Radar Fundamentals PDF

Summary

This document provides an overview of radar fundamentals, including principles, applications, classes, equations, scan patterns, and basics. It covers basic radar operational principles and discusses pulse vs. CW radar systems. The document also details radar applications for civilian and military use, along with various radar classes and functions.

Full Transcript

Radar Fundamentals

Christo Cloete
[email protected]
 Outline
Radar Principles
Radar Applications
Radar Classes
Radar Equations
Radar Scan Patterns
Radar Basics

Page 2
 Basic Radar Operational Principle
Radar - RAdio Detection And Ranging
An electromagnetic wave is transmitted by the radar
Some of the energy is scattered when it hits a distant target
A small portion of the scattered energy, the radar echo, is
collected by the radar antenna

C = 3x108 m/s

Slant Range vs
Ground Range

Page 3
 Pulse vs. CW
Radars with a single antenna can not send and receive
signals at the same time
This limitation can be solved by
Transmitting short pulses and listening
for echoes between pulses

CW radars – Separate transmit and receive antennas
Continuously changing the TX frequency so that the
echoes received are at a different frequency to the
signal being transmitted when they return to the radar
𝑐𝑇∆𝑓
𝑅=
2𝐵
Both methods have strong and weak points
Currently pulsed radars are the most common
Transmitting pulses can result in measurement ambiguities

Page 4
 Pulsed Radar Terminology and Concepts …

PRF = 1/ PRI

Pulse Repetition Interval (PRI)
“Real” pulse
Time between pulses
For Pulse Doppler radar – determine the maximum
unambiguous Doppler velocity of the target
Pulse Repetition Frequency
Inverse of the PRI
Pulse Width (PW or Ʈ)
Duration of pulse (pulse length)
Determines spatial resolution of radar
Page 5
 CW & Pulsed Radars examples
Reutech Radar Systems (RRS)

Page 6
 (Some) Radar Applications
Civilian
Aircraft, Air Traffic Control (ATC) & ground-controlled approach
(bad weather landing)
Radar Altimeter (Air and space craft)
Collision avoidance (aircraft, ships and cars)
Border control (people, land, sea and air vehicles)
Weather radar
Natural resources (Oil and gas exploration)
Geology (Ice cover, deforestation, ground composition)
Satellite & space debris tracking
Space craft docking
Speed trap / ball speeds in sports
Military
Surveillance
Early Warning
Target tracking
Missile Defense (ranging from mortars to ICBMs)
Radar guided missiles
Terrain / ground mapping / surveillance
Terrain following aircraft (fighters and cruise missiles)
Locating land mines

Page 7
Proximity fuses (AAA, mortar, missiles)
 Radar Classes and Functions
Radar classes
Active radar (primary)
- Monostatic
- Bi- or multi-static
Secondary radar
- Erroneously referred to as Identify-Friend-or-Foe (IFF)
Not ADS-B (Automatic Dependent Surveillance – Broadcast)
Passive radar (Passive Coherent Location - PCL)
Typical Functions
Detect and track target
Measure:
- Target range
- Direction to the target
- Radial velocity between the radar and target
- Size and shape of the target (Radar Cross Section - RCS)
Imaging
- SAR & ISAR (Synthetic Aperture Radar & Inverse SAR)
Identification
- Cooperative
Transponder – Secondary Surveillance Radar (SSR)
- Non-Cooperative
Target Recognition (NCTR)
Weapons Control
Page 8
 Primary Surveillance Radar (PSR)

Page 9
 Secondary Surveillance Radar (SSR)

SSR Mode C provides altitude information with a resolution of 100 feet and an accuracy of ±50 feet
Page 10
 Automatic Dependent Surveillance – Broadcast (ADS-B)

Page 11
 Automatic Dependent Surveillance – Contract (ADS-C)
Use SATCOM
ADS-B used primarily in
continental airspace
ADS-C mainly in oceanic
airspace

ARINC = Aeronautical Radio, Incorporated
Page 12 SITA = Societe Internationale de Telecommunications Aeronautiques
 Transponder Multilateration (Mlat)
Transponder-equipped aircraft
SSR & ADS-B
Determine aircraft position
based on the Time Difference
Of Arrival (TDOA)

An active MLAT station will also
interrogate the aircraft in the area.
A Wide Area Multilateration (WAM)
system will have mostly passive
stations with some active stations to
interrogate aircraft

Higher update rate enables more efficient separation
Page 13
 Passive Radar
Passive Coherent Location (PCL) Power Densities [dBW/m2]

