Transmitters and Receivers PDF

Summary

This chapter explores radio transmitter configurations and associated circuits. It covers oscillator, amplifier, and impedance-matching topics. It discusses modulation techniques and different power amplifier classes. Notably, it explains the principles of high-level and low-level FM and AM modulation.

Full Transcript

chapter

8
Radio Transmitters
A radio transmitter takes the information to be communicated and con-
verts it to an electronic signal compatible with the communication medium.
Typically this process involves carrier generation, modulation, and power
amplification. The signal is then fed by wire, coaxial cable, or waveguide
to an antenna that launches it into free space. This chapter covers trans-
mitter configurations and the circuits commonly used in radio transmitters,
including oscillators, amplifiers, frequency multipliers, and impedance-
matching networks.

Objectives
After completing this chapter, you will be able to:
Calculate the frequency tolerance of crystal oscillators in percent
and in parts per million (ppm).
Discuss the operation of phase-locked loop (PLL) and direct digital
synthesis (DDS) frequency synthesizers, and explain how the output
frequency is changed.
Calculate the output frequency of a transmitter given the oscillator
frequency and the number and types of multipliers.
Explain the biasing and operation of class A, AB, and C power
amplifiers using transistors.
Discuss the operation and benefits of class D, E, and F switching
amplifiers, and explain why they are more efficient.
Explain the operation and benefits of feedforward, digital
predistortion, Doherty, envelope tracking, and GaN power amplifiers.
Explain the basic design of L, π, and T-type LC circuits, and discuss
how they are used for impedance matching.
Explain the use of transformers and baluns in impedance matching.

236
8-1 Transmitter Fundamentals
The transmitter is the electronic unit that accepts the information signal to be transmitted Transmitter
and converts it to an RF signal capable of being transmitted over long distances. Every
transmitter has four basic requirements.
1. It must generate a carrier signal of the correct frequency at a desired point in the
spectrum.
2. It must provide some form of modulation that causes the information signal to modify
the carrier signal.
3. It must provide sufficient power amplification to ensure that the signal level is high
enough to carry over the desired distance.
4. It must provide circuits that match the impedance of the power amplifier to that of
the antenna for maximum transfer of power.

Transmitter Configurations
The simplest transmitter is a single-transistor oscillator connected directly to an antenna.
The oscillator generates the carrier and can be switched off and on by a telegraph key to
produce the dots and dashes of the International Morse code. Information transmitted
in this way is referred to as continuous-wave (CW) transmission. Such a transmitter is Continuous-wave (CW)
rarely used today, for the Morse code is nearly extinct and the oscillator power is too transmission
low for reliable communication. Nowadays transmitters such as this are built only by
amateur (ham) radio operators for what is called QRP or low-power operation for per-
sonal hobby communication.
The CW transmitter can be greatly improved by simply adding a power amplifier to
it, as illustrated in Fig. 8-1. The oscillator is still keyed off and on to produce dots and
dashes, and the amplifier increases the power level of the signal. The result is a stronger
signal that carries farther and produces more reliable transmission.
The basic oscillator-amplifier combination shown in Fig. 8-1 is the basis for virtually
all radio transmitters. Many other circuits are added depending on the type of modulation
used, the power level, and other considerations.

High-Level AM Transmitters. Fig. 8-2 shows an AM transmitter using high-level
modulation. An oscillator, in most applications a crystal oscillator, generates the final
carrier frequency. The carrier signal is then fed to a buffer amplifier whose primary
purpose is to isolate the oscillator from the remaining power amplifier stages. The buf-
fer amplifier usually operates at the class A level and provides a modest increase in
power output. The main purpose of the buffer amplifier is simply to prevent load changes

Figure 8-1 A more powerful CW transmitter.

Antenna
Power
amplifier
Oscillator

Key
Crystal

Radio Transmitters 237
Figure 8-2 An AM transmitter using high-level collector modulation.

Final
power
Carrier amplifier
oscillator Driver

Buffer
amplifier

Audio
amplifier
Speech
processing
Microphone Driver
Modulation
amplifier

in the power amplifier stages or in the antenna from causing frequency variations in the
oscillator.
The signal from the buffer amplifier is applied to a class C driver amplifier designed
to provide an intermediate level of power amplification. The purpose of this circuit is to
Final power amplifier generate sufficient output power to drive the final power amplifier stage. The final power
amplifier, normally just referred to as the final, also operates at the class C level at very
high power. The actual amount of power depends on the application. For example, in a
CB transmitter, the power input is only 5 W. However, AM radio stations operate at much
higher powers — say, 250, 500, 1000, 5000, or 50,000 W — and the video transmitter at
a TV station operates at even higher power levels. Cell phone base stations operate at
GOOD TO KNOW the 30- to 40-W level.
AM radio stations can operate at All the RF circuits in the transmitter are usually solid-state; i.e., they are imple-
power levels up to 50,000 W, and mented with either bipolar transistors or metal-oxide semiconductor field-effect transis-
TV video transmissions operate at tors (MOSFETs). Although bipolar transistors are by far the most common type, the use
of MOSFETs is increasing because they are now capable of handling high power at high
even higher levels. In contrast, the
frequencies. Transistors are also typically used in the final as long as the power level
power input of a citizens band does not exceed several hundred watts. Individual RF power transistors can handle up
(CB) transmitter is only 5 W. to about 800 W. Many of these can be connected in parallel or in push-pull configura-
tions to increase the power-handling capability to many kilowatts. For higher power
levels, vacuum tubes are still used in some transmitters, but rarely in new designs. Vac-
uum tubes function into the VHF and UHF ranges, with power levels of 1 kW or more.
Now, assume that the AM transmitter shown in Fig. 8-2 is a voice transmitter. The input
from the microphone is applied to a low-level class A audio amplifier, which boosts the
small signal from the microphone to a higher voltage level. (One or more stages of ampli-
Speech processing fication could be used.) The voice signal is then fed to some form of speech-processing
(filtering and amplitude control) circuit. The filtering ensures that only voice frequencies in
a certain range are passed, which helps to minimize the bandwidth occupied by the signal.
Most communication transmitters limit the voice frequency to the 300- to 3000-Hz range,
which is adequate for intelligible communication. However, AM broadcast stations offer
higher fidelity and allow frequencies up to 5 kHz to be used. In practice, many AM stations
modulate with frequencies up to 7.5 kHz, and even 10 kHz, since the FCC uses alternate
channel assignments within a given region and the outer sidebands are very weak, so no
adjacent channel interference occurs.

238 Chapter 8
 Speech processors also contain a circuit used to hold the amplitude to some maxi-
mum level. High-amplitude signals are compressed and lower-amplitude signals are given
more amplification. The result is that overmodulation is prevented, yet the transmitter
operates as close to 100 percent modulation as possible. This reduces the possibility of
signal distortion and harmonics, which produce wider sidebands that can cause adjacent
channel interference, but maintains the highest possible output power in the sidebands.
After the speech processor, a driver amplifier is used to increase the power level of
the signal so that it is capable of driving the high-power modulation amplifier. In the AM
transmitter of Fig. 8-2, high-level or collector modulation (plate modulation in a tube) is
used. As stated previously, the power output of the modulation amplifier must be one-half
the input power of the RF amplifier. The high-power modulation amplifier usually operates
with a class AB or class B push-pull configuration to achieve these power levels.

