Introduction to RF & Wireless - Part 2

Introduction to RF & Wireless

Two Day Seminar

Module 2

Course Agenda
Day One
• Morning (Module 1)
– Introduction to RF
• Afternoon (Module 2)
– RF hardware

Day Two
• Morning (Module 3)
– Older systems & mobile telephony
• Afternoon (Module 4)
– Newer systems & the future

Module 2 - RF Hardware

1. Basic Building Blocks

2. Other Components

3. Circuits

Transmitter/Receiver Preview
Antennas
Amplifiers
Filters
Mixers
Sources
Transmitter/Receiver Review

Transmitters & Receivers
Recall

Basics Building Blocks - Transmitter/Receiver P

Antennas

Basic Building Blocks - Antennas

Antennas
Function
♦ Turn current on a wire into airborne waves
♦ Vice versa
• Most antennas work in both directions


Antennas
What
♦ Act as impedance matching circuits
• From conductor (50 ohms) to free space (377 ohms)

Antenna

Free space Conductor
377 ohms 50 ohms

Antennas
How
♦ Conductors that are about ½ wavelength long
begin to radiate RF energy as waves

½ Wavelength

Wavelength (meters) Application
Wavelengths 5,000,000 Electrical wall outlet

152,500 The human voice

566 AM radio

5 VHF television

3 FM radio

0.3 Cellular phones

0.1 PCS phones

0.02 DirectTV™

Antennas
Characteristics
♦ Active: Requires a power supply
♦ Passive: Does not require a power supply
♦ Directional: Sends RF energy in one direction
♦ Omnidirctional: Sends RF energy in all directions
♦ Size: Depends on the wavelength
♦ Shape: Depends on the direction of the RF energy


Antenna Pattern
What Is It?
♦ An engineering tool that shows a birds-eye view of
the RF energy radiating out of an antenna


Antenna Pattern
Omnidirectional


Antenna Pattern
Directional

Beamwidth

20°

Azimuth


Gain
Two Kinds
♦ Power gain
• Comes from an amplifier
• Increases the power
♦ Antenna gain
• Directional gain
• No increase in power


Isotropic Antenna
What Is It?
♦ A mythical "point" antenna
• Antenna pattern is a sphere
• Minimum power density


Directional Antenna
Visual Depiction
♦ Higher power density
than isotropic


Antenna Gain
Directional Gain
♦ A gain in power density NOT power
• Relative to an isotropic antenna
♦ Measured in dBi
Definition
♦ dBi = "dB greater than isotropic"


Antenna Gain
For Example
An directional antenna with 10 dBi of antenna gain
produces an RF signal with TEN TIMES the power
density compared to an isotropic antenna


Antenna Gain

10 dBi
Output power = 30 dBm

Input power = 30 dBm Effective Isotropic Radiated Power
= 30 dBm + 10 dBi = 40 dBm


Output power
40 dBm

Free space loss 120 dB
-80 dBm
Absorption 10 dB
-90 dBm
S/N 30 dB
Noise floor -120 dBm

Effective isotropic
radiated power 40 dBm

-80 dBm
Absorption 10 dB
-90 dBm
S/N 30 dB

Effective isotropic
radiated power 40 dBm

-80 dBm
Absorption 10 dB Ant gain

S/N 40 dB

Antenna Gain

30 dBm Antenna FSL Absorb Antenna -80 dBm
10 dBi -120 dB -10 dB 10 dBi

S/N 40 dB



Antenna Gain
Even Omnidirectionals Have Gain
♦ 2 - 3 dBi


Antenna Types
Omnidirectional
♦ Dipole: ½ wavelength long
♦ Monopole: ¼ wavelength long
Directional
♦ Dish
♦ Horn
♦ Patch
♦ Array

Polarization
What Is It?
♦ The RF (sine) waves which emanate from an
antenna have an orientation to them
• Horizontal
• Vertical

Polarization
Horizontal Vertical


Polarization
So What
♦ Otherwise identical RF signals can be made
distinct by having different polarizations
• Better use of scarce bandwidth
• Polarization diversity


Smart Antennas
What Are They?
♦ Directional antennas in which the antenna beam moves


Smart Antennas
How?
♦ Switched beam
♦ Electronically scanned
Why?
♦ More users per area
♦ Spatial division multiple access


Amplifiers

Basic Building Blocks - Amplifiers

Amplifiers
Function
♦ Increase the power of RF signals
• "Power gain"


Amplifiers
Main Types
♦ Low noise amplifier (LNA)
• First one in a receiver
♦ High power amplifier (HPA)
• Last one in a transmitter
♦ Other
• Many different kinds
• "Gain blocks"


