MIT Lincoln Laboratory Ind. Day 3/10/2010 1 For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved.

Slides:

Advertisements

Similar presentations

The HPEC Challenge Benchmark Suite

Advertisements

Remote Sensing andGIS.

Presented By: Usama Ashraf ID: Terminal Doppler Weather Radar (TDWR): TDWR is a doppler weather radar system used primarily for the detection.

7. Radar Meteorology References Battan (1973) Atlas (1989)

Analyse de spectres Doppler de la surface de la mer en bande L G. Soriano*, M. Joelson**, P. Forget #, M. Saillard # * Institut Fresnel, UMR CNRS-Université.

ATS 351 Lecture 9 Radar. Radio Waves Electromagnetic Waves Consist of an electric field and a magnetic field Polarization: describes the orientation.

OBSERVATIONAL VALIDATION OF AVIAN RADAR SYSTEMS Wendell Bunch Edwin Herricks, PhD.

1 Technology Service Corporation / California Operations FOR OFFICIAL USE ONLY Ground Moving Target Indicator (GMTI) Radar Discrimination of Combatants.

© 2010 SRC FOR OFFICIAL USE ONLY. Distribution limited to Department of Defense (DoD) and DoD Contractors ONLY. Exempt from Mandatory Disclosure under.

Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.

Radar Many in a series of McGourty- Rideout Productions.

COPS-GOP-WS3 Hohenheim 2006_04_10 Micro- Rain- Radar Local Area Weather Radar Cloud Radar Meteorological Institute University Hamburg Gerhard Peters.

RHB C-band radar scan strategy constraints Cloud top height less than 1.5 km altitude Features of interest < 5 km in scale Rapid evolution of cells  fast.

Radar Remote Sensing Laboratory University of Washington Melissa Meyer, Andrew Morabito, Zac Berkowitz, John Sahr University of Washington Electrical Engineering.

Radar: Acronym for Radio Detection and Ranging

Use of FOS for Airborne Radar Target Detection of other Aircraft Example PDS Presentation for EEE 455 / 457 Preliminary Design Specification Presentation.

Doppler Radar From Josh Wurman Radar Meteorology M. D. Eastin.

Basic RADAR Principles Prof. Sandra Cruz-Pol, Ph.D. Electrical and Computer Engineering UPRM.

Radar 101 Rick Reaser May 19, 2010.

Ship-Based Observations of Ocean Waves Using Multiple X-Band Radars Christa McKelvey, Shanka Wijesundara, Andrew O’Brien, Graeme Smith, Joel T. Johnson,

ElectroScience Lab IGARSS 2011 Vancouver Jul 26th, 2011 Chun-Sik Chae and Joel T. Johnson ElectroScience Laboratory Department of Electrical and Computer.

slide 1 German Aerospace CenterMicrowaves and Radar Institute Extraction of clear-air wind Dr. Thomas Börner DLR Oberpfaffenhofen.

Radar equation review 1/19/10. Radar eq (Rayleigh scatter) The only variable is h, the pulse length Most radars have a range of h values. Rewrite the.

R ADAR By: Abdullah Khan(09ES18). W HAT IS R ADAR ? RADAR (Radio Detection And Ranging) is a way to detect and study far off targets by transmitting a.

1 Technology Service Corporation / California Operations FOR OFFICIAL USE ONLY Ground Moving Target Indicator (GMTI) Radar Discrimination of Combatants.

Presented by: (U) I2WD support of FOPEN-GXP Peter Lamanna UNCLASSIFIED//FOR OFFICIAL USE ONLY.

© 2009 SRC FOR OFFICIAL USE ONLY. Distribution limited to Department of Defense (DoD) and DoD Contractors ONLY. Exempt from Mandatory Disclosure under.

Dr A VENGADARAJAN, Sc ‘F’, LRDE

A Doppler Radar Emulator and its Application to the Detection of Tornadic Signatures Ryan M. May.

