Chapter 5: Radio Signals and Equipment

Section 5.1: Signal Review

a radio signal at one frequency, at constant power, is CW - continuous wave
adding information to a signal (via changes in frequency, phase angle, or amplitude) is modulation
the method of modulation is asignal's mode
an unmodulated signal carries no information
to recover information from a signal is demodulation
voice mode/phone mode - voice/speech is information
data mode/digital mode - data is information
analog - information can be understood by human
digital - information can be understood by computer

AM

amplitude modulation
information contained int he signal's envelope, or maximum instantaneous power for each cycle
AM signals have a carrier and 2 sidebands
AM signals with the carrier removed are double sideband DSB
AM signals with one sideband and the carrier removed are single sideband SSB

angle modulation

varying freq to add info is frequency modulation FM
amt that signal frequency varies is called deviation
phase angle can be varied with respect to reference phase, this is phase modulation
FM/PM can be decoded with same circuits
FM: changes amount of time signal takes to make a 360 degree cycle

PM - changes relative phase difference between signal and reference phase

FM and PM signals have one carrier, multiple sidebands
FM/PM are constant power (modulated or not)

bandwidth

definition of bandwidth - width outside of which the average power of the signal is attenuated by 26 dB below the mean power
typical bandwidth values:
- TV - 6 MHz
- AM - 6 kHz
- FM - 5-16 kHz
- SSB - 2-3 kHz
- Digital - 50-300 Hz
- CW - 100-300 Hz

Section 5.1 Summary

The process that changes the phase angle of an RF wave to convey information is phase modulation
the process that changes instantaneous frequency of RF wave to convey information is frequency modulation
Instantaneous power level of RF signal used to convey information in amplitude modulation AM
The phone emission with the narrowest bandwidth is SSB single sideband

Section 5.2: Radio's Building Bloccks

Oscillators, mixers, multipliers, modulators

Oscillators:

produce a pure sine wave, as close to 1 frequency as possible
oscillator has two parts:
- amplifier to increase gain
- feedback circuit to route some output back into input
if product of amplifier gain and amt of feedback are > 1, circuit's output will be self-sustaining - this is called oscillation
oscillator output frequency can be fixed or varied

fixed frequency oscillators FFOs: 3 types

RC (resistors/capacitors)
LC (inductors/capacitors)
crystal (acts like LC, orders of magnitude more precise)

variable frequency oscillators VFOs: 3 types

LC circuit with variable capacitor
PLL phase locked loop
DDS direct digital synthesizer (software-controlled, has stability of crystal oscillator)

Mixers:

changing frequency of signal is key function in RX/TX
this is what mixer does
- in: f1, f2
- out: f1 +/- f2
mixers combine 2 frequencies f1 and f2
combine to form f1 + f2 and f1 - f2
heterodyning - the mixing of 2 frequencies (f1 +/- f2)
input f1 is called RF input (transmitted signal)
input f2 is called local oscillator LO (locally-generated reference signal)
outputs from mixer are called mixing products

Multipliers:

this unit creates a harmonic of the input frequency (multiplies by an integer)
low-frequency oscillators are easier/smaller to build, so run low-frequency oscillator signal through a multiplier to make a VHF/UHF signal

Modulators:

modulators add information to a carrier signal
information added to a signal as amplitude, frequency, or phase variations
input 1 is carrier input f1
input 2 is modulating input f2
output is f1 modulated by f2

Amplitude Modulators:

first created by varying the power supply voltage of a CW signal
as voltage changes, amplituded of output signal's envelope follows along
also called plate modulation, or drain modulation, or collector modulation
- plate modulation: voltage being varied connects to a vacuum tube
- drain modulation - voltage being varied connect to transistor's drain
- collector modulation - voltage being varied connects to a transistor's collector
modulation transformer then adds/subtracts amplified voice signal to power supply voltage
AM circuits cannot generate SSB signals
AM, double sideband can be generated by balanced modulator
balanced modulator:
- input 1: carrier signal f1
- input 2: modulating signal f2
- output signal: double sideband f1 +/- f2
- the pairs of sidebands, above and below, are due to heterodyning, f1 +/- f2
DSB - double sideband requires a balanced modulator, so the carrier frequency will cancel out
AM - requires an unbalanced modulator, so the carrier frequency will survive heterodyning

Frequency and Phase Modulators:

FM - frequency of modulated signal changes with modulating signal's amplitude
PM - frequency of modulated signal (deviation of signal) is proportional to modulating signal's amplitude and frequency
FM/PM sound the same, demodulated with same circuit
angle modulation performed with a reactance modulator
two types of reactance modulators:
- FM reactance modulators
- PM reactance modulators
FM reactance modulator: amp feeds into reactance modulator, output is frequency modulated output
PM reactance modulator: amp and fixed-frequency oscillator feed into reactance modulator, output is phase modulated output