Amplifiers
HPA LNA

Other

Amplifier Properties
LNA HPA
♦ Gain ♦ Gain
♦ Linearity ♦ Linearity
♦ Noise figure ♦ Output power


Gain
Power Gain (Gp)
♦ Measured in dB

30 dB

-90 dBm

-60 dBm

Linearity
Transfer Curve One dB compression point

Linearity
Another Measure
♦ Third order intercept (Ip3)
♦ Intercept point
• Measured in dB


Output Power
Dictates Amplifier Performance
♦ Suppose Psat = 40 dBm

HPA

30 dB

20 dBm

50 dBm

Output Power

30 dB

20 dBm

50 dBm

Output Power

30 dB

20 dBm

40 dBm

Output Power

30 dB
20 dB
20 dBm

40 dBm

Noise Figure
Definition
♦ How much an amplifier decreases the S/N ratio
• Measured in dB

LNA
S/N 40 dB S/N 37 dB
NF=3dB


A Special Amplifier
Variable Gain Amplifier (VGA)
♦ Gain can be made to vary

15 dB


A Special Amplifier
Variable Gain Amplifier (VGA)
♦ Gain can be made to vary

30 dB


Filters

Basic Building Blocks - Filters

Filters
Function
♦ Eliminate signals at unwanted frequencies


Filters
Block Diagrams


Filters
Frequency Response
♦ Used to describe a filter's behavior
♦ A graph of attenuation vs frequency

Filters
Types
♦ Low pass
• Only signals below a certain frequency can pass
♦ High pass
• Only signals above a certain frequency can pass
♦ Band pass
• Only signals between two frequencies can pass
♦ Band reject ("Notch")
• Only signals outside two frequencies can pass

Low Pass Filter
Ideal Frequency Response

Stop band

Pass band

Low Pass Filter
Real Frequency Response

Stop band

Pass band

Low Pass Filter
Real Frequency Response

Ideal Out of band signals
pass
band

High Pass Filter
Frequency Response

Band Pass Filter
Frequency Response

Band Reject Filter
Frequency Response

Special Filters
Duplexer ("Diplexer")
♦ Two band pass filters in one package

Special Filters
Duplexer Frequency Response

Special Filters
SAW (Surface Acoustic Wave)
♦ Converts RF signals into sound signals
♦ Used for low frequency applications
• Typically less than 3 GHz
♦ Very small and low cost
• Ideal for use in cell phones


Special Filters
Superconducting Filters
♦ Have zero insertion loss in the pass band
♦ Have a near-vertical frequency response
♦ Require cooling units
• Used primarily in cellular base station receivers


Filters
Interesting Things To Know
♦ All devices have a 1 dB compression point
-even passive ones like filters
• A function of input power
♦ IL of a passive device is its noise figure

Basics Building Blocks - Filters

Mixers

Basics Building Blocks - Mixers

Mixers
Function
♦ To change the frequency of the RF signal


Mixers
How
♦ Mixers have two inputs and one output called ports

Input 1 Output

Input 2


Mixers
How
♦ One RF signal goes into Input 1
♦ One RF signal goes into Input 2
♦ TWO RF signals come out of the Output


Mixers
How
♦ Output signal 1
• Frequency = sum of frequencies of input signals
♦ Output signal 2
• Frequency = difference of frequencies of input signals


Mixers
Example
One input signal to a mixer has a frequency of 400 MHz
while the other has a frequency of 500 MHz. What is
the frequency of the two output signals?

Frequency (signal 1) = 400 MHz + 500 MHz = 900 MHz

Frequency (signal 2) = 500 MHz - 400 MHz = 100 MHz


Mixers
Example 100 MHz

500 MHz

900 MHz

400 MHz

Mixers
What
♦ Mixers can be used to raise OR lower the
frequency of an RF signal
• Raise: upconverter and it's in a transmitter
• Lower: downconverter and it's in a receiver
♦ Only one output signal is used
♦ The other is eliminated with a filter


Mixers
Characteristics
♦ Noise figure
♦ Insertion loss called conversion loss (CL)
♦ One dB compression point
♦ Ports have designations


Mixers
Port Designations

RF IF

LO


Mixers
Port Designations
♦ LO is always one of the inputs
• LO: Local Oscillator
♦ RF/IF can be input or output
• IF: Intermediate Frequency
• Upconverter (transmitter): RF is output
• Downconverter (receiver): RF is input


Mixers
How They're Actually Used
♦ Upconverters/Downconverters
• Change the frequency
♦ Phase modulators/demodulators
• Impart or detect a phase shift