Low-Level FM Transmitters. In low-level modulation, modulation is performed on
the carrier at low power levels, and the signal is then amplified by power amplifiers. This
arrangement works for both AM and FM. FM transmitters using this method are far more
common than low-level AM transmitters.
Fig. 8-3 shows the typical configuration for an FM or PM transmitter. The indirect
method of FM generation is used. A stable crystal oscillator is used to generate the car-
rier signal, and a buffer amplifier is used to isolate it from the remainder of the circuitry.
The carrier signal is then applied to a phase modulator such as those discussed in Chap. 6.
The voice input is amplified and processed to limit the frequency range and prevent
overdeviation. The output of the modulator is the desired FM signal.
Most FM transmitters are used in the VHF and UHF range. Because crystals are not
available for generating those frequencies directly, the carrier is usually generated at a
frequency considerably lower than the final output frequency. To achieve the desired
output frequency, one or more frequency multiplier stages are used. A frequency multi-
plier is a class C amplifier whose output frequency is some integer multiple of the input
frequency. Most frequency multipliers increase the frequency by a factor of 2, 3, 4, or
5. Because they are class C amplifiers, most frequency multipliers also provide a modest
amount of power amplification.
Not only does the frequency multiplier increase the carrier frequency to the desired
output frequency, but also it multiplies the frequency deviation produced by the modula-
tor. Many frequency and phase modulators generate only a small frequency shift, much
lower than the desired final deviation. The design of the transmitter must be such that
the frequency multipliers will provide the correct amount of multiplication not only for
the carrier frequency, but also for the modulation deviation. After the frequency multiplier
stage, a class C driver amplifier is used to increase the power level sufficiently to oper-
ate the final power amplifier, which also operates at the class C level.

Figure 8-3 A typical FM transmitter using indirect FM with a phase modulator.

Frequency
multipliers
Carrier
oscillator
Phase
modulator
Buffer Driver Final
power
amplifier

Audio
amplifier
Speech
processing
Microphone

Radio Transmitters 239
Figure 8-4 An SSB transmitter.

Carrier Balanced
oscillator modulator Mixer
Sideband
filter
Buffer Linear Final linear
driver
power amplifier
amplifier

Tuned
circuit

Microphone

Speech
processing
Audio LO
amplifier

Most FM communication transmitters operate at relatively low power levels, typ-
ically less than 100 W. All the circuits, even in the VHF and UHF range, use transistors.
For power levels beyond several hundred watts, vacuum tubes must be used. The final
amplifier stages in FM broadcast transmitters typically use large vacuum tube class C
amplifiers. In FM transmitters operating in the microwave range, klystrons, magnetrons,
and traveling-wave tubes are used to provide the final power amplification.

Single-sideband (SSB) transmitter SSB Transmitters. A typical single-sideband (SSB) transmitter is shown in Fig. 8-4. An
oscillator signal generates the carrier, which is then fed to the buffer amplifier. The buffer
amplifier supplies the carrier input signal to the balanced modulator. The audio amplifier and
speech-processing circuits described previously provide the other input to the balanced mod-
ulator. The balanced modulator output — a DSB signal — is then fed to a sideband filter that
selects either the upper or lower sideband. Following this, the SSB signal is fed to a mixer
circuit, which is used to convert the signal to its final operating frequency. Mixer circuits,
which operate as simple amplitude modulators, are used to convert a lower frequency to a
higher one or a higher frequency to a lower one. (Mixers are discussed more fully in Chap. 9.)
Typically, the SSB signal is generated at a low RF. This makes the balanced modula-
tor and filter circuits simpler and easier to design. The mixer translates the SSB signal to
a higher desired frequency. The other input to the mixer is derived from a local oscillator
set at a frequency that, when mixed with the SSB signal, produces the desired operating
frequency. The mixer can be set up so that the tuned circuit at its output selects either the
sum or the difference frequency. The oscillator frequency must be set to provide the desired
output frequency. For fixed-channel operation, crystals can be used in this local oscillator.
Variable frequency oscillator (VFO) However, in some equipment, such as that used by hams, a variable frequency oscillator
(VFO) is used to provide continuous tuning over a desired range. In most modern com-
munication equipment, a frequency synthesizer is used to set the final output frequency.
The output of the mixer in Fig. 8-4 is the desired final carrier frequency containing
the SSB modulation. It is then fed to linear driver and power amplifiers to increase the
power level as required. Class C amplifiers distort the signal and therefore cannot be
used to transmit SSB or low-level AM of any kind, including DSB. Class A or AB
linear amplifiers must be used to retain the information content in the AM signal.

Digital Transmitters. Most modern digital radios such as cell phones use DSP to
produce the modulation and related processing of the data to be transmitted. Refer to
Fig. 8-5. The serial data representing the data to be transmitted is sent to the DSP, which
then generates two data streams that are then converted to RF for transmission. The data
paths from the DSP chip are sent to DACs where they are translated to equivalent analog

240 Chapter 8
Figure 8-5 Modern digital transmitter.

LPF Mixer
I I
DAC

cos
90
DSP  PA
Serial sin
digital Osc.
data to be Summer
transmitted
Q
DAC
Q
LPF Mixer

signals. The analog signals are filtered in a low-pass filter (LPF) and then applied to
mixers that will up-convert them to the final output frequency. The mixers receive their
second inputs from an oscillator or a frequency synthesizer that selects the operating
frequency. Note that the oscillator signals are in quadrature; i.e., one is shifted 90° from
the other. One is a sine wave, and the other is a cosine wave. The upper signal is referred
to as the in-phase (I ) signal and the other as the quadrature (Q) signal. The output signals
from the mixers are then added, and the result is amplified and transmitted by the power
amplifier (PA). Two quadrature signals are needed at the receiver to recover the signal
and demodulate it in a DSP chip. This configuration works for any type of modulation
as all of the modulation is done with mathematical algorithms. You will learn more about
this technique in Chap. 11.

8-2 Carrier Generators Carrier generator
The starting point for all transmitters is carrier generation. Once generated, the carrier
can be modulated, processed in various ways, amplified, and finally transmitted. The
source of most carriers in modern transmitters is a crystal oscillator. PLL frequency
synthesizers in which a crystal oscillator is the basic stabilizing reference are used in
applications requiring multiple channels of operation.

Crystal Oscillators Crystal oscillator
Most radio transmitters are licensed by the FCC either directly or indirectly to operate Crystal
not only within a specific frequency band but also on predefined frequencies or chan- Piezoelectric effect
nels. Deviating from the assigned frequency by even a small amount can cause interfer-
ence with signals on adjacent channels. Therefore, the transmitter carrier generator must
be very precise, operating on the exact frequency assigned, often within very close
tolerances. In some radio services, the frequency of operation must be within 0.001 GOOD TO KNOW
percent of the assigned frequency. In addition, the transmitter must remain on the
assigned frequency. It must not drift off or wander from its assigned value despite the The only oscillator capable of
many operating conditions, such as wide temperature variations and changes in power maintaining the frequency preci-
supply voltage, that affect frequency. The only oscillator capable of meeting the preci- sion and stability demanded by
sion and stability demanded by the FCC is a crystal oscillator. the FCC is a crystal oscillator.
A crystal is a piece of quartz that has been cut and ground into a thin, flat wafer In fact, the FCC requires that a
and mounted between two metal plates. When the crystal is excited by an ac signal
crystal oscillator be used in all
across its plates, it vibrates. This action is referred to as the piezoelectric effect. The
frequency of vibration is determined primarily by the thickness of the crystal. Other transmitters.
factors influencing frequency are the cut of the crystal, i.e., the place and angle of cut