Section 5.2 Summary

if a 3 kHz LSB signal has a carrier frequency of 7.178 MHz, it occupies 7.175-7.178 MHz
if using 3 kHz USB signal on 20 m, how close to edge of band should carrier signal be? 3 kHz below edge of band
basic components of a sine wave oscillator are an amplifier and a feedback circuit with a filter
frequency of LC oscillator can vary depending on component ratings - individual inductances and capacitances
a transceiver controlled by a direct digital synthesizer is that you have stability of a crystal, with variable frequency
a reactance modulator connected to RF amplifier stage generates phase modulation or frequency modulation
carrier suppression in SSB phone - the advantage over AM is that transmitter power can be used more efficiently (narrower bandwidth)
the receiver stage that combines a 14.250 MHz signal with a 13.795 MHz oscillator to produce a 455 kHz intermediate frequency is a mixer (heterodyning)
the mixing of two signals is called heterodyning
in a VHF/UHF transmitter (FM), the stage that generates a harmonic of a low-frequency signal is the multiplier

Section 5.3: Transmitter Structure

transmitters and receivers are assembled from the following building blocks:

am modes

CW, SSB, and AM are all types of amplitude-modulated signals
generated by same transmitter structure
analog transmitters: generate/modify signals with discrete electronic components
DSP/SDR transmitters perform these operations in software, on a microprocessor

CW transmitters

oscillator + amplifier
crystal oscillator restricts operating frequency, but is stable
variable frequency oscillator VFO controlled transmitter
oscillator may contain buffer amplifier to protect from chirps - rapid change in frequency (key-down periods due to power supply, or load changes)
output amplifier: two stages
- driver stage
- power amplifier stage
VFO transmitter, mixers used to change TX output frequency without changing VFO frequency range
schematic: VFO has a fixed range, fed into mixer. other feed into mixer is local oscillator - switch between three different crystals. the mixer output is sent to the filter, and combined with the keyer to send out a signal.

SSB transmitter:

same arrangement, but the VFO is now replaced with a microphone circuit
input to balanced modulator is carrier signal, plus microphone input
output is DSB signal, so filter is required to remove the undesired sideband
USB signals on 20 m, LSB on 80 and 40 m
mixer then converts signal to correct frequency
SSB transmitter can unbalance the modulator to generate AM signals
SSB signals: carrier must be reduced or suppressed to at least 40 dB below signal's peak power output, to prevent interference
output amplifier must be a linear amplifier, due to rapidly changing speech waveforms
nonlinear amplifier will distort speech
CW transmitter turns sine wave on/off, no need to be linear
SSB/AM stages must all reproduce input signal accurately, via mixing, filtering, amplifying
distortion in the transmit chain will create suprious signals, harmonics, mixing products, splatter
SSB bandwidth should be 3 kHz or smaller
AM bandwidth should be 6 kHz or smaller
on 60 m, USB signals hsould be 2.8 kHz or narrower

FM transmitters:

modulation and frequency changes work differently in FM TX than SSB/AM TX
less expensive implementation of FM:
- generate FM signal at low frequency
- multiply it to reach new band
for 2 m FM transmitter, modulated oscillator frequency is about 12 MHz, and multiplier selects 12th harmonic for transmission on 2 m (12 x 12 = 144 MHz)
To transmit a signal at 146.52 MHz, you must use the 12th harmonic, so the oscillator frequency must be adjusted to 146.52/12 = 12.21 MHz
Deviation from crystal is also multiplied
to control deviation of 146.52 MHz to within 5 kHz, crystal oscillator deviation should be 5/12 = .416 kHz = 416.7 Hz
good FCC practice requires bandwidth to be limited
Carson's Rule: BW = 2 x ( Peak Deviation + Highest Modulating Frequency)
If FM phone signal peak deviation is 5 kHz, and highest modulating frequency is 3 kHz, bandwidth = 2(5+3) = 16 kHz
Repeater coordinators use 20 kHz channel, fits 16 kHz wide signal comfortably
FM and PM phase modulation have constant power, so amplifier does not need to be linear

Signal quality:

keep signals intelligible and prevent excessive bandwidth
potential issues:
- overmodulation - AM modes
- Speech processing
- Overdeviation - FM/AM
- key clicks

Overmodulation - AM modes:

if amplitude of AM or SSB signal is varied excessively in response to modulating signal, result is overmodulation
overmodulation caused by speaking too loudly or by setting mic or audio gain too high
overmodulation causes spurious signals in nearby frequencies
modulation envelope - waveform created by connecting peaks of modulated signal
cutoff - transmitter is turned off instead of following the modulated signal (floor is too high)
flag-topping - transmitter reaches max output and cannot increase with signal (ceiling too low)
transmitted audio is distorted
spurious signals are created
- distortion products
- splatter
- buckshot
properly adjust mic gain
use oscilloscope to check for clean signal at TX output
note transmitter settings and meter behavior, and oscilloscope images
flat topping happens when drive level to transmitter output or external amplifiers is beyond the max power level
carrier cutoff occurs when output signal is totally cut off between peaks
use normal speech/audio levels
use monitor function to check own signal
ALC - automatic level control
two tone test for transmitter linearity:
- modulate signal with pair of non-harmonic tones
- adjust transmitter and amplifier for output without any distortion

