PhD, Postdoctoral Research Associate and Lecturer
Department
of Electrical and Computer Engineering
State
University of New York at Stony Brook
Stony
Brook, NY 11794-2350, USA
Email:
parksy@ece.sunysb.edu
Phone:
O) 631-632-9149
H)
631-928-7255
Fax: O) 631-632-8494
OBJECTIVE
A teaching and research position in Computer Vision and
Image Processing
EDUCATION
¨
September
1999 ~ May 2003: PhD, Department of Electrical and Computer Engineering, The State University of New
York at Stony Brook, Stony Brook, NY
Advisor: Prof. Murali Subbarao
¨ March 1991 ~ February 1993:
MS, Department of Electronics Engineering, Kyungpook National
University, Daegu, Korea
¨
March 1987 ~ February 1991: BE, Department of Electronics
Engineering, Kyungpook
National University, Daegu, Korea
WORK EXPERIENCES
¨ June 2003 ~ present: Postdoctoral Research Associate, Computer
Vision Lab, Department of Electrical and Computer
Engineering, State
University of New York at Stony Brook
¨ January
2004 ~ present: Lecturer,
Department of Electrical and Computer Engineering, State University of New York at Stony Brook
¨ September 2000 ~ May 2003: Research/Teaching Assistant, Computer Vision Lab., Department of Electrical and
Computer Engineering, State University of New York at Stony Brook
¨ September 1999 ~ August 2000: Research Fellow, Department
of Electrical and Computer Engineering, Research Foundation of the State University of New York at Stony Brook
(Supported by Symbol Technology Inc.)
¨ March
1993 ~ August 1999: Senior Research
Engineer, Advanced
Robotics Lab,
Korea Atomic Energy Research Institute (KAERI), Daejon, Korea 305-600
RESEARCH
INTERESTS
o
3D Sensing and Modeling (Sponsor: Olympus Corporation, Japan)
Ÿ
Photo-realistic 3D model reconstruction using
multiple range images of real objects
Ÿ
Stereo camera
calibration and stereo image rectification
Ÿ
Object segmentation
using color image analysis techniques
Ÿ
Registration of multiple
geometric and photometric images using point-to-plane techniques
Ÿ Estimation of 3D pose and
registration of multiple data sets
Ÿ An accurate and fast
point-to-plane registration refinement technique: A new registration technique
based on an Contractive Projection Point (CPP) technique
Ÿ
Volumetric
integration and mesh reconstruction from multiple range images
Ÿ Pose estimation between two
3D models of an object using Base Tangent Plane (BTP) constraints
Ÿ
Object
motion tracking using the CPP-based registration technique
Ÿ
Image-based 3D modeling:
voxel coloring and space carving
Ÿ
Photo-realistic human
face and body modeling
o
Automatic Focusing of Color Digital Camera (Sponsor: Olympus Corporation, Japan)
Ÿ
Automatic focusing of SLR (Single Lens Reflection) digital camera
using the Depth-from-Defocus
technique
Ÿ
Automatic focusing of a
zoom digital camera
Ÿ Measuring of image blur
using a spatial
domain image analysis technique
Ÿ Integration of
Depth-from-Stereo and Depth-from-Focus using digital cameras
o
Stereoscopic Imaging: Development of Stereoscopic Imaging and
Tele-presence Systems (Sponsor: Korean Government Long-term Research Project)
Ÿ
Development of polarized stereoscopic monitors
for tele-presence
Ÿ
Development of parallel-verging stereoscopic
cameras with vergence and focus control
Ÿ
Development of polarized stereoscopic monitors
using TFT-LCDs (Sponsor: Samsung
Electronics)
Ÿ
Development of a binocular target tracking
system with cepstrum-based vergence control technique
Ÿ
Stereo target tracking system using color image correlation and cepstrum-based
matching
Ÿ
Automatic vergence and focus control of a parallel-verging
stereo camera
TEACHING EXPERIENCES
As an Instructor
¨
Spring 2004: ESE124, Computer Techniques for Electronic Design, SUNY at Stony Brook
As a Teaching Assistant
¨
Fall 2000: ESE333, Real-Time Operating System, SUNY at Stony Brook
¨
Spring 2001: ESE344, Software Techniques for Engineers, SUNY at Stony Brook
¨
Fall 2001: ESE358, Computer Vision, SUNY at Stony Brook
¨
Spring 2002: ESE344, Software Techniques for Engineers, SUNY at Stony Brook
¨
Fall 2002: ESE358, Computer Vision, SUNY at Stony Brook
¨
Spring 2003: ESE344, Software Techniques for Engineers, SUNY at Stony Brook
RESEARCH
GRANTS
o Title: Photo-realistic 3D
Model Generation System using Digital Stereo Cameras, Research Assistant, Sponsor:
Olympus Corporation, Project Dates: 11/00 ~ 10/03
o Title: Depth-from-Defocus
Technique for Automatic Focusing of Digital Camera, Research Associate,
Sponsor: Olympus Corporation, Project Dates: 11/03 ~ 10/05
o Title: Clinically-Accurate Low-cost
3D Vision System for Positioning and 3D Surface Imaging of Patients, co-PI,
Sponsor: Center for Biotechnology, SUNY at Stony Brook, proposal submitted
o Title: Improvement in
Detection of Radiological Threats, Research Associate, Sponsor: DTRA, A white
paper submitted to DTRA
PUBLICATIONS (Recent)
¨
Journal papers
¨
Conference papers
1.