Mixers
Downconverter
♦ Superheterodyne

From Antenna To Demod

RF Signal
Baseband Signal
900 MHz
IF Signal 64 KHz
70 MHz


Sources

Basics Building Blocks - Sources

Sources
Function
♦ To generate a perfect sine wave at a specified
frequency
• It is the "source" of the RF
• It is also called an oscillator
• It feeds the LO port of a mixer

Sources
How
♦ Many materials produce a sine wave when
excited with electrical energy
What
♦ The objective is to produce the most perfect
sine wave possible


Sources
Examples
Acronym Oscillator

DRO Dielectric resonator

XO Crystal

YIG Yttrium Iron Garnet


Special Sources
Voltage Controlled Oscillator (VCO)
♦ The frequency of the sine wave can be made to
vary by means of an external control
Sine wave out

Control voltage in


Special Sources
Synthesizer
♦ "Sophisticated" oscillator

Frequency selector

Recap
Antenna Airborne waves to current

Amplifer Makes signals bigger

Filter Elliminates unwanted frequencies

Mixer Changes a signal’s frequency

Source Produces a perfect sine wave

Transmitter Block Diagram
64 Kbps

64 KHz

70 MHz

900 MHz

900 MHz

Receiver Block Diagram
Signals

900 MHz

70 MHz

64 KHz


64 KHz

64 Kbps

Basic Building Blocks
The end

2. Other Components
Switches
Attenuators
Dividers/Combiners
Couplers
Circulators/Isolators
Transformers
Detectors
Phase Shifters/Detectors

Switches
Function
♦ Switch an RF signal's path

Other Components - Switches

Switches
Function
♦ Change an RF signal's path


Switches
Where
Cell phone


Switch Types
Switch Type Characterstics

Solid state Fast
Small
Inexpensive

Electromechanical Big
Slow
Low insertion loss


Insertion Loss vs Isolation
Insertion Loss
♦ Loss in the closed path

Insertion loss ≈ 1 dB


Insertion Loss vs Isolation
Isolation
♦ Loss in the open path

Isolation ≈ 30 dB


Attenuators
Function
♦ To make an RF signal smaller
Heat

Other Components - Attenuators

Attenuators
Block Diagrams


Attenuator Types
Attenuator Type Characterstics

Fixed Insertion loss has a
single value

Voltage Variable Insertion loss can take any
value over a range

Digital Insertion loss can only take
certain values over a range


Digital Attenuator


Recall
Saturated Power

30 dB

20 dBm

50 dBm

Attenuators
Where
♦ To prevent saturation


Dividers
Function
♦ Break up an RF signal into 2 or more signals

Other Components - Dividers

Dividers
Function

? dBm

1 dB
30 dBm

? dBm

Dividers
Function

26 dBm

1 dB
30 dBm

26 dBm

Combiners
Function
♦ Combine 2 or more RF signals into one

Other Components - Combiners

Couplers
Coupler Types Also Called

Directional coupler Coupler

Bi-directional coupler Dual directional coupler

Quad coupler Quadrature coupler
Quadrature (Quad) hybrid
Hybrid
Lange coupler

Directional Couplers
Function
♦ To "sample" an RF signal

Other Components - Couplers

Bi-Directional Couplers
Function
♦ To sample reflected power also

Quad Couplers
Function
♦ Splits a signal into 2 with a phase shift

90°


Quad Couplers
Where
♦ Balanced amplifier


Circulators
Function
♦ Reroutes RF signals

Other Components - Circulators

Circulators
Where
Cell phone

Other Components - Circulators

Isolators
Function
♦ To protect something from reflected power

Load

Other Components - Isolators

Isolators
Where

Base station
Load

Other Components - Isolators

Transformers
Function
♦ Impedance matching, coupling, and others

RF in RF out

Other Components - Transformers

Impedance matching circuit

75 ohms 50 ohms

Other Components - Transformers

Detectors
Function
♦ To convert RF power to voltage
RF in Voltage out

Other Components - Detectors

Phase Shifters
Function
♦ To phase shift the output relative to the input

Phase shifted
Input signal
Φ output signal

Other Components - Phase Shifters

BPSK


Phase Shifters
Where
♦ In modulators

Φ
180°


Phase Detectors
Function
♦ To convert a phase difference to a voltage
Where
♦ In demodulators