speech processing:

average power of SSB signal is low compared to CW
energy spread over wider spectrum
makes signals harder to understand through noise
speech processing increases average power of speech signal without distorting signal
some processors go between mic and radio, some go between radio and amplifier
compression - increases gain at low input levels, holds gain constant for hi input levels
amount of compression mesasured in dB
- if low-level input signal is amplified to 10 dB more gain than high-level signal, you have 10 dB of compression
overprocesssing can also be an issue
processed signals require adjustment of transmitter modulation to avoid splatter
speech processing can increase background noise too
speech processing requires balance between increase in average power versus reduction in intelligibility

overdeviation

distortion in FM signals happening due to overmodulation
instead of envelope distortion, you get frequency deviation
overdeviation of FM signals will cause interference nearby, just like AM

Key clicks:

sharp transient clicking sounds heard on frequencies adjacent to CW signals
caused by transmitter turning on and off
reduce key clicks by adjusting TX configuration or by modifying keyer's control circuit
use oscilloscope to monitor CW waveform
leading adn trailing edges of CW output shoudl be 4-8 ms long, otherwise clicks will be generated from too-rapid on/off
waveform: key clicks will show up as signals in sidebands

amplifiers:

hf operators use amps to strength signals
VHF/UHF amps are solid state bricks
HF amps use vacuum tube circuits
SSB modes require linear amplifier, so wave form input not distorted
amplifier circuit = stage
four classes of amplifier stages:
- Class A - most linear, least efficient, on all the time, gain is limited
- Class B - push-pull, pair of amplifiers switching on and off with cycle, good efficiency, linearity is possible
- Class AB - midway between A and B, amplifier device is active for more than half of the cycle. Linearity not as good as Class A.
- Class C - active for less than half of cycle, highest efficiecy, only work for CW and FM due to non-linearity

Tuning Linear Amplifier:

3 primary operator adjustments
- band
- tune
- load/coupling
band - configures input and output impedance matching or filter circuits
tune/load adjust components in output matching circuit (pi network)
start by setting the band switch properly
apply drive power to amplifier, wtch current meter
adjust tune control for a minimum setting, which indicates output matching circuit is resonant with input signal
adjust load to maximize output power, then adjust tune to plate-current minimum
this will enable max output power without max plate current being exceeded
drive power important, esp. for grid-driven amplifier circuits
too much drive causes excessive grid current
modern amplifiers have circuitry to protect circuits against excessive grid drive
operate amp according to mfg specs!
excessive drive power can also destroy solid state amplifiers with power transistors

neutralization:

for oscillations, positive feedback must lead to a gain > 1
HF amplifiers using triode tubes can become self-oscillating at VHF frequencies
main path for positive feedback in a grid-driven amplifier is inter-electrode capacitance (voltage difference between plate and control grid)
self-oscillation geneates spurious signals, can damage circuit components
neutalization: creates negative feedback at VHF - connect an out-of-phase signal with input signal to cancel unwanted positive feedback
neutralization is performed by connecting small variable apacitor between amplifier's output and input

Section 5.3 Summary

Transceiver operated in "split mode" means it transmits/receives on different frequencies
on a vacuum tube RF power amp, the plate current meter indicates correct plate tuning control when there is a dip or minimum
use ALC auto level control with RF power amp to reduce distortion due to excessive drive
in a solid state RF amplifier, excessive drive power can cause damage
the correct adjustment for the load/coupling control of a vacuum tube RF power amplifier is maximum power output - while not exceeding maximum plate current
transmitter keying circuits include time delay so that transmit-receive changeover operations can complete properly before RF output is allowed
common use for a dual VFO feature on transceiver is to allow monitoring of 2 different frequencies
to conduct a two-tone test, use two non-harmonically related signals
the two-tone test analyzes transmitter linearity
on modern transciever, speech processor is used to increase intelligibility of voice signals
for ssb phone signal, speech processor will increase average power
incorrectly adjusted speech processor will result in all of these:
- distorted speech
- splatter
- excessive bkgd noise
efficiency of RF power amplifier is obtained by: Efficiency = (RF output power)/(DC input power)
Class A linear amplifier has the following characteristic: low distortion (but inefficient)
Class C power stage is used to amplify CW signals (not SSB, not AM, because nonlinear and distorts speech waveform)
Amplifier with highest efficiency is Class C, the most non-linear. The least efficient is Class A, the most linear.
The final amplifier stage of a transmitter is neutralized to eliminate self-oscillations
a linear amplifier is an amplifier that preserves the output wave form
in some ssb transmitters, a filter sits between the balanced modulator and the mixer
in some ssb transmitters, a balanced modulator combines the carrier oscillator and speech amp signals and sends the results to a filter
an effect of overmodulation is excessive bandwidth
to adjust proper ALC settings, on ssb, adjust transmit audio or mic gain
flat topping means signal distorition caused by excessive drive
an AM signal's modulation envelope is the waveform created by connecting peak values of modulated signal

Section 5.4: Receiver Structure

Section 5.4 Summary

Flags

General/Chapter 5 Study Guide

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