Soon-Yong
Park and Murali Subbarao, “A Range Image Refinement Technique for Multi-view 3D
Model Reconstruction”, The 4th International Conference on 3-D Digital Imaging and
Modeling, Oct. 2003.
2.
Soon-Yong
Park and Murali Subbarao, “A Point-to-Tangent plane Technique for Multi-view
Registration,” The 4th International Conference on 3-D Digital Imaging and
Modeling, Oct. 2003.
3.
Soon-Yong
Park and Murali Subbarao, “Pose Estimation and Integration for Complete 3D
Model Reconstruction, “ IEEE Workshop on Application of Computer Vision
(WACV2002), pp.143-147, Dec. 2002.
4.
Soon-Yong
Park and Murali Subbarao, “Pose Estimation of Two-pose 3D Models using the Base Tangent Plane and Stability Constraints”, 7th
International Workshop on Vision, Modeling, and Visualization (VMV2002),
Nov. 2002.
5.
Soon-Yong
Park and Murali Subbarao, “Automatic 3D Model Reconstruction Using Voxel Coding
and Pose Integration,” Proceedings of IEEE International Conference on Image
Processing (ICIP2002), pp. 533-536, Sept. 2002.
6.
Soon-Yong
Park and Murali Subbarao, "A New Technique for Registration and
Integration of Partial 3D Models," Proceedings of SPIE, Vol. 4567,
Oct. 2001.
7.
Huei-Yung
Lin, Murali Subbarao, and Soon-Yong Park, "Complete 3D Model
Reconstruction from Multiple Views," Proceedings of SPIE, Vol.
4567, Oct. 2001.
8.
Soon-Yong Park, Nam-Ho Lee and Yong-bum Lee,
"Simple Method
for Automatic Vergence Control of the Parallel Stereo Camera, " SPIE 10th International Conference on
Electronics Imaging, Jan. 1998.
9.
Soon-Yong Park, Yong-Bum Lee and Jong-Min
Lee,"3-D Model Reconstruction from Three Orthogonal Views Based on Merging
Technique of RP Codes", IEEE Conf.
on System, Man and Cybernetic", Oct. 1995
INVITED TALKS
1. A Complete
3D Model Generation System based on Stereo-Vision Techniques. Olympus Optical Co., Advanced
Core Technology Group, Japan, Sep. 2003.
2.
A Multi-view Modeling Technique for Complete 3D Model Reconstruction: CAVE Lab, Columbia University, New York, Dec. 2002.
3.
Stereoscopic
Vision Systems for Complete and Photorealistic 3D Model Reconstruction, Intelligent
Systems Lab, Rensselaer
Polytechnic Institute, New York, Mar. 2003.
4.
3D
Model Generation from a Stereo Digital Camera, Olympus Optical Co., Advanced
Core Technology Group, Japan, Jan. 2000.
DEMONSTRATION
1.
Photo-realistic 3D Model Generation System, CEWIT (Center of Excellence
at Wireless and Information Technology) Conference, New York, Nov. 2003.
