January 29, 2007Videometrics IX, Electronic Imaging 2007, San Jose, CA, U.S.A. Real-Time Range Imaging by Phase-Stamp Method Using Correlation Image Sensor.

Slides:

Advertisements

Similar presentations

Extrinsic and Depth Calibration of TOF-cameras Reporter ：鄒嘉恆 Date ： 2009/12/22.

Advertisements

Verification of specifications and aptitude for short-range applications of the Kinect v2 depth sensor Cecilia Chen, Cornell University Lewis’ Educational.

TERRESTRIAL LASER SCANNING (TLS): APPLICATIONS TO ARCHITECTURAL AND LANDSCAPE HERITAGE PRESERVATION – PART 1.

Sensing industry needs Use of Laser Range Finders in Mobile Robots & AGV’s 22 nd April 2009 Hannover.

Kawada Industries Inc. has introduced the HRP-2P for Robodex 2002

Structured Light principles Figure from M. Levoy, Stanford Computer Graphics Lab.

--- some recent progress Bo Fu University of Kentucky.

Calibration for LHAASO_WFCTA Yong Zhang, LL Ma on behalf of the LHAASO collaboration 32 nd International Cosmic Ray Conference, Beijing 2011.

Laser Distance measurement by Aleksi Väisänen Pauli Korhonen.

Rotary Encoder. Wikipedia- Definition  A rotary encoder, also called a shaft encoder, is an electro- mechanical device that converts the angular position.

Structured light and active ranging techniques Class 11.

Depth from Structured Light II: Error Analysis

Vision Sensing. Multi-View Stereo for Community Photo Collections Michael Goesele, et al, ICCV 2007 Venus de Milo.

Currently: 3 year ( ) NSF-supported UF/IAP collaborative project "Methods and Instruments for High-Precision Characterization of LIGO Optical Components"

SIGGRAPH Course 30: Performance-Driven Facial Animation Section: Markerless Face Capture and Automatic Model Construction Part 2: Li Zhang, Columbia University.

Structured light and active ranging techniques Class 8.

Stereoscopic Light Stripe Scanning: Interference Rejection, Error Minimization and Calibration By: Geoffrey Taylor Lindsay Kleeman Presented by: Ali Agha.

A Laser Range Scanner Designed for Minimum Calibration Complexity James Davis, Xing Chen Stanford Computer Graphics Laboratory 3D Digital Imaging and Modeling.

1 Adaptive computer-based spatial -filtering method for more accurate estimation of the surface velocity of debris flow APPLIED OPTICS M. Shorif, Hiroyuki.

Chem. 133 – 2/17 Lecture. Announcements Lab Work –Electronics Lab Report due 2/19 –Let me know by today if you plan to do a lab practical instead –Half.

Sean Ryan Fanello. ^ (+9 other guys. )

Structured light and active ranging techniques Class 8

The Remote Sensing of Winds Student: Paul Behrens Placement and monitoring of wind turbines Supervisor: Stuart Bradley.

Digital Imaging Systems –I/O. Workflow of digital imaging Two Competing imaging format for motion pictures Film vs Digital Video( TV) Presentation of.

1 Intelligent Robotics Research Centre (IRRC) Department of Electrical and Computer Systems Engineering Monash University, Australia Visual Perception.

Surface Contouring by phase-shifting real-time holography using photorefractive sillenite crystals M.R.R. Gesualdi,D.Soga, M.Muramatsu Optics and Laser.

PSD Motion Capture Device Professor ： Yih – Ran Sheu Student ： Shih-Ping Chou Student Id ： MA PTT Production Rate ： 100 ％ 1 This paper appears in:

Image Processing1 Image Acquisition Photo sensors –Photo diodes and photo diode array –Photo transistor Video camera.

Gerardo Cabral Jr MIS 304 Professor Fang Fang.  Project Natal” is the code name for a revolutionary new way to play on your Xbox 360.  Natal is pronounced.

Real-Time Phase-Stamp Range Finder with Improved Accuracy Akira Kimachi Osaka Electro-Communication University Neyagawa, Osaka , Japan 1August.

LSC meeting, HLO, August 18, 2004 IAP/UF/LIGO Research Collaboration: Status and Prospectives Efim Khazanov, Ilya Kozhevatov, Anatoly Malshakov, Oleg Palashov,

3D SLAM for Omni-directional Camera

IPBSM status and plan ATF project meeting M.Oroku.