Radio Transmitters 241
 made in the base quartz rock from which the crystal was derived, and the size of the
crystal wafer. Crystals frequencies range from as low as 30 kHz to as high as 150 MHz.
As the crystal vibrates or oscillates, it maintains a very constant frequency. Once a
crystal has been cut or ground to a particular frequency, it will not change to any great
extent even with wide voltage or temperature variations. Even greater stability can be
achieved by mounting the crystal in sealed, temperature-controlled chambers known as
crystal ovens. These devices maintain an absolute constant temperature, ensuring a
stable output frequency.
As you saw in Chap. 4, the crystal acts as an LC tuned circuit. It can emulate a series
or parallel LC circuit with a Q as high as 30,000. The crystal is simply substituted for
the coil and capacitor in a conventional oscillator circuit. The end result is a very precise,
stable oscillator. The precision, or stability, of a crystal is usually expressed in parts per
million (ppm). For example, to say that a crystal with a frequency of 1 MHz has a preci-
sion of 100 ppm means that the frequency of the crystal can vary from 999,900 to
1,000,100 Hz. Most crystals have tolerance and stability values in the 10- to 1000-ppm
range. Expressed as a percentage, the precision is (100/1,000,000) 3 100 5 0.0001 3
100 5 0.01 percent.
You can also use ratio and proportion to figure the frequency variation for a crystal
with a given precision. For example, a 24-MHz crystal with a stability of 650 ppm has
a maximum frequency variation ¢f of (50/1,000,000) 3 24,000,000. Thus, ¢ f 5
50(24,000,000)/1,000,000 5 24 3 50 5 1200 Hz or 61200 Hz.

Example 8-1
What are the maximum and minimum frequencies of a 16-MHz crystal with a stability
of 200 ppm?
The frequency can vary as much as 200 Hz for every 1 MHz of frequency or
200 3 16 5 3200 Hz.
The possible frequency range is
16,000,000 2 3200 5 15,996,800 Hz
16,000,000 1 3200 5 16,003,200 Hz
Expressed as a percentage, this stability is (3200/16,000,000) 3 100 5
0.0002 3 100 5 0.02 percent.
In other words, the actual frequency may be different from the designated fre-
quency by as much as 50 Hz for every 1 MHz of designated frequency, or
24 3 50 5 1200 Hz.
A precision value given as a percentage can be converted to a ppm value as follows.
Assume that a 10-MHz crystal has a precision percentage of 60.001 percent;
0.001 percent of 10,000,000 is 0.00001 3 10,000,000 5 100 Hz.
Thus,
ppm/1,000,000 5 100/10,000,000
ppm 5 100(1,000,000)/10,000,000 5 10 ppm
However, the simplest way to convert from percentage to ppm is to convert the
percentage value to its decimal form by dividing by 100, or moving the decimal point
two places to the left, and then multiplying by 106, or moving the decimal point six
places to the right. For example, the ppm stability of a 5-MHz crystal with a precision
of 0.005 percent is found as follows. First, put 0.005 percent in decimal form:
0.005 percent 5 0.00005. Next, multiply by 1 million:
0.00005 3 1,000,000 5 50 ppm

242 Chapter 8
Example 8-2
A radio transmitter uses a crystal oscillator with a frequency of 14.9 MHz and a
frequency multiplier chain with factors of 2, 3, and 3. The crystal has a stability of
6300 ppm.
a. Calculate the transmitter output frequency.
Total frequency multiplication factor 5 2 3 3 3 3 5 18
Transmitter output frequency 5 14.9 MHz 3 18
5 268.2 MHz

b. Calculate the maximum and minimum frequencies that the transmitter is likely to
achieve if the crystal drifts to its maximum extreme.
300
6300 ppm 5 3 100 5 6 0.03%
1,000,000
This variation is multiplied by the frequency multiplier chain, yielding
60.03 percent 3 18 5 60.54 percent. Now, 268.2 MHz 3 0.0054 5 1.45 MHz.
Thus, the frequency of the transmitter output is 268.2 6 1.45 MHz. The upper
limit is
268.2 1 1.45 5 269.65 MHz
The lower limit is
268.2 2 1.45 5 266.75 MHz

Typical Crystal Oscillator Circuits. The most common crystal oscillator is a
Colpitts type, in which the feedback is derived from the capacitive voltage divider made Colpitts oscillator
up of C1 and C2. An emitter-follower version is shown in Fig. 8-6. Again, the feedback
comes from the capacitor voltage divider C1–C2. The output is taken from the emitter,
which is untuned. Most oscillators of this type operate as class A amplifiers with a sine
wave output. JFETs are also widely used in discrete component amplifiers.
Occasionally you will see a capacitor in series or in parallel with the crystal (not
both), as shown in Fig. 8-6. These capacitors can be used to make minor adjustments in

Figure 8-6 An emitter-follower crystal oscillator.

V

R1

Q1
C1
Output

R2
XTAL
C2

Crystal “pulling”
or “rubbering”
capacitors

Radio Transmitters 243
 the crystal frequency. As discussed previously, it is not possible to affect large frequency
changes with series or shunt capacitors, but they can be used to make fine adjustments.
The capacitors are called crystal pulling capacitors, and the whole process of fine-tuning
Rubbering a crystal is sometimes referred to as rubbering. When the pulling capacitor is a varactor,
FM or FSK can be produced. The analog or binary modulating signal varies the varactor
capacitance that, in turn, shifts the crystal frequency.

Overtone Oscillators. The main problem with crystals is that their upper frequency
operation is limited. The higher the frequency, the thinner the crystal must be to oscillate
at that frequency. At an upper limit of about 50 MHz, the crystal is so fragile that it
becomes impractical to use. However, over the years, operating frequencies have contin-
ued to move upward as a result of the quest for more frequency space and greater chan-
nel capacity, and the FCC has continued to demand the same stability and precision that
are required at the lower frequencies. One way to achieve VHF, UHF, and even micro-
wave frequencies using crystals is by employing frequency multiplier circuits, as described
earlier. The carrier oscillator operates on a frequency less than 50 MHz, and multipliers
raise that frequency to the desired level. For example, if the desired operating frequency
is 163.2 MHz and the frequency multipliers multiply by a factor of 24, the crystal fre-
quency must be 163.2/24 5 6.8 MHz.
Another way to achieve crystal precision and stability at frequencies above 50 MHz
Overtone crystal is to use overtone crystals. An overtone crystal is cut in a special way so that it optimizes
its oscillation at an overtone of the basic crystal frequency. An overtone is like a harmonic
as it is usually some multiple of the fundamental vibration frequency. However, the term
Harmonic harmonic is usually applied to electric signals, and the term overtone refers to higher
Overtone mechanical vibration frequencies. Like a harmonic, an overtone is usually some integer
multiple of the base vibration frequency. However, most overtones are slightly more or
slightly less than the integer value. In a crystal, the second harmonic is the first overtone,
the third harmonic is the second overtone, and so on. For example, a crystal with a
fundamental frequency of 20 MHz would have a second harmonic or first overtone of
40 MHz, and a third harmonic or second overtone of 60 MHz.
The term overtone is often used as a synonym for harmonic. Most manufacturers
GOOD TO KNOW refer to their third overtone crystals as third harmonic crystals.
Overtones refer to multiples of the The odd overtones are far greater in amplitude than the even overtones. Most overtone
harmonic frequency. The second crystals oscillate reliably at the third or fifth overtone of the frequency at which the crystal
harmonic is the first overtone, the is originally ground. There are also seventh-overtone crystals. Overtone crystals can be
obtained with frequencies up to about 250 MHz. A typical overtone crystal oscillator may
third harmonic is the second
use a crystal cut for a frequency of, say, 16.8 MHz and optimized for overtone service will
overtone, and so on. have a third-overtone oscillation at 3 3 16.8 5 50.4 MHz. The tuned output circuit made
up of L1 and C1 will be resonant at 50.4 MHz.
Most crystal oscillators are circuits built into other integrated circuits. The crystal is
external to the IC. Another common form is that shown in Fig. 8-7, where the crystal and
oscillator circuit are fully packaged together as an IC. Both sine and square output versions
are available.
There are many different versions of these packaged crystal oscillators. These are the
basic crystal oscillator (XO), the voltage-controlled crystal oscillator (VCXO), the tempera-
ture-compensated crystal oscillator (TCXO), and the oven-controlled crystal oscillator
(OCXO). The selection depends upon the desired degree of frequency stability required by
the application. The basic XO has a stability in the tens of ppm.
A VCXO uses a varactor in series or parallel with the crystal (Fig. 8-6) to vary the
crystal frequency over a narrow range with an external DC voltage.
Improved stability is obtained in the TCXO, which uses a feedback network with a
thermistor to sense temperature variations, which in turn controls a voltage variable capacitor
(VVC) or varactor to pull the crystal frequency to some desired value. TCXOs can achieve
stability values of 60.2 to 62 ppm.
An OCXO packages the crystal and its circuit in a temperature-controlled oven that
holds the frequency stable at the desired frequency. A thermistor sensor in a feedback network