FOPEN-GXP Program Overview Vincent Sabio Program Manager

10. Satellite Communication & Radar Sensors

Study Design and Summary Atmospheric boundary layer (ABL) observations were conducted in Sapporo, Japan from April 2005 to July Three-dimensional.

Airborne RLAN and Weather Radar Interference Studies at C Band Paul Joe 1, Frank Whetten 2, John Scott 1 and Dennis Whetten 2 1 Environment Canada 2 The.

Radar Pulse Compression Using the NVIDIA CUDA SDK

© 2010 SRC FOR OFFICIAL USE ONLY. Distribution limited to Department of Defense (DoD) and DoD Contractors ONLY. Exempt from Mandatory Disclosure under.

TODWL and other Navy airborne wind lidar plans including nocturnal flight plan in November G. D. Emmitt SWA Working Group meeting Snowmass, CO 18 July,

Kinematics in Two Dimensions

EumetCal Examples.

Chapter-3 Falling Objects and Projectile Motion Outline: Acceleration due to gravity Falling object Projectile motion Overview: Explore how objects move.

Microwave Motion Sensor Modules (DNS-000 Series) ■ Features - X-Band Microwave Motion Sensor Module - * Used a RF the Microwave Sensor. * The up-to-date.

Ionospheric HF radars Pasha Ponomarenko. Outline Conventional radars vs ionospheric radars Collective scatter processes Aspect angle effects HF propagation.

PTCN-HPEC-02-1 AIR 25Sept02 MIT Lincoln Laboratory Resource Management for Digital Signal Processing via Distributed Parallel Computing Albert I. Reuther.

The objective of Nonlinear Equalization (NLEQ) is to extend the dynamic range of RF receivers by reducing in-band nonlinear distortions. This enables detection.

1 A conical scan type spaceborne precipitation radar K. Okamoto 1),S. Shige 2), T. Manabe 3) 1: Tottori University of Environmental Studies, 2: Kyoto University.

Chapter-3 Falling Objects and Projectile Motion. Overview Explore how objects move under the influence of gravity close to the surface of the earth.

BENT 4343 RADIO NAVIGATION SYSTEM Dr. Ho Yih Hwa Room: A3/37 Tel:

EEE381B Pulsed radar A pulsed radar is characterized by a high power transmitter that generates an endless sequence of pulses. The rate at which the pulses.

Camp Sentinel II Radar System [4] -Installed outside US Army Camp in Vietnam in Antenna Dimensions: 3.5 m diameter x 1 m tall antenna. -2 kW.

Chirped Amplitude Modulation Ladar for Range and Doppler Measurements and 3-D Imaging Barry Stann, Brian Redman, William Lawler, Mark Giza, John Dammann,

A Moment Radar Data Emulator: The Current Progress and Future Direction Ryan M. May.

False Radar Pulse Detection on WUR Signal

Visit for more Learning Resources

Doppler Radar Basics Pulsed radar

An-Najah National University

RADIATION SOURCES: OUTPUT POWER vs. FREQUENCY

Instrument Landing System and Microwave Landing System

Methodology for 3D Wind Retrieval from HIWRAP Conical Scan Data:

Parallel Processing in ROSA II

Design and Survivability Analysis of a 5GHz Operational Amplifier

Light 24 GHz Multi-Channel RADAR System Aiding Unmanned Aerial Vehicle Navigation Soumyaroop Nandi.

Eliminating range ambiguity

the University of Oklahoma

Developed by Eastwood Im Jet Propulsion Laboratory

Linear Kinematics of Human Movement

Advanced Radar Systems

Microwave Motion Sensor Light Module I

Open book, open notes, bring a calculator

Regents Physics Vectors and Scalars What is a Vector? A scalar?

Presentation transcript:

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR FORESTER Target Doppler Signature Phenomenology* DARPA FOPEN-GXP Industry Day Presentation Paul Monticciolo Jen King Jao MIT Lincoln Laboratory 10 March 2010 *This work was sponsored by the Defense Advanced Research Projects Agency, Information Processing Techniques Office under US Air Force Contract FA C Opinions, interpretations, conclusions, and recommendations are those of the authors and are not necessarily endorsed by the United States Government.