Building Three-Dimensional Images Using a Time-Reversal Chaotic Cavity

ICOSN2001 Yokohama, Japan 1 Measurement of density distribution in a small cell by digital phase-shift holographic interferometry Toshiharu Mizukaki*,

A New Fingertip Detection and Tracking Algorithm and Its Application on Writing-in-the-air System The th International Congress on Image and Signal.

CONTACT-LESS 3D COORDINATE MEASUREMENT SYSTEM BY LASER SCANNING AND IMAGE RECONSTRUCTION FROM UNORGANIZED DATA Gabriella Tognola (1) Cesare Svelto (2)

Digital two photon microscopy for multiple fast signals acquisition Laboratory of Advanced Biological Spectroscopy (L.A.B.S.) University of Milan - Bicocca.

DECREASED FLICKER SENSITIVITY WITH A SCANNED LASER DISPLAY. J.P. Kelly 1, H.L. Pryor, E.S. Viirre, T. Furness III. 1 Children's Hospital & Medical Center;

Haifeng Huang and Kevin K. Lehmann

Development of a Gamma-Ray Beam Profile Monitor for the High-Intensity Gamma-Ray Source Thomas Regier, Department of Physics and Engineering Physics University.

Tests of AWAKE spectrometer screen and camera at PHIN Introduction Layout Procedure Setup, results (runs 1 – 5) Conclusions L. Deacon, S. Mazzoni, B. Biskup.

Development of a laser slit system in LabView

高精度高速度的三维测量技术. 3D stereo camera Stereo line scan camera 3D data and color image simultaneously 3D-PIXA.

Liquid Crystal Elastomer Response to Light Rafael Soares Zola CPIP-LCI Advisor: Peter Palffy-Muhoray.

Physics 114: Lecture 8 Measuring Noise in Real Data Dale E. Gary NJIT Physics Department.

Charles University Prague Charles University Prague Institute of Particle and Nuclear Physics Absolute charge measurements using laser setup Pavel Bažant,

Beam Halo Monitoring using Optical Diagnostics Hao Zhang University of Maryland/University of Liverpool/Cockcroft Institute.

Charts for TPF-C workshop SNR for Nulling Coronagraph and Post Coron WFS M. Shao 9/28/06.

Taikan SUEHARA, ATF2 meeting, KEK, 2006/11/22 Status of fringe stabilization of Shintake-monitor Taikan SUEHARA The University of Tokyo.

Electrical and Computer Engineering Smart Goggles To Chong Ryan Offir Matt Ferrante James Kestyn Advisor: Dr. Tilman Wolf Team Wolf.

Analysis of denoising filters for photo response non uniformity noise extraction in source camera identification Irene Amerini, Roberto Caldelli, Vito.

Robust Segmentation of Freight Containers in Train Monitoring Videos Qing-Jie Kong*, Avinash Kumar**, Narendra Ahuja**,Yuncai Liu* **Department of Electrical.

European Geosciences Union General Assembly 2016 Comparison Of High Resolution Terrestrial Laser Scanning And Terrestrial Photogrammetry For Modeling Applications.

Optical Instruments II Instruments for Imaging the Retina.

Date of download: 6/26/2016 Copyright © 2016 SPIE. All rights reserved. Horizontal noncontact FMT imaging system. (a) The FMT setup is illustrated, where.

Tracking Under Low-light Conditions Using Background Subtraction Matthew Bennink Clemson University Clemson, SC.

L08Tarange from cameras1.

Nov Visualization with 3D CG

range from cameras stereoscopic (3D) camera pairs illumination-based

General Engineering Research Institute

AAFS 2004 Dallas Zeno Geradts

Abstract ID: Programm Nr 2276

제 5 장 스테레오.

Range Imaging Through Triangulation

Distance Sensor Models

LightGage™ Frequency Scanning Technology

Volume 98, Issue 9, Pages (May 2010)

All images are compressed.