244 Chapter 8
Figure 8-7 The Pierce crystal oscillator using an FET.

varies the temperature of a heating element in the oven. Stabilities in the 61 3 1028 or
better can be obtained.

Frequency Synthesizers
Frequency synthesizers are variable-frequency generators that provide the frequency sta- Frequency synthesizer
bility of crystal oscillators but with the convenience of incremental tuning over a broad
frequency range. Frequency synthesizers usually provide an output signal that varies in
fixed frequency increments over a wide range. In a transmitter, a frequency synthesizer
provides basic carrier generation for channelized operation. Frequency synthesizers are
also used in receivers as local oscillators and perform the receiver tuning function.
GOOD TO KNOW
Using frequency synthesizers overcomes certain cost and size disadvantages associ- A growing alternative to crystal
ated with crystals. Assume, e.g., that a transmitter must operate on 50 channels. Crystal oscillators are those made with
stability is required. The most direct approach is simply to use one crystal per frequency micro-electro-mechanical sys-
and add a large switch. Although such an arrangement works, it has major disadvantages.
tems (MEMS) technology. The
Crystals are expensive, ranging from $1 to $10 each, and even at the lowest price,
50 crystals may cost more than all the rest of the parts in the transmitter. The same frequency determining element is
50 crystals would also take up a great deal of space, possibly occupying more than a vibrating silicon mechanical
10 times the volume of all the rest of the transmitter parts. With a frequency synthesizer, structure within the electronic
only one crystal is needed, and the requisite number of channels can be generated by silicon oscillator circuit.
using a few tiny ICs.
Over the years, many techniques have been developed for implementing frequency
synthesizers with frequency multipliers and mixers. Today, however, most frequency
synthesizers use some variation of the phase-locked loop (PLL). A newer technique called Phase-locked loop (PLL)
digital signal synthesis (DSS) is becoming more popular as integrated-circuit technology Digital signal synthesis (DSS)
has made high-frequency generation practical.

Phase-Locked Loop Synthesizers Phase-locked loop synthesizer

An elementary frequency synthesizer based on a PLL is shown in Fig. 8-8. Like all phase-
locked loops, it consists of a phase detector, a low-pass filter, and a VCO. The input to
the phase detector is a reference oscillator. The reference oscillator is normally crystal-
controlled to provide high-frequency stability. The frequency of the reference oscillator
sets the increments in which the frequency may be changed. Note that the VCO output
is not connected directly back to the phase detector, but applied to a frequency divider
first. A frequency divider is a circuit whose output frequency is some integer submultiple Frequency divider
of the input frequency. A divide-by-10 frequency synthesizer produces an output frequency

Radio Transmitters 245
 Figure 8-8 Basic PLL frequency synthesizer.

Phase Low-pass Carrier output 
detector filter 1 MHz

⬇
XTAL
oscillator VCO
reference
100 kHz
100 kHz Frequency
divider
( N )
 10

that is one-tenth of the input frequency. Frequency dividers can be easily implemented
with digital circuits to provide any integer value of frequency division.
In the PLL in Fig. 8-8, the reference oscillator is set to 100 kHz (0.1 MHz). Assume
that the frequency divider is initially set for a division of 10. For a PLL to become
locked or synchronized, the second input to the phase detector must be equal in fre-
quency to the reference frequency; for this PLL to be locked, the frequency divider
output must be 100 kHz. The VCO output has to be 10 times higher than this, or 1
MHz. One way to look at this circuit is as a frequency multiplier: The 100-kHz input
is multiplied by 10 to produce the 1-MHz output. In the design of the synthesizer, the
VCO frequency is set to 1 MHz so that when it is divided, it will provide the 100-kHz
input signal required by the phase detector for the locked condition. The synthesizer
output is the output of the VCO. What has been created, then, is a 1-MHz signal source.
Because the PLL is locked to the crystal reference source, the VCO output frequency
has the same stability as that of the crystal oscillator. The PLL will track any frequency
variations, but the crystal is very stable and the VCO output is as stable as that of the
crystal reference oscillator.
To make the frequency synthesizer more useful, some means must be provided to
vary its output frequency. This is done by varying the frequency division ratio. Through
various switching techniques, the flip-flops in a frequency divider can be arranged to
provide any desired frequency division ratio. In the most sophisticated circuits, a micro-
processor generates the correct frequency division ratio based on software inputs.
Varying the frequency division ratio changes the output frequency. For example, in
the circuit in Fig. 8-8, if the frequency division ratio is changed from 10 to 11, the VCO
output frequency must change to 1.1 MHz. The output of the divider then remains at
100 kHz (1,100,000/11 5 100,000), as necessary to maintain a locked condition. Each
incremental change in frequency division ratio produces an output frequency change of
0.1 MHz. This is how the frequency increment is set by the reference oscillator.
A more complex PLL synthesizer, a circuit that generates VHF and UHF frequencies
over the 100- to 500-MHz range, is shown in Fig. 8-9. This circuit uses a FET oscillator
to generate the carrier frequency directly. No frequency multipliers are needed. The output
of the frequency synthesizer can be connected directly to the driver and power amplifiers
in the transmitter. This synthesizer has an output frequency in the 390-MHz range, and the
frequency can be varied in 30-kHz increments above and below that frequency.
The VCO circuit for the synthesizer in Fig. 8-9 is shown in Fig. 8-10. The frequency
of this LC oscillator is set by the values of L1, C1, C2 and the capacitances of the varac-
tor diodes D1 and D2, Ca and Cb, respectively. The dc voltage applied to the varactors
changes the frequency. Two varactors are connected back to back, and thus the total
effective capacitance of the pair is less than either individual capacitance. Specifically,
it is equal to the series capacitance CS, where CS 5 CaCb/(Ca 1 Cb ). If D1 and D2 are
identical, CS 5 Ca/2. A negative voltage with respect to ground is required to reverse-
bias the diodes. Increasing the negative voltage increases the reverse bias and decreases
the capacitance. This, in turn, increases the oscillator frequency.
Using two varactors allows the oscillator to produce higher RF voltages without the
problem of the varactors becoming forward-biased. If a varactor, which is a diode,

246 Chapter 8
Figure 8-9 VHF/UHF frequency synthesizer.
Loop filter
Exclusive OR
phase detector
FET To transmitter
 driver and power
 VCO
Op –DC See Fig. 8-10 amplifiers
amp controller
f0
N ⴝ 203 389.76 MHz
M  64
30 kHz Programmable
frequency  64
fr divider
Prescaler
30 kHz
6.09 MHz
 100

3 MHz
Programming
XTAL inputs
oscillator
reference R  MN

Figure 8-10 VHF/UHF range VCO.