SOFTWARE and HARDWARE SKILLS
1. Programming
Languages: C/C++, Visual C++, Matlab
2. Image/Vision
Libraries: MFC (Microsoft Foundation Class), OpenGL, OpenCV (Intel Computer
Vision Library), MIL (Matrox Image Library), FreeImage (Freeware for Image
Processing), VectorLib (Vector Library from CMU), FLTK, LaPack,
3. Software Tools: AutoCAD, Origin, MS Office, Latex,
OpenOffice
4. Operating Systems: Unix, Linux, MS Windows
5. Image/Vision/Robot
System Interfaces: Frame grabbers (Matrox, Data Translation, Datacube), Point
Grey Stereo Camera, IEE1394 cameras, Digital
camera SDK (Olympus),
A/D and D/A boards (Data Translation), Servo motion controllers, and GPIB board,
3D Scanning System, Stereoscopic Imaging
PATENTS (Korean)
1. Vergence
control method of a parallel-type stereoscopic camera, Korean patent
#1002567770000, 2/24/2000
2. Polarizing
stereoscopic monitor using a color-LCD and two twisted-nematic LCDs, Korean
patent # 2001803830000, 2/17/2000
3. Automatic
vergence control of a stereo-vision camera, Korean patent #2001804390000,
2/7/2000.
4. Polarizing
stereoscopic monitor using TFT-LCD, Korean patent #102508080000, 1/7/2000
5. Method
of depth measure using a stereoscopic camera with vergence control, Korean
patent #1001700160000, 10/14/1998
6. System
for storing and retrieving stereo pictures, Korean patent #1001517600000,
6/23/1998
GRANTS
1. September
1999 ~ May 2000: Graduate Student Research
Fellowship, Research
Foundation of the State University of New York at Stony Brook (Sponsored by
Symbol Technology Co.)
2. March 1991 ~ February 1993: Graduate Student
Scholarship, Kyungpook National University, Korea
3. March 1987 ~ February 1991: Undergraduate Student
Scholarship, Kyungpook National University, Korea
ACTIVITES
1. September
1999 ~ present: IEEE member
2. September
1999 ~ present: SPIE member
RESEARCH SUMMARY (Soon-Yong Park)
One topic of research
interest today in three-dimensional (3D) model reconstruction is the generation
of a complete and photorealistic 3D model from multiple views of an object. My
PhD thesis addresses the problem of generating 3D computer models of real-world
objects. It presents stereo vision systems and computer vision techniques for
complete 3D model reconstruction through a sequence of steps: (1) Multi-view
range image acquisition (2) Registration and integration of multi-view range
images (3) Pose estimation of 3D models (4) Integration of two-pose 3D models
and (5) Photorealistic texture mapping. The thesis presents two stereo vision
systems to obtain multi-view range images and photometric textures of an
object. Range images obtained from multiple views of an object are registered
to a common coordinate system through the calibrations of the vision systems.
In order to refine the registration of multi-view range images, we introduce a
novel registration refinement technique.
For many real
objects, using a single pose yields only a partial 3D model because some
surfaces of the object remain hidden from a range sensor due to occlusions or
concavities. In order to obtain a complete and closed 3D model, we generate two
3D models of the object, register and integrate the 3D models into a single 3D
model. By placing the object in different suitable poses and sensing the
visible surfaces, we reconstruct two partial 3D models. We then merge the
partial 3D models by novel pose registration and integration techniques. A pose
estimation technique between two 3D models is presented to determine coarse
registration parameters. The pose estimation technique finds a stable tangent
plane (STP) on a 3D model which can be transformed to the base tangent plane (BTP)
of the other model and vice versa. After pose estimation, the two pose models
are integrated to obtain a complete 3D model through a volumetric pose
integration technique. The integration technique merges two iso-surfaces of the
corresponding partial 3D models.
Texture mapping finally generates photorealistic 3D models of real-world
objects.
I have been involved in long-term research projects to develop stereoscopic imaging systems. The purpose of the projects was mainly to develop tele-operation systems of remotely operated robotic vehicles, which are supposed to be operated in hazardous nuclear facilities. I have developed polarizing stereoscopic monitors using CRT or LCD monitors. The stereoscopic monitors provide tele-presence to human operators for efficient operation. I was also the main person of a research project to develop stereoscopic cameras. The developed cameras have a parallel-verging stereo configuration and a simultaneous vergence and focus control function. This is because the camera’s lens is detached from the body and moved in parallel and perpendicular directions with the CCD plane to control both focus and vergence.
The
parallel-verging stereo camera with a simultaneous vergence and focus control
system gives a linear control property between the focusing and the vergence.
Using this property of the camera, I control the focus and the vergence
simultaneously using focus measure of the lens system. I was also
involved in developing a binocular
active-vision system for automatic tracking of a moving object in real-time, an
active stereo tracking system to track a moving object in work space, a stereo
BOOM and Molly system for tele-presence, and a tele-inspection system using a
high-definition infra-red camera.