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Outlines Target Doppler signature overview –Tower-based radar measurements –Black-Hawk FORESTER measurements Fort Stewart A160 FORESTER target Doppler signatures Summary

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR FORESTER Detection and Exploitation Processing Challenges Dismount signatures vary with movement, group size, observation geometry, and foliage conditions Principal challenges Complex dismount signatures - Doppler signatures are time varying, aspect angle dependent, and attenuated by foliage Airborne platform motion Platform-antenna interactions Wind-blown clutter Clutter false alarms Target discrimination dBm 2 Range (m) Torso Limb harmonics Single dismount Doppler signature Radial Velocity (m/s) CPI: 5 s

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Target Doppler Signature Examples: Ground Measurements At Ku-Band And UHF 4 Ku-band UHF Frequency & wavelength15.7 GHz & 1.9 cm 435 MHz & 0.7 m Bandwidth & range res.1200 MHz & 12.5 cm 30 MHz & 5 m CPI0.048 s 5 s Doppler at 1 m/s & res.105 Hz & 20.8 Hz2.9 Hz & 0.2 Hz UHF Ku Ku-band, spectrogram over multiple CPIs Range Rate (m/s) Time (s) Range Rate (m/s) Gait period TorsoLimbs Main body Leg Dismount walker Camel Doppler (Hz) Amplitude (dB) Amplitude (dB) One dismount on open road One horse in woods Clutter UHF, Doppler spectrum for one CPI

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Dismount Doppler Signatures MIT LL and ESSCO Tower-Based Measurements RCS (dBsm) Aspect Angle (deg) 22.5° 30.0° Grazing angle Measurement of single unarmed personnel, MHz, HH-pol Doppler harmonics, aspect angle = 0 degDoppler harmonics, aspect angle = 45 deg Torso return 1 st limb modulation rate 2 nd limb modulation rate Subject: 123 Walking speed ~ 1 m/s Grazing angle: 45 deg Torso return 1 st limb modulation rate Walking speed ~ 1 m/s Grazing angle: 45 deg RCS (dBm 2 ) Range Rate (m/s) Range Rate (m/s)

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Dismount Detection and Signature Example Black-Hawk FORESTER Flight 23, 28 June 2007 at Ft. AP Hill SCNR (dB) Range Rate (m/s) Target +Clutter (dB) Clutter Target + clutter Torso return Limb modulation Excellent signature measurements obtained for detected dismounts M123-S Dismount SCNR threshold:14 dB Ground range:7 – 12 km Velocity:0 – 4 m/s SCNR threshold:14 dB Ground range:7 – 12 km Velocity:0 – 4 m/s Distance (east from BH, km) Distance (north from BH, km)

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR 5 dismounts in foliage 5 dismounts in foliage False alarm False alarm SCNR: >14 dB Ground range: 7 – 12 km Velocity: 0 – 4 m/s SCNR: >14 dB Ground range: 7 – 12 km Velocity: 0 – 4 m/s M141-S Distance (east from BH, km) Distance (north from BH, km) Dismount Detection and Signature Example Black-Hawk FORESTER Flight 41, 10 October 2007 at AP Hill False alarm Range Rate (m/s) SCNR (dB) Foliage obscuration and multiple-target groups result in complex target signatures 5 dismounts SCNR (dB)

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Outlines Target Doppler signature overview Ft. Stewart A160 FORESTER target Doppler signatures –Detections –Doppler signature examples Summary

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR SCNR threshold15 dB Range rate<= 4 m/s Beamwidth, (3 beams)~6 deg LOS depression~30 deg s CPIs over 15 min. Composite GMTI Plan Position Indicator (PPI) Targets Moving On Wooded Trails SCNR threshold15 dB Range rate<= 4 m/s Beamwidth, (3 beams)~6 deg LOS depression~20 deg s CPIs over 20 min.