V

RFC RFC D1(Ca)
DC
Control L1
voltage D2(Cb)

C1

C2

RFC

becomes forward-biased, it is no longer a capacitor. High voltages in the tank circuit of
the oscillator can sometimes exceed the bias voltage level and cause forward conduction.
When forward conduction occurs, rectification takes place, producing a dc voltage that
changes the dc tuning voltage from the phase detector and loop filter. The result is called
phase noise. With two capacitors in series, the voltage required to forward-bias the com-
bination is double that of one varactor. An additional benefit is that two varactors in
series produce a more linear variation of capacitance with voltage than one diode. The
dc frequency control voltage is, of course, derived by filtering the phase detector output
with the low-pass loop filter.

Radio Transmitters 247
 In most PLLs, the phase detector is a digital circuit rather than a linear circuit, since
the inputs to the phase detector are usually digital. Remember, one input comes from
the output of the feedback frequency divider chain, which is certainly digital, and the
other comes from the reference oscillator. In some designs, the reference oscillator fre-
quency is also divided down by a digital frequency divider to achieve the desired fre-
quency step increment. This is the case in Fig. 8-9. Since the synthesizer frequency can
be stepped in increments of 30 kHz, the reference input to the phase detector must be
30 kHz. This is derived from a stable 3-MHz crystal oscillator and a frequency divider
of 100.
The design shown in Fig. 8-9 uses an exclusive-OR gate as a phase detector. Recall
that an exclusive-OR (XOR) gate generates a binary 1 output only if the two inputs are
complementary; otherwise, it produces a binary 0 output.
Fig. 8-11 shows how the XOR phase detector works: Remember that the inputs to
a phase detector must have the same frequency. This circuit requires that the inputs have
a 50 percent duty cycle. The phase relationship between the two signals determines the
output of the phase detector. If the two inputs are exactly in phase with each other, the
XOR output will be zero, as Fig. 8-11(b) shows. If the two inputs are 180° out of phase
with each other, the XOR output will be a constant binary 1 [see Fig. 8-11(c)]. Any other
phase relationship will produce output pulses at twice the input frequency. The duty cycle
of these pulses indicates the amount of phase shift. A small phase shift produces narrow
pulses; a larger phase shift produces wider pulses. Fig. 8-11(d) shows a 90° phase shift.
The output pulses are fed to the loop filter (Fig. 8-9), an op amp with a capacitor
in the feedback path that makes it into a low-pass filter. This filter averages the phase
detector pulses into a constant dc voltage that biases the VCO varactors. The average dc
voltage is proportional to the duty cycle, which is the ratio of the binary 1 pulse time to
the period of the signal. Narrow pulses (low duty cycle) produce a low average dc volt-
age, and wide pulses (high duty cycle) produce a high average dc voltage. Fig. 8-11(e)
shows how the average dc voltage varies with phase shift. Most PLLs lock in at a phase
difference of 90°. Then, as the frequency of the VCO changes because of drift or
because of changes in the frequency divider ratio, the input to the phase detector from

Figure 8-11 Operation of XOR phase detector.

A B C
0 0 0
0 1 1
XOR 1 0 1
A C 1 1 0
B Truth table
(a)

1 1
A A
0 0
1 1
B B
0 0
1 1
C
0
C
0
其
In phase Average dc voltage
(b) 90° phase shift
(d )
1
A Voltage at lock
Average dc output

0
1
B
0
1
C
0
180° out of phase
(c) 0° 90° 180° 270° 360°
(e)

248 Chapter 8
the feedback divider changes, varying the duty cycle. This changes the dc voltage from
the loop filter and forces a change of the VCO frequency to compensate for the original
change. Note that the XOR produces a positive dc average voltage, but the op amp used
in the loop filter inverts this to a negative dc voltage, as required by the VCO.
The output frequency of the synthesizer fo and the phase detector reference fre-
quency fr are related to the overall divider ratio R as follows:
fo fo
R5 fo 5 Rfr or fr 5
fr R
In our example, the reference input to the phase detector fr must be 30 kHz to match the
feedback from the VCO output fo. Assume a VCO output frequency of 389.76 MHz. A
frequency divider reduces this amount to 30 kHz. The overall division ratio is
R 5 fo /fr 5 389,760,000/30,000 5 12,992.
In some very high-frequency PLL synthesizers, a special frequency divider called a
prescaler is used between the high-output frequency of the VCO and the programmable Prescaler
part of the divider. The prescaler could be one or more emitter-coupled logic (ECL) flip-
flops or a low-ratio CMOS frequency divider that can operate at frequencies up to 1 to
2 GHz. Refer again to Fig. 8-9. The prescaler divides by a ratio of M 5 64 to reduce
the 389.76-MHz output of the VCO to 6.09 MHz, which is well within the range of most
programmable frequency dividers. Since we need an overall division ratio of R 5 12,992
and a factor of M 5 64 is in the prescaler, the programmable portion of the feedback
divider N can be computed. The total division factor is R 5 MN 5 12,992. Rearranging,
we have N 5 R/M 5 12,992/64 5 203.
Now, to see how the synthesizer changes output frequencies when the division
ratio is changed, assume that the programmable part of the divider is changed by
one increment, to N 5 204. For the PLL to remain in a locked state, the phase
detector input must remain at 30 kHz. This means that the VCO output frequency
must change. The new frequency division ratio is 204 3 64 5 13,056. Multiplying
this by 30 kHz yields the new VCO output frequency fo 5 30,000 3 13,056 5
391,680,000 Hz 5 391.68 MHz. Instead of the desired 30-kHz increment, the VCO out-
put varied by 391,680,000 2 389,760,000 5 1,920,000 Hz, or a step of 1.92 MHz. This
was caused by the prescaler. For a 30-kHz step to be achieved, the feedback divider
should have changed its ratio from 12,992 to 12,993. Since the prescaler is fixed with a
division factor of 64, the smallest increment step is 64 times the reference frequency, or
64 3 30,000 5 1,920,000 Hz. The prescaler solves the problem of having a divider with
a high enough frequency capability to handle the VCO output, but forces the use of
programmable dividers for only a portion of the total divider ratio. Because of the pres-
caler, the divider ratio is not stepped in integer increments but in increments of 64.
Circuit designers can either live with this or find another solution.
One possible solution is to reduce the reference frequency by a factor of 64. In the
example, the reference frequency would become 30 kHz/64 5 468.75 Hz. To achieve
this frequency at the other input of the phase detector, an additional division factor of
64 must be included in the programmable divider, making it N 5 203 3 64 5 12,992.
Assuming the original output frequency of 389.76 MHz, the overall divider ratio is
R 5 MN 5 12,992(64) 5 831,488. This makes the output of the programmable divider
equal to the reference frequency, or fr 5 389,760,000/831,488 5 468.75 Hz.
This solution is logical, but it has several disadvantages. First, it increases cost and
complexity by requiring two more divide-by-64 ICs in the reference and feedback paths.
Second, the lower the operating frequency of the phase detector, the more difficult it is
to filter the output into direct current. Further, the low-frequency response of the filter
slows the process of achieving lock. When a change in the divider ratio is made, the
VCO frequency must change. It takes a finite amount of time for the filter to develop
the necessary value of corrective voltage to shift the VCO frequency. The lower the phase
detector frequency, the greater this lock delay time. It has been determined that the lowest
acceptable frequency is about 1 kHz, and even this is too low in some applications. At
1 kHz, the change in VCO frequency is very slow as the filter capacitor changes its charge

Radio Transmitters 249
 Figure 8-12 Using a variable-modulus prescaler in a PLL frequency divider.