Page 14
 Bistatic Radar –Principle

Monostatic range resolution:
𝑐
Δrm =
2𝐵

Bistatic range resolution:
𝑐
Δrb =
2𝐵 cos(β/2)

Page 15
 PCL Systems
Lockheed Martin’s Silent Sentry
Fraunhofer
CORA11
Hensholdt’s Twinvis
PCL-PET
Thalés; Ground Alerter 100
Leonardo’s AULOS

Page 16
 Radar Categories
Surveillance Radar
Imaging radar – Synthetic Aperture Radar (SAR)
Can have a Ground Moving Target Indicator (GMTI) mode
Search Radar
Detects the presence of a target and determines its position (range and
bearing)
Usually observes the target over a period of time
Can designate the target to a
- Target Acquisition Radar (TAR)
- Target Tracking Radar (TTR)
Tracking Radar
Provides the track of a target
Usually receives target designation from another source (e.g. search radar)
- Single Target Track (STT) – Tracks a single target to ID and/or generate a firing solution
- Automatic Detection and Tracking (ADT) – Performed by a surveillance radar or a tracking radar using
Track-While-Scan (TWS) and can track many targets simultaneously
Multi-Function Radar
Performed by an AESA radar to search, detect and track multiple targets simultaneously
Can do weapon control, SAR, Comms, ES and EA are also possible
Deployment
Monostatic: the transmitter and receiver are co-located
Bistatic / Multistatic: the transmit and receive antennas are at different locations

Page 17
 Active Radar Block Diagram
Pseudo-Coherent (Monostatic) Radar

Synchronizer - produce TRIGGER PULSES that start the transmitter,
Page 18 indicator sweep circuits, and ranging circuits
 Active Radar Block Diagram …
Coherent (Monostatic) Radar

Page 19
 Active Radar Block Diagram …
Active Electronic Steered Array (AESA)

Waveform
Generator/Signal
Processor

Data
Processor

Display

Page 20
 Active Radar Attributes

Page 21
 Radar Frequency Trade-offs
Long range detection/acquisition/surveillance is better at lower frequencies
Precision tracking is better at higher frequencies
Antennas are smaller at higher frequencies
Rain has bigger effect at higher frequencies
Clutter is worse at lower frequencies
Jamming potentially more effective at lower frequencies (max bandwidth)

Page 22
 Radar Equation and the Detection Process
PtG2λ2σ
Pr =
(4π)3R4

Swerling Models
Model Decorrelation Geometry
Several independent
1 Scan-to-Scan
reflectors of similar
2 Pulse-to-Pulse intensity

Several independent
3 Scan-to-Scan
reflectors and one
4 Pulse-to-Pulse predominates
Page 23
 Radar Maximum Range
The basic radar equation can also be expressed in Signal-to-Noise ratio (SNR)
𝑃 𝐺 2 𝜆2 𝜎
𝑆𝑁𝑅 =
4𝜋 3 𝑘𝑇𝐵𝐹𝑅4
where
- k is the Boltzmann’s constant, [1.38×10-23 W/(Hz K)] - P is the transmit power [w]
- T is the receiver temperature in K - G is the antenna gain
- B is the radar bandwidth in Hz - λ is the wavelength [m]
- F is the radar receiver noise figure - σ is the Radar Cross Section (RCS) [m2]
Then the basic radar range equation is given as

𝑃 𝐺 2 𝜆2 𝜎
𝑅4 =
4𝜋 3 𝑘𝑇𝐵𝐹 𝑆𝑁𝑅

What’s NOT in this (simplified) Radar Equation
Losses
Time on Target (Power is a function of time)
Signal (Pulse) Integration time or Other Processing Gains
Peak Power or Average Power (Duty Cycle considerations)
Scintillation or Glint
Page 24
 Radar Cross Section (RCS)
Ratio of the power re-radiated (reflected) in a given direction
(𝑃𝑟 ) to the power density impinging on the target (𝑃𝑖 )
𝑃𝑟
𝑅𝐶𝑆 = σ = [𝑚2 ]
𝑃𝑖
Relevant Parameters that influence RCS
Target shape
Target aspect ratio
- Incident & reflected directions
Target size
Target material
Radar RF frequency
RCS = 3Dimensional

Page 25
 Typical RCS Values

Page 26
 Other effects

Page 27
 Clutter

Clutter is anything that is not a target
Rain
Sea surface
Mountains
Trees Note - For SAR these are typically the targets
Buildings
Jamming
Clutter “hides” targets since clutter returns are typically much larger than targets

Page 28
 Sensitivity Time Control (STC)
STC is used to attenuate the very strong signals returned from nearby ground clutter targets
in the first few range gates of a Radar receiver
Without this signal attenuation, the receiver would routinely saturate due to the strong signals

