need to be amplified while high level signals are passed along with little or no gain. [ compression is the automatic reduction of gain as the signal level increases beyond a pre-set level known as the threshold. ]

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Key words: NOT ASSOCIATED WITH ANALOG. Compression, bandwidth limiting and clipping can all be performed as analog processes. Frequency division requires a numerical computation.

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The expression "peak limiting" entails limiting the amplitude. Compression, AF clipping and RF clipping are valid operations. There is no such thing as frequency clipping.

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Audio frequency clipping abruptly stops voltage excursions at a certain level. This gives the audio a square wave appearance; square waves are rich in harmonics. AF clippers need to be followed by a low-pass filter to prevent harmonics from entering modulation stages. You may also eliminate the bad answers: "reduction in peak amplitude" is the object of clipping, "increased average power" is a result of clipping (softer passages are no longer dwarfed by the peaks), "increased average power" simply contradicts the previous answer.

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Working at radio-frequencies is evidently more difficult and thus more expensive than dealing with audio frequencies. RF clipping is generally presumed to induce less distortion because any harmonics generated through clipping automatically end up outside the passband of subsequent filters. At audio frequencies, harmonics of the lower speech frequencies fall within the audio passband and can muddle the audio signal.

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Clipping places a hard limit on voltage swings. Compression is a reduction in gain when signal exceed a certain threshold. The ALC circuit samples the envelope (peak) of the RF output and produces a DC control voltage used to control the gain of an earlier stage when the output reaches a certain level.

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Deviation = the amount of frequency shift, at a given instant, from the centre carrier frequency (e.g., plus or minus 5 kHz). Modulation Index = the ratio of deviation to modulating frequency for a particular audio frequency (both being expressed in the same units): e.g., 3 kHz deviation with 1 kHz audio represents a Modulation Index of 3. Deviation Ratio = the ratio of maximum deviation to the maximum modulating frequency: e.g. maximum deviation of 5 kHz with a highest modulating frequency of 3 kHz is a Deviation Ratio of 1.66 .

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Deviation = the amount of frequency shift, at a given instant, from the centre carrier frequency (e.g., plus or minus 5 kHz). Modulation Index = the ratio of deviation to modulating frequency for a particular audio frequency (both being expressed in the same units): e.g., 3 kHz deviation with 1 kHz audio represents a Modulation Index of 3. Deviation Ratio = the ratio of maximum deviation to the maximum modulating frequency: e.g. maximum deviation of 5 kHz with a highest modulating frequency of 3 kHz is a Deviation Ratio of 1.66 .

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Deviation = the amount of frequency shift, at a given instant, from the centre carrier frequency (e.g., plus or minus 5 kHz). Modulation Index = the ratio of deviation to modulating frequency for a particular audio frequency (both being expressed in the same units): e.g., 3 kHz deviation with 1 kHz audio represents a Modulation Index of 3. Deviation Ratio = the ratio of maximum deviation to the maximum modulating frequency: e.g. maximum deviation of 5 kHz with a highest modulating frequency of 3 kHz is a Deviation Ratio of 1.66 .

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Deviation = the amount of frequency shift, at a given instant, from the centre carrier frequency (e.g., plus or minus 5 kHz). Modulation Index = the ratio of deviation to modulating frequency for a particular audio frequency (both being expressed in the same units): e.g., 3 kHz deviation with 1 kHz audio represents a Modulation Index of 3. Deviation Ratio = the ratio of maximum deviation to the maximum modulating frequency: e.g. maximum deviation of 5 kHz with a highest modulating frequency of 3 kHz is a Deviation Ratio of 1.66 .

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Centre Frequency is the transmitter output frequency in the absence of modulation. Frequency deviation and frequency shift both are synonyms for the offset in carrier frequency caused by modulation at a given instant. Modulating frequency relates to the audio frequency used for modulation.

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In Frequency Modulation, the amplitude of the modulation is translated into the importance of the deviation, the modulation frequency is reflected in the rhythm of the deviation.