Prescaler
Input from VCO M A
fo M1
Preset
Modulus
control Detect zero Preset A

Down-counters

N
Output fr
(to phase detector)

Preset N

in response to the different duty-cycle pulses of the phase detector. With a 468.75-Hz phase
detector frequency, the loop response becomes even slower. For more rapid frequency
changes, a much higher frequency must be used. For spread spectrum and in some satel-
lite applications, the frequency must change in a few microseconds or less, requiring an
extremely high reference frequency.
To solve this problem, designers of high-frequency PLL synthesizers created special
IC frequency dividers, such as the one diagrammed in Fig. 8-12. This is known as a
Fractional N divider fractional N divider PLL. The VCO output is applied to a special variable-modulus pres-
caler divider. It is made of emitter-coupled logic or CMOS circuits. It is designed to have
two divider ratios, M and M 1 1. Some commonly available ratio pairs are 10/11, 64/65,
and 128/129. Let’s assume the use of a 64/65 counter. The actual divider ratio is deter-
mined by the modulus control input. If this input is binary 0, the prescaler divides by M,
or 64; if this input is binary 1, the prescaler divides by M 1 1, or 65. As Fig. 8-12 shows,
the modulus control receives its input from an output of counter A. Counters A and N are
programmable down-counters used as frequency dividers. The divider ratios are preset into
the counters each time a full divider cycle is achieved. These ratios are such that N. A.
The count input to each counter comes from the output of the variable-modulus prescaler.
A divider cycle begins by presetting the down-counters to A and N and setting the
prescaler to M 1 1 5 65. The input frequency from the VCO is fo. The input to the
down-counters is fo /65. Both counters begin down-counting. Since A is a shorter coun-
ter than N, A will decrement to 0 first. When it does, its detect-0 output goes high,
changing the modulus of the prescaler from 65 to 64. The N counter initially counts
down by a factor of A, but continues to down-count with an input of fo /64. When it
reaches 0, both down-counters are preset again, the dual modulo prescaler is changed
back to a divider ratio of 65, and the cycle starts over.
The total division ratio R of the complete divider in Fig. 8-12 is R 5 MN 1 A. If
M 5 64, N 5 203, and A 5 8, the total divider ratio is R 5 64(203) 1 8 5 12,992 1
8 5 13,000. The output frequency is fo 5 Rfr 5 13,000(30,000) 5 390,000,000 5
390 MHz.
Any divider ratio in the desired range can be obtained by selecting the appropriate
preset values for A and N. Further, this divider steps the divider ratio one integer at a
time so that the step increment in the output frequency is 30 kHz, as desired.
As an example, assume that N is set to 207 and A is set to 51. The total divider
ratio is R 5 MN 1 A 5 64(207) 1 51 5 13,248 1 51 5 13,299. The new output fre-
quency is fo 5 13,299(30,000) 5 398,970,000 5 398.97 MHz.
If the A value is changed by 1, raising it to 52, the new divide ratio is R 5 MN 1 A 5
64(207) 1 52 5 13,248 1 52 5 13,300. The new frequency is fo 5 13,300(3,000) 5
399,000,000 5 399 MHz. Note that with an increment change in A of 1, R changed by

250 Chapter 8
1 and the final output frequency increased by a 30-kHz (0.03-MHz) increment, from
398.97 to 399 MHz.
The preset values for N and A can be supplied by almost any parallel digital source
but are usually supplied by a microprocessor or are stored in a ROM. Although this
type of circuit is complex, it achieves the desired results of stepping the output fre-
quency in increments equal to the reference input to the phase detector and allowing
the reference frequency to remain high so that the change delay in the output frequency
is shorter.

Example 8-3
A frequency synthesizer has a crystal reference oscillator of 10 MHz followed by a
divider with a factor of 100. The variable-modulus prescaler has M 5 31/32. The A
and N down-counters have factors of 63 and 285, respectively. What is the synthesizer
output frequency?
The reference input signal to the phase detector is
10 MHz
5 0.1 MHz 5 100 kHz
100
The total divider factor R is
R 5 MN 1 A 5 32 (285) 1 63 5 9183
The output of this divider must be 100 kHz to match the 100-kHz reference signal to
achieve lock. Therefore, the input to the divider, the output of the VCO, is R times
100 kHz, or
fo 5 9183 (0.1 MHz) 5 918.3 MHz

Example 8-4
Demonstrate that the step change in output frequency for the synthesizer in
Example 8-3 is equal to the phase detector reference range, or 0.1 MHz.
Changing the A factor one increment to 64 and recalculating the output yield
R 5 32(285) 1 64 5 9184
fo 5 9184(0.1 MHz) 5 918.4 MHz
The increment is 918.4 2 918.3 5 0.1 MHz.

Direct Digital Synthesis
A newer form of frequency synthesis is known as direct digital synthesis (DDS). A DDS Direct digital synthesis
synthesizer generates a sine wave output digitally. The output frequency can be varied in
increments depending upon a binary value supplied to the unit by a counter, a register, or
an embedded microcontroller.

Radio Transmitters 251
 The basic concept of the DDS synthesizer is illustrated in Fig. 8-13. A read-only
memory (ROM) is programmed with the binary representation of a sine wave. These are
the values that would be generated by an analog-to-digital (A/D) converter if an analog
sine wave were digitized and stored in the memory. If these binary values are fed to a

Figure 8-13 Basic concept of a DDS frequency source.

ROM
(sine D/A converter LPF
table)

Sine
Address wave
out put
Counter (or
register)
Clock

Figure 8-14 Shifting a sine wave to direct current.