RF Input 1 Phase
Voltage Output
RF Input 2 Detector

Other Components - Phase Detectors

Recap
Switch Change an RF signals’ path

Antennuator Makes signals smaller

Divider/ Splits a signal evenly
Combiner

Coupler Samples a signal

Quad Coupler Splits a signal with phase shift

Recap
Circulator/ Reroutes a signal
Isolator

Transformer Impedance matching, coupling, etc

Detector Converts an RF signal to a voltage

Phase Shifter Imparts a phase shift on a signal Φ

Phase Converts a phase diff to a voltage Phase
Detector
Detector

3. Circuits
Semiconductors

Circuit Technologies

Interconnection

Semiconductor Materials
Material Comments

Silicon Low cost
(Si) Low frequency

Gallium Aresenide Higher cost
(GaAs) Higher frequency

Silicon Germanium Low cost
(SiGe) High effeciency

Indium Phosphide Highest cost
(InP) Highest frequency

Circuits - Seminconductors

Semiconductor Building Blocks
Component Usage

Diode Switches, Attenuators
Mixers, Detectors

Transistor Amplifers, Switches
Oscillators, Mixers

Integrated Circuit Combine multiple
components

Diodes
Main Structures
♦ PIN
• Power
♦ Schottky
• Speed


Diodes


Transistors
Main Structures
♦ Bipolar Junction (BJT)
• Low frequency
• High power

♦ Field Effect (FET)
• High frequency
• Low noise


Bipolar Junction Transistors
Materials
♦ Silicon
• "Bipolar"
♦ Gallium Arsenide
• Heterojunction Bipolar Transistor (HBT)


Field Effect Transistors
Materials
♦ Silicon
• MOSFET
• LDMOS
♦ Gallium Arsenide
• MESFET
• HEMT
• PHEMT


Transistors


Integrated Circuits
MMIC
♦ Microwave Monolithic Integrated Circuit
• Si, SiGe or GaAs
• Transistors + other components
– Amplifiers
– Switches
– Digital attenuators
– Mixers


Integrated Circuits


Recap
Materials
♦ Silicon - Low frequency
♦ Gallium Arsenide - Higher frequency
♦ Silicon Germanium - High efficiency
♦ Indium Phosphide - Highest frequency
Building Blocks
♦ Diodes - PIN, Schottky
♦ Transistors - BJT, FET
♦ Integrated circuits - Combination

Circuit Designs
Two Types
♦ Lumped element
♦ Distributed
Dictated By
♦ Frequency

Circuits - Circuit Technologies

Circuit Designs
Lumped Element
♦ Uses discrete ("real")
passive components
• Inductors
• Capacitors
• Couplers
• Transformers


Circuit Designs
Distributed
♦ Uses metal traces as
passive components
• Inductors
• Capacitors
• Couplers
• Transformers


Circuit Construction
Four Ways
♦ Discrete
♦ Hybrid
♦ MMIC
♦ Cavity
Dictated By
♦ Cost
♦ Size
♦ Performance

Discrete
♦ Packaged semiconductors
♦ Lumped passives
♦ Printed circuit board


Hybrid
♦ Packaged or bare
chip semiconductors
♦ Lumped or
distributed passives
♦ Ceramic substrate


MMIC
♦ Semiconductors
devices
♦ Distributed passives
♦ On a single piece of
semiconductor



Cavity
♦ A hollow container
♦ Signals move as waves
inside
♦ Used for high power


Recap
Circuit Design
♦ Lumped - Low frequency
♦ Distributed - High frequency
♦ Discrete - High power, quick design time
♦ Hybrid - High frequency, best performance
♦ MMIC - Small size, high volume
♦ Cavity - Very high power


Interconnection

Transmission lines

Interconnection
Transmission Lines
♦ Should be 50 ohms (i.e. good match)
♦ Have insertion loss
♦ Effect system performance
♦ Can be made several different ways

Circuits - Interconnection

Transmission Lines
Can Be Made Using
1) Cables - box to box
2) Waveguides - high power box to box
3) Metal traces - low power, inside a box


Cables
Coaxial Cables
Insulator
Inner conductor

Outer shield


Cable Assemblies
Consist Of
♦ Coaxial cable
♦ Connectors


Cables
Connectors
♦ Many families
• Price
• Performance
• Evolution
♦ Many types
• Usage
dependent


Cables
How To Interconnect Different Families
♦ Adapters


Waveguides
What
♦ Rectangular metal
tubing
How
♦ Signals travel as
waves
Why
♦ Zero insertion loss

Traces
Where
♦ On printed circuit boards


Traces
Where
♦ In hybrids


Traces
Where
♦ As part of MMICs


Traces
Construction
♦ Stripline
♦ Microstrip
♦ Coplanar waveguide Metal

Substrate

Recap
Transmission Lines

♦ Coaxial cables

♦ Waveguide

♦ Traces


Module 2 -RF Hardware
The end

Dinner

Introduction to RF & Wireless - Part 2

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