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Unlike AM where a single modulating frequency creates only a pair of side frequencies (one on each side of the carrier), FM creates an infinite number of side frequency pairs; the Modulation Index influences the amplitude of the side frequencies through a mathematical relation known as a Bessel Function. The number of side frequencies with significant amplitude determines the required bandwidth. For certain Modulation Index values, there is zero energy at the centre frequency; the energy is then totally found in the side frequencies.

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Certain Modulation Index values cause nulls at the centre carrier frequency: e.g., the Bessel function returns zero for the carrier component at Modulation Indices of 2.4048, 5.5201 or 8.6537 . Detecting a carrier null permits determining deviation as Modulation Index times modulating frequency. For example, with a tone of 905 hertz and deviation set at 4996 hertz (nearly 5 kHz), a null in the carrier will be observed because 4996 Hz deviation for a tone of 905 Hz is a Modulation Index of 5.52 . An all-mode receiver with a sharp filter permits observing the carrier component. The procedure could be used to set a transmitter or calibrate a home-made deviation meter.

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Certain Modulation Index values cause nulls at the centre carrier frequency: e.g., the Bessel function returns zero for the carrier component at Modulation Indices of 2.4048, 5.5201 or 8.6537 . Detecting a carrier null permits determining deviation as Modulation Index times modulating frequency. For example, with a tone of 905 hertz and deviation set at 4996 hertz (nearly 5 kHz), a null in the carrier will be observed because 4996 Hz deviation for a tone of 905 Hz is a Modulation Index of 5.52 . An all-mode receiver with a sharp filter permits observing the carrier component. The procedure could be used to set a transmitter or calibrate a home-made deviation meter.

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Carson's Rule permits estimating the bandwidth of an FM signal: bandwidth equals twice the sum of deviation + modulating frequency, in this example, 5 + 3 = 8, twice 8 = 16. [ Mathematician and engineer John R. Carson (1887-1940) had predicted the approximate bandwidth of an FM signal circa 1922. ]

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In this example, the frequency multiplication ratio between oscillator and output is 12 ( 146.52 divided by 12.21 = 12 ). Hence, the oscillator needs only be shifted by 416.7 Hz, i.e., 5000 Hz divided by 12.

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Two methods exist to produce Frequency Modulation. The Direct Method supposes forcing deviation directly on the oscillator; deviation is then multiplied along with the oscillator frequency up to the operating frequency. Phase Modulation is an indirect method whereby the phase of the signal is affected (i.e., retarding/advancing) in step with the modulation by varying a reactance on a stage other than the oscillator.

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With direct FM, deviation is independent of modulating frequency, actual deviation is determined solely by the modulating amplitude. With Phase Modulation, deviation depends on the amount of phase shift and its rapidity, increasing modulating frequency results in proportionally more deviation even if amplitude is held constant. Because commercial standards were based on Phase Modulation, an FM transmitter requires an artificial boost in high frequency response so that PM and FM sound the same at the receiver. A pre-emphasis network tailors the frequency response in the FM transmitter. De-emphasis is employed in the receiver to restore a flat audio response.

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With direct FM, deviation is independent of modulating frequency, actual deviation is determined solely by the modulating amplitude. With Phase Modulation, deviation depends on the amount of phase shift and its rapidity, increasing modulating frequency results in proportionally more deviation even if amplitude is held constant. Because commercial standards were based on Phase Modulation, an FM transmitter requires an artificial boost in high frequency response so that PM and FM sound the same at the receiver. A pre-emphasis network tailors the frequency response in the FM transmitter. De-emphasis is employed in the receiver to restore a flat audio response.

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In this context, compression and clipping are AUDIO processes aimed at maintaining high average deviation without exceeding a given peak value. Two answers can be readily scratched as they pertain to radiofrequency (RF) paths. The microphone circuit is not suitable as the audio level at that point is too low for a simple clipper.

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Stability is paramount in all transmitters, frequency deviation ultimately determines bandwidth while linearity (absence of distortion) minimizes out-of-channel emissions. Carrier Suppression is a concern with SSB, pre-emphasis (FM transmitter) and de-emphasis (FM receiver) are simple resistor-capacitor networks.

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