Receiver
Gain

Time

Page 29
 Direction Determination
The angular determination of the target is determined by the directivity of the antenna
By measuring the direction in which the antenna is pointing when the echo is received, both the
azimuth and elevation angles from the radar to the object or target can be determined
The accuracy of angular measurement is determined by the
directivity, which is a function of the size (frequency) of the antenna
The shape of the beam influences the echo signal strength

Page 30
 Dwell Time and Hits per Scan
Dwell Time (TD)
The time that an antenna beam spends on a target is called dwell time TD
The dwell time of a 2D–search radar depends predominantly on the antenna’s horizontally beam
width ΘAZ and the turn speed n of the antenna (rotations per minute)

Hits per Scan`(m)
The hit number stands (e.g. for a search radar with a rotating antenna) for the number of the received
echo pulses of a single target per antenna turn. The dwell time TD and the Pulse Repetition Time
PRT determine the value of hits per scan

Page 31
 Radar Antenna Beams

(Cosec2)

Monopulse

Page 32
 Search Scan Patterns
Circular Scan
Sector Scan
Helical Scan
Spiral Scan

Page 33
 Multi-Function Scan/Track/Control

Page 34
 Target Tracking
A target that is tracked is said to be “locked on”
Key data to maintain on locked targets is
Range
Azimuth and elevation angle
Radial velocity (Doppler radars)
Angle tracking techniques are
Sequential lobing
Conical scan
Monopulse
Beam steering
Range Tracking
Early/Late Gate
Complete Range Line

Page 35
 Target Tracking …
Angle tracking
Sequential lobing

Page 36
 Target Tracking …
Angle tracking
Conical scan

Page 37
 Target Tracking …
Angle tracking
Monopulse

Page 38
 Airborne Radar Modes
Air-to-Air Search
Air-to-Air Tracking (Single Target Tracking – STT)
Air-to-Air Track-While-Scan

Raster Scan

Page 39
 Airborne Radar Modes
Ground Mapping
Continuous Wave Illumination
Multimode

Page 40
 Search Radar Coverage
Two-dimensional radar often use an antenna with a cosecant square pattern
Most radars are not designed to detect aircraft directly above the radar antenna. This gap is known
as the cone of silence. This gap or cone of silence is the inverted cone mapped out by the rotating
antenna as a result of the antenna back angle being less than 90 degrees
Aircraft flying in a radar's cone of silence may, however, be detected by another, or several other
radar sites a hundred or so miles away due to their overlapping coverage

Page 41
 Radar Operator Displays

PPI = Plan Position Indicator

Page 42
 Radar Operator Displays …
Weather Radar Displays
Reflectivity image
Velocity image

Page 43
 Radar Resolution Cell
The radar’s pulse width, horizontal beam and vertical beam width form a 3D Resolution Cell (RC)
The horizontal and vertical dimensions of the RC vary with range
𝑐 𝑃𝑊
The RC is the smallest volume of airspace Range resolution is given as Δ𝑅 =
in which a radar cannot distinguish the 2
presence of more than one target Function of Pulse Compression
Angular resolution is function of Antenna
Beamwidth

Page 44
 Range Resolution
The range resolution of a radar is its ability to distinguish between targets that are very close in range
Pulses must be shorter than the time it takes for the signal to travel between targets
- Otherwise, the returned pulses overlap in the receiver and the radar cannot distinguish between them
Weapons-control radars should be able to distinguish between targets that are only meters apart
Search radars are usually less precise and only distinguishes between targets that are hundreds of
meters or even kilometers apart

Page 45
 Radar Unambiguous Range
Maximum range at which a target can be unambiguously detected
Leading edge of the backscattered pulse must be received before the transmission of the next pulse begins
Maximum unambiguous range is related to the PRI of the radar as

Cannot send out
𝑐 (𝑃𝑅𝐼 − 𝑃𝑊) another pulse until
𝑅𝑢𝑎𝑚𝑏 = total time window
2 (range) has passed, in
which it is expected to
see a return echo
Staggered PRI may be used to solve the unambiguity
PRI changes in a controlled way
The ambiguous target does not have stable range over multiple staggered PRIs