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Composite GMTI PPI Dismount Activities and Boats SCNR threshold15 dB Range rate<= 4 m/s Beamwidth (3 beams)~6 deg LOS depression~30 deg s CPIs over 20 min East (km) North (km)

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Range-Doppler Data Examples Doppler (Hz) Ground Range (km) East (km) North (km) SCNR threshold15 dB Range rate<= 4 m/s Beamwidth (1 beam)~6 deg LOS depression~30 deg s CPIs over 15 min. Flight 30 Taylors Creek DZ Flight 30 Taylors Creek DZ Dwell #57 ( M330-S007)

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR East (km) North (km) Doppler Signature Examples Clutter Relative Power (dB) Doppler (Hz) SCNR threshold15 dB Range rate<= 4 m/s Beamwidth (1 beam)~6 deg LOS depression~30 deg s CPIs over 15 min. Flight 30 Taylors Creek DZ Flight 30 Taylors Creek DZ

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Additional Doppler Signature Examples Doppler (Hz) Amplitude (dB) M330-S Amplitude (dB) M331-S Clutter Doppler (Hz) 1: 2: M330-S : M331-S :

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR M330-S007_PPI_PDS_Movie1.wmv Target Doppler Spectrum Example: Target In Open Field East (km) North (km) SCNR threshold15 dB Range rate <=<= 4 m/s Beamwidth (3 beams)~6 deg LOS depression~25 deg 80 frames over 20 min., 1 frame per 15 sec Current Detection Previous Detections Flight 30 Taylors Creek DZ Flight 30 Taylors Creek DZ

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Target Doppler Spectrum Example: Walking On Dirt Road SCNR threshold16 dB Range rate <=<= 4 m/s Beamwidth (1 beam)~24 deg LOS depression~20 deg 180 frames over 15 min., 1 frame per 5 sec Current Detection Previous Detections M331-S005_PPI_PDS_Movie2.wmv East (km) North (km) Flight 31 D10 – D13 site Flight 31 D10 – D13 site

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR M331-S005_PPI_PDS_Movie3.wmv Target Doppler Spectrum Example: Walking Under Foliage SCNR threshold15 dB Range rate<= 4 m/s Beamwidth (3 beams)~6 deg LOS depression~25 deg 60 frames over 15 min., 1 frame per 15 sec Current Detection Previous Detections East (km) North (km) Flight 31 D10 – D13 site Flight 31 D10 – D13 site

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Target Doppler Spectrum Example: Tree Line Movement East (km) North (km) SCNR threshold15 dB Range rate<= 4 m/s Beamwidth (1 beam)~6 deg LOS depression~25 deg 180 frames over 15 min., 1 frame per 5-s CPI Current Detection Previous Detections Flight 30 Taylors Creek DZ Flight 30 Taylors Creek DZ M330-S007_PPI_PDS_Movie4.wmv

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR M331-S004_PPI_PDS_Movie5.wmv Target Doppler Spectrum Example: Targets Under Trees East (km) North (km) SCNR threshold14 dB Range rate<= 4 m/s Beamwidth (3 beams)~6 deg LOS depression~25 deg 60 frames over 15 min., 1 frame per 15 sec Current Detection Previous Detections Flight 31 D10 – D13 site Flight 31 D10 – D13 site

MIT Lincoln Laboratory Ind. Day 3/10/ For Official Use Only / ITAR exempt from mandatory disclosure under the FOIA, Exemption 3 applies. Not approved for release without permission from DARPA/IPTO FOUO/ITAR Summary FORESTER experimental data indicates that Doppler-based target signatures may be useful for exploitation purposes –Long CPIs provide excellent Doppler resolution –One of many potential activity and discrimination features Fort Stewart data collections cover a wide variety of target classes and scenarios for examining Doppler signatures –Humans, sheep, horses, dogs, mules, and motor vehicles –Open areas, under foliage, woods, and rivers MIT Lincoln Laboratory personnel available during Q & A session