Presentation transcript:

January 29, 2007Videometrics IX, Electronic Imaging 2007, San Jose, CA, U.S.A. Real-Time Range Imaging by Phase-Stamp Method Using Correlation Image Sensor Akira Kimachi 1 and Shigeru Ando 2 1 Osaka Electro-Communication University, Japan 2 The University of Tokyo, Japan

Active Range Imaging Active range imaging — Image sensor + Active light –Time-of-flight methods –Triangulation methods # of frames (scans) Interpixel image processing Image intensity- dependence Light spotManyNoneYes Light stripeManyStripe detectionYes Time stamp light stripe 1NoneYes Structured light1Fringe detection Fringe order Yes Phase-shifting structured light 3-4 or moreNoneNo

Depth Scan angle of sheet beam Stripe image location Light Stripe Range Finder (LSRF)

Time Stamp LSRF (TSRF) Frame-rate operation Pixel-wise sensing –One image for one beam scan –Record a “Time Stamp” for light stripe arrival at each pixel “VLSI silicon range finder” –Gruss et al. (1991) –Kang et al. (1994) –Yokoyama et al. (1994) depth beam angle time stamp

TSRF threshold LSRF Effect of Spatially Nonuniform Reflectance/Background Intensity-dependent detection of light stripe causes errors in LSRF and TSRF nonuniform surface reflectance nonuniform background illumination nonuniform surface reflectance nonuniform background illumination

Objectives Goal — Real-time active range imaging –Frame-rate operation –Pixel-wise sensing (image processing error-free) –Robustness to spatial nonuniformity in Surface reflectance Background illumination Solution — Phase-Stamp Range Finder (PSRF) –Three-Phase Correlation Image Sensor (3PCIS) –Detect the sheet beam angle by “phase stamp”

Three-Phase Time-Domain Correlation Image Sensor (3PCIS) temporal correlation S. Ando and A. Kimachi, IEEE Trans. ED (2003) average intensity

Phase-Stamp Range Finder (PSRF) Three-phase reference signals : Frame rate : Object surface reflectance : Sheet beam intensity : Background light intensity : Arrival time of light stripe Image intensity at

Phase-Stamp Imaging (1) Sheet beam arrives (2) Phase stamped (3) Converted to beam angle one scan one image

Real-Time Range Imaging by PSRF 3PCIS output Phase stamp Total light image Sheet beam image Range imageBeam angle image known function by design Frame-rate range imaging Pixel-wise beam angle detection Robust to spatially nonuniform reflectance/background Phase stamp image uncorrelated to

3PCIS Output Images in PSRF Sheet beam-only intensity imageTotal light intensity image : Surface reflectance : Sheet beam intensity : Background intensity 0   /2  /2 Phase stamp image

Experimental PSRF System 3PCIS camera –200x200 pixels –Frame fps Sheet beam –7 mW laser diode –Cylindrical lens –Scanning scans/s Reference signals –PC ＋ D/A board Hz Camera and geometry calibration –Based on Zhang’s method Reference signals Sheet beam angle

Real-Time 3D Video Capture Phase stampTotal light intensity Sheet beam intensity

3D Imaging Examples left thumb & palm cone-shaped surface 23 mm 17 mm 40 mm

3D Measurement Accuracy Flat mm from the camera phase stamptotal lightsheet beam PhaseStd. dev.4.08 deg Depth Std. dev.2.35 mm Syst. error-1.96 mm 0   /2  /2 3D surface plot

Nonuniform Background Illumination Backgroundabsentstriped Std. dev. [mm] Syst. err. [mm] phase stamptotal lightsheet beam

Nonuniform Surface Reflectance Reflectanceuniformstriped Std. dev. [mm] Syst. err. [mm] phase stamptotal lightsheet beam

Conclusions Phase-stamp range finder using the 3PCIS –Frame-rate operation –Pixel-wise sensing –Robustness to spatial nonuniformity in Surface reflectance Background illumination Evaluation by an experimental system –Real-time range fps –Accuracy Deviation — 2.35 mm → fixed pattern noise (~4 deg) removal Systematic error — mm → geometry calibration

Outline Introduction –Real-time active range imaging Phase-stamp range finder (PSRF) –Three-phase correlation image sensor (3PCIS) –Phase-stamp imaging Experimental system Results Conclusion

Previous Results Other real-time range finders using 3PCIS –Phase-modulated sheet beam Kimachi et al., Trans. IEE Japan (2001) –Phase-modulated structured light Goto et al., 19th Sensor Symposium (2002) Ono et al., 21st Sensor Symposium (2004) PSRF is simpler –No modulated light needed