Page 46
 Pulse Compression
What is Pulse Compression
Method to increase range resolution and signal-to-noise ratio (SNR) of radar measurements simultaneously
Basis of operation:
- Transmit (long) coded pulse – more energy on the target
- Compress return through matched filtering
Why
Maximum detection range
- Radar detection range is dependant on the amount of energy on target
High range resolution
- Accurate target position
- Target separation for multiple targets
- Clutter reduction
Robustness against various forms of jamming
Radar Equation, SNR
SNR depends on energy = PTx τ Psignal PTxGTx GRx 2
- Increase peak power PTx =
Expensive, makes radar more detectable Pnoise (4 )3 R 4 kTs
- Increase pulse duration τ?
Two broad classes of pulse compression codes
Phase coded
Frequency Modulated

Page 47
 Doppler
Relative movement with a radial component
between a transmitter source and a receiver will
cause an apparent shift in frequency
This apparent change in frequency is called the
Doppler Frequency
Where
ft = Transmit frequency
vr = radial velocity

When not directly radial

Pulse Doppler (PD Radar combines the
advantages of both pulse and Doppler
radar systems ( Range, Azimuth, Elevation
and radial Velocity )
Page 48
 Doppler Ambiguity
The frequency spectrum of the transmitted pulsed signal is a comb-shaped line spectrum
The line spacing of the spectrum is equal to the PRF or fPRF
The received frequency spectrum (subject to the Doppler Effect) can only be used for unambiguous
velocity measurements when the displacement of the received spectrum is smaller than the line
spacing in the spectrum
i.e. the Doppler frequency must be lower than the PRF
Unambiguous velocity
or the PRF must be higher than transmitted frequency

Page 49
 Range/Doppler Maps

Page 50
 PRF and Range & Doppler Ambiguity
PRF Categories depends on the operational situation
Low PRF is one for which the maximum required operational range falls within the first range zone –
unambiguous in range
High PRF is one for which all significant targets are unambiguous in velocity
Medium PRF is one for which both range and Doppler frequency are ambiguous

Example

Typical PRFs
Low PRF < 3 kHz
Medium PRF = 3 kHz to 30 kHz
High PRF > 30 kHz

Page 51
 Duty Cycle
Ratio of the PW and the PRI
𝜏 𝑃𝑊
𝐷𝑢𝑡𝑦𝐶𝑦𝑐𝑙𝑒 = = = 𝑃𝑊 𝑃𝑅𝐹
𝑃𝑅𝐼 𝑃𝑅𝐼
The following equations are also widely used
𝑃𝑎𝑣𝑔
𝐷𝑢𝑡𝑦𝐶𝑦𝑐𝑙𝑒 =
𝑃𝑝𝑒𝑎𝑘
𝑃𝑊
𝑃𝑎𝑣𝑔 = 𝑃𝑝𝑒𝑎𝑘 𝐷𝑢𝑡𝑦𝐶𝑦𝑐𝑙𝑒 = 𝑃𝑝𝑒𝑎𝑘
𝑃𝑅𝐼
Duty Cycle of a CW radar = 100%

Page 52
 Detection
False Alarm
Erroneous radar target detection decision caused by
noise or other interfering signals exceeding the
detection threshold
False Alarm Rate (FAR)
𝐹𝑎𝑙𝑠𝑒 𝑡𝑎𝑟𝑔𝑒𝑡𝑠 𝑝𝑒𝑟 𝑃𝑅𝑇
𝐹𝐴𝑅 =
𝑁𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝑟𝑎𝑛𝑔𝑒 𝑐𝑒𝑙𝑙𝑠
Target detection - Compares the signal to a threshold
Threshold - function of probability of detection and
probability of false alarm
Constant false-alarm rate (CFAR) schemes vary
the detection threshold as a function of the sensed
environment
Detection is needed for a given cell (Cell Under test - CUT)
Noise power is estimated from neighbouring cells
Detection threshold, T, is given by T=αPn
- where Pn is the noise power estimate
- α is a scaling factor called the threshold factor
With the appropriate threshold factor, α, the resulting probability of false alarm can be kept at a constant, hence
the name CFAR

Page 53
 Detection
CFAR can be
Range Acting
Doppler Acting
Range & Doppler acting
Different type of CFAR
Cell-Averaging CFAR (CA-CFAR)
Greatest-Of CFAR (GO-CFAR)
Order Statistics (OS-CFAR)
Cell-Averaging Greatest-Of (CAGO-CFAR)
Least-Of CFAR (LO-CFAR)
Cell-Averaging Smallest Of (CASO-CFAR)
Cell Averaging CFAR
Most widely used CFAR detector
Noise samples are extracted from both leading and lagging cells (called
training cells) around the CUT. The noise estimate can be computed as

N is the number of training cells and xm is the sample in each training cell

Page 54
 Radar Classification by Waveform

(Coherent)

Pulse Doppler

Page 55
 Any Easy Questions?

Page 56
 Assignment

Page 57