1

0

1

0 90 180 270 360
(0)
(a) Standard sine wave

2

1

0
0 90 180 270 360
(0)
(b) Shifted sine wave

252 Chapter 8
digital-to-analog (D/A) converter, the output of the D/A converter will be a stepped
approximation of the sine wave. A low-pass filter (LPF) is used to remove the high-
frequency content near the clock frequency, thereby smoothing the ac output into a nearly
GOOD TO KNOW
perfect sine wave. High-frequency content near the
To operate this circuit, a binary counter is used to supply the address word to the clock freqency of the D/A con-
ROM. A clock signal steps the counter that supplies a sequentially increasing address to verter must be removed from the
ROM. The binary numbers stored in ROM are applied to the D/A converter, and the
waveform. A low-pass filter is
stepped sine wave is generated. The frequency of the clock determines the frequency of
the sine wave. used to accomplish this, and a
To illustrate this concept, assume a 16-word ROM in which each storage location smooth sine wave results.
has a 4-bit address. The addresses are supplied by a 4-bit binary counter that counts
from 0000 through 1111 and recycles. Stored in ROM are binary numbers represent-
ing values that are the sine of particular angles of the sine wave to be generated. Since
a sine wave is 360° in length, and since the 4-bit counter produces 16 addresses or
increments, the binary values represent the sine values at 360/16 5 22.5° increments.
Assume further that these sine values are represented with 8 bits of precision. The
8-bit binary sine values are fed to the D/A converter, where they are converted to a pro-
portional voltage. If the D/A converter is a simple unit capable of a dc output voltage only,
it cannot produce a negative value of voltage as required by a sine wave. Therefore, we
will add to the sine value stored in ROM an offset value that will produce a sine wave
output, but shifted so that it is all positive. For example, if we wish to produce a sine wave
with a 1-V peak value, the sine wave would vary from 0 to 11, then back to 0, from 0
to 21, and then back to 0, as shown in Fig. 8-14(a). We add a binary 1 to the waveform
so that the output of the D/A converter will appear as shown in Fig. 8-14(b). The D/A
converter output will be 0 at the peak negative value of the sine wave. This value of 1 is
added to each of the sine values stored in ROM. Fig. 8-15 shows the ROM address, the
phase angle, sine value, and the sine value plus 1.
If the counter starts counting at zero, the sine values will be sequentially accessed
from ROM and fed to the D/A converter, which produces a stepped approximation of
the sine wave. The resulting waveform (red) for one complete count of the counter is
shown in Fig. 8-16. If the clock continues to count, the counter will recycle and the sine
wave output cycle will be repeated.
An important point to note is that this frequency synthesizer produces one complete
sine wave cycle for every 16 clock pulses. The reason for this is that we used 16 sine

Figure 8-15 Address and sine values for a 4-bit DDS.

ADDRESS ANGLE (DEGREES) SINE SINE ⴙ 1
0000 90 1 2
0001 112.5 0.924 1.924
0010 135 0.707 1.707
0011 157.5 0.383 1.383
0100 180 0 1
0101 202.5 0.383 0.617
0110 225 0.707 0.293
0111 247.5 0.924 0.076
1000 270 1 0
1001 292.5 0.924 0.076
1010 315 0.707 0.293
1011 337.5 0.383 0.617
1100 360 0 1
1101 22.5 0.383 1.383
1110 45 0.707 1.707
1111 67.5 0.924 1.924
0000 90 1 2

Radio Transmitters 253
Figure 8-16 Output waveforms of a 4-bit DDS.

N1 N2
2.0
1.9
1.8
1.7
1.6
1.5
N4
1.4
1.3
1.2
1.1
1.0
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
90 180 270 360 90
(0)

values to create the one cycle of the sine wave in ROM. To get a more accurate repre-
sentation of the sine wave, we could have used more bits. For example, if we had used
an 8-bit counter with 256 states, the sine values would be spaced every 360/256 5 1.4°,
giving a highly accurate representation of the sine wave. Because of this relationship,
the output frequency of the sine wave f0 5 the clock frequency fclk /2N, where N is equal
to the number of address bits in ROM.
If a clock frequency of 1 MHz were used with our 4-bit counter, the sine wave output
frequency would be
GOOD TO KNOW
f0 5 1,000,000/24 5 1,000,000/16 5 62,500 Hz
The output frequency f0 equals
the clock frequency fclk divided The stepped approximation of the sine wave is then applied to a low-pass filter where
by 2N, where N is the number of the high-frequency components are removed, leaving a low-distortion sine wave.
The only way to change the frequency in this synthesizer is to change the clock fre-
address bits in ROM.
quency. This arrangement does not make much sense in view of the fact that we want our
synthesizer output to have crystal oscillator precision and stability. To achieve this, the clock
oscillator must be crystal-controlled. The question then becomes, How can you modify this
circuit to maintain a constant clock frequency and also change the frequency digitally?
The most commonly used method to vary the synthesizer output frequency is to
replace the counter with a register whose content will be used as the ROM address but
also one that can be readily changed. For example, it could be loaded with an address
from an external microcontroller. However, in most DDS circuits, this register is used in
conjunction with a binary adder, as shown in Fig. 8-17. The output of the address regis-
ter is applied to the adder along with a constant binary input value. This constant value
can also be changed. The output of the adder is fed back into the register. The combina-
Accumulator tion of the register and adder is generally referred to as an accumulator. This circuit is
arranged so that upon the occurrence of each clock pulse, the constant C is added to the
previous value of the register content and the sum is re-stored in the address register. The
constant value comes from the phase increment register, which in turn gets it from an
embedded microcontroller or other source.

254 Chapter 8
Figure 8-17 Complete DDS block diagram.

ROM Sine
(sine D/A converter LPF wave
table) output

Phase increment Address
register (counter) register

Adder

Input from
processor or
other source Constant Clock
value (c)

To show how this circuit works, assume that we are using a 4-bit accumulator register
and the same ROM described previously. Assume also that we will set the constant value
to 1. For this reason, each time a clock pulse occurs, a 1 is added to the content of the
register. With the register initially set to 0000, the first clock pulse will cause the register
to increment to 1. On the next clock pulse the register will increment to 2, and so on. As
a result, this arrangement acts just as the binary counter described earlier.
Now assume that the constant value is 2. This means that for each clock pulse, the
register value will be incremented by 2. Starting at 0000, the register contents would be
0, 2, 4, 6, and so on. Looking at the sine value table in Fig. 8-15, you can see that the
values output to the D/A converter also describe the sine wave, but the sine wave is being
generated at a more rapid rate. Instead of having eight amplitude values represent the
peak-to-peak value of the sine wave, only four values are used. Refer to Fig. 8-16, which
illustrates what the output looks like (blue curve). The output is, of course, a stepped
approximation of a sine wave, but during the complete cycle of the counter from 0000
through 1111, two cycles of the output sine wave occur. The output has fewer steps and
is a cruder representation. With an adequate low-pass filter, the output will be a sine wave
whose frequency is twice that generated by the circuit with a constant input of 1.
The frequency of the sine wave can further be adjusted by changing the constant
value added to the accumulator. Setting the constant to 3 will produce an output frequency
that is three times that produced by the original circuit. A constant value of 4 produces
GOOD TO KNOW
a frequency four times the original frequency. For stepped-up constants added
With this arrangement, we can now express the output sine wave frequency with the to the 4-bit accumulator register,
formula the output can be calculated
Cfclk based on the constant C multi-
f0 5
2N plied by the clock frequency fclk
The higher the constant value C, the fewer the samples used to reconstruct the output divided by 2N, where N is the
sine wave. When the constant is set to 4, every fourth value in Fig. 8-15 will be sent to number of bits in the register.
the D/A converter, generating the dashed waveform in Fig. 8-16. Its frequency is four
times the original. This corresponds to two samples per cycle, which is the least number
that can be used and still generate an accurate output frequency. Recall the Nyquist
criterion, which says that to adequately reproduce a sine wave, it must be sampled a
minimum of two times per cycle to reproduce it accurately in a D/A converter.
To make the DDS effective, then, the total number of sine samples stored in ROM
must be a very large value. Practical circuits use a minimum of 12 address bits, giving
4096 sine samples. Even a larger number of samples can be used.

Radio Transmitters 255
256
Figure 8-18 Analog Devices AD9852 DDS chip.

System clock Inverse Digital multipliers
4X–20X DDS core
Ref sine 12-bit
Reference ref clk Analog
clk I filter cosine DAC
clock in multi- 12 out

MUX
MUX
buffer 48 48 17 17
plier 丢 12
System DAC Rset

Phase
clock

ACC 1
ACC 2
Diff/single MUX

converter

Phase-to-

Chapter 8
48 14

ampuitude

Frequency
select

accumulator
accumulator
12-bit
System Analog
O control
clock out
12 DAC

PSK/BPSK/hold MUX MUX MUX
data in
Delta System Programmable Analog
frequency clock amplitude and in
rate timer rate control
Comparator
System 
48 clock 48 48 14 14 12 Clock
 out
Delta Frequency Frequency First 14-bit phase/ Second 14-bit phase/ AM modulation 12-bit DC
frequency tuning tuning offset word offset word control
word word 1 word 2
Programming registers Shaped
ON/OFF
System System Bus keying
clock CK 2 clock AD9852
O
D GND
Bidirectional Internal I/O port buffers
internal/external programmable
I/O update update clock Vs
clock INT/EXT

Read Write Serial/ 8-bit address 8-bit Master
parallel or serial parallel reset
select programming load
lines
 The DDS synthesizer described earlier offers some advantages over a PLL synthe-
sizer. First, if a sufficient number of bits of resolution in ROM word size and the accu-
mulator size are provided, the frequency can be varied in very fine increments. And
because the clock is crystal-controlled, the resulting sine wave output will have the
accuracy and precision of the crystal clock.
A second benefit is that the frequency of the DDS synthesizer can usually be changed
much faster than that of a PLL synthesizer. Remember that to change the PLL synthesizer
frequency, a new frequency-division factor must be entered into the frequency divider.
Once this is done, it takes a finite amount of time for the feedback loop to detect the
error and settle into the new locked condition. The storage time of the loop low-pass
filter considerably delays the frequency change. This is not a problem in the DDS syn-
thesizer, which can change frequencies within nanoseconds.
A downside of the DDS synthesizer is that it is difficult to make one with very high
output frequencies. The output frequency is limited by the speed of the available D/A
converter and digital logic circuitry. With today’s components, it is possible to produce a
DDS synthesizer with an output frequency as high as 200 MHz. Further developments in
IC technology will increase that in the future. For applications requiring higher frequen-
cies, the PLL is still the best alternative.
DDS synthesizers are available from several IC companies. The entire DDS circuitry is
contained on a chip. The clock circuit is usually contained within the chip, and its frequency
is set by an external crystal. Parallel binary input lines are provided to set the constant value
required to change the frequency. A 12-bit D/A converter is typical. An example of such a
chip is the Analog Devices AD9852, shown in Fig. 8-18. The on-chip clock is derived from
a PLL used as a frequency multiplier that can be set to multiply by any integer value between
4 and 20. With a maximum of 20, a clock frequency of 300 MHz is generated. To achieve
this frequency, the external reference clock input must be 300/20 5 15 MHz. With a
300-MHz clock, the synthesizer can generate sine waves up to 150 MHz.
The outputs come from two 12-bit DACs that produce both the sine and the cosine waves
simultaneously. A 48-bit frequency word is used to step the frequency in 248 increments.
A 17-bit phase accumulator lets you shift the phase in 217 increments.
This chip also has circuitry that lets you modulate the sine wave outputs. AM, FM,
FSK, PM, and BPSK can be implemented. More advanced DDS ICs are available with
DAC resolution to 14-bits and a maximum clock input of 1 GHz.
Keep one important thing in mind. Although there are individual PLL and DDS
synthesizer chips, today these circuits are more likely to be part of a larger system on a
chip (SoC).

Phase Noise
An important specification and characteristic of any signal (carrier) source, crystal oscil-
lator, or frequency synthesizer is phase noise. Phase noise is the minor variation in the
amplitude and phase of the signal generator output. The noise comes from natural semi-
conductor sources, power supply variations, or thermal agitation in the components. The
phase variations manifest themselves as frequency variations. The result is what appears
to be a sine wave signal source that has been amplitude and frequency modulated.
Although these variations are small, they can result in degraded signals in both the
transmitter and the receiver circuits.
For example, in the transmitter, variations in the carrier other than those imposed by
the modulator can produce a “fuzzy” signal that can result in transmission errors. In the
receiver, any added noise can mask and interfere with any small signals being received. A
particularly difficult problem is the multiplication of the phase noise in PLL synthesizers.
A PLL is a natural frequency multiplier that in effect amplifies the phase noise of the input
crystal oscillator. The goal therefore is to minimize phase noise in the carrier signal by
design or through the selection of signal sources with the least phase noise.
When looking at a sine wave carrier on a spectrum analyzer, what you should see
is a single vertical straight line, its amplitude representing the signal power and it

Radio Transmitters 257
Figure 8-19 (a) The ideal carrier plot in the frequency domain. (b) Real-world carrier plot as shown on a spectrum analyzer.
Carrier Carrier

Thermal noise
floor

fc fc
(a) (b)

horizontal position representing the carrier frequency (fc). See Fig. 8-19a. However,
because of signal distortion or noise, what you actually see is the carrier signal accom-
panied by sidebands around the carrier made up of harmonics and phase noise compo-
nents. Fig. 8-19b is an example. Serious harmonic distortion can be filtered out, but the
phase noise cannot.
Notice in Fig. 8-19b that the noise sidebands occur both above and below the carrier
frequency. When measuring phase noise, only the upper sidebands are considered; it is
assumed that, because of the random nature of the noise, both upper and lower sidebands
will be identical. Phase noise is designated as L( f ) and represents the single sideband
power referenced to the carrier. It is calculated and measured as the ratio of the average
noise power (Pn) in a 1 Hz bandwidth at a point offset from the carrier to the carrier
signal power (Pc) expressed in dBc/Hz. The average noise power is referred to as the
spectral power density,
L( f ) 5 Pn /Pc
Fig. 8-20 shows a plot of the phase noise. Note that the noise power is averaged
over a narrow 1-Hz bandwidth. The location of that 1-Hz window is offset from the

Figure 8-20 A single sideband plot of phase noise in L(f) dBc/Hz vs. frequency,
showing the offset and the 1-Hz measurement bandwidth. Not to scale.
Carrier

0

–40
L(f ) – dBc/Hz

1Hz BW

–120

–180
fc Frequency
Offset
(100 KHz)

258 Chapter 8
carrier. The phase noise is measured at different offset values from 1 kHz to 10 MHz or
more, depending on the frequencies involved, the modulation type, and the application.
Close-in phase noise is in the 1-kHz to 10-kHz range, whereas far-out phase noise is
offset by 1 MHz or more.
The range of common phase noise values is −40 dBc/Hz to −170 dB/Hz. The greater
the number, of course, the lower the phase noise. The noise floor is the lowest possible
level and is defined by the thermal power in the circuitry and could be as low as −180
dBc/Hz. In Fig. 8-20 the phase noise is −120 dBc/Hz at 100 kHz.

8-3 Power Amplifiers
The three basic types of power amplifiers used in transmitters are linear, class C, and
switching.
Linear amplifiers provide an output signal that is an identical, enlarged replica of Linear amplifier
the input. Their output is directly proportional to their input, and they therefore faithfully
reproduce an input, but at a higher power level. Most audio amplifiers are linear. Linear
RF amplifiers are used to increase the power level of variable-amplitude RF signals such
as low-level AM or SSB signals. Most modern digital modulation techniques such as
spread spectrum, QAM and orthogonal frequency division muli