The document discusses the objectives and outcomes of a course on digital image processing. The course aims to introduce students to fundamental image processing techniques including image enhancement, restoration, compression and segmentation. It will also cover color image processing and different methods to represent color images. The syllabus outlines topics like digital image basics, enhancement, restoration, compression, color processing and segmentation that will be covered in the course.
2. Course Objectives:
The student should be made to
1. Learn digital image fundamentals and to be exposed to basic image
processing techniques.
2. Be familiar with image segmentation and compression techniques.
3. Learn to represent color images in the form of features.
Course Outcomes:
Upon successful completion of this course, students will be able to:
1. Explain digital image fundamentals and basic image processing techniques.
2. Evaluate the techniques for image enhancement and restoration.
3. Define the need for image compression and to analyse various image
compression methods.
4. Partition a digital image into multiple objects using various techniques.
5. Use different color models to represent an image.
3. Syllabus:
1. Digital Image fundamentals
2. Image enhancement
3. Image restoration
4. Image compression
5. Colour image processing
6. Image segmentation
Text Books:
1. Rafael C. Gonzales, Richard E. Woods, “Digital Image Processing”, Third
Edition, Pearson Education, 2010
2. Digital Image Processing by S Jayaraman , S Esakkirajan , T Veerakumar ,
Tata McGraw-Hill Education
6. Remote sensing
Image transmission &
storage applications
Medical processing
Radar & sonar
Robotics & automated
inspection
Typical Applications
Tracking of earth resources, Flood & fire control
Geographical mapping, urban growth, weather,
Other environmental appl. & space applications
TV Broadcasting, teleconferencing
Transmission of facsimile images for office automation
Security monitoring systems, military communications
X-Ray images processing, cineangiograms, radiology images
Nuclear magnetic resonance, ultrasonic scanning
Detection of tumours etc.
Detection and recognition of targets
Guidance of aircraft or missile systems
Exploration of sea & submarine navigation
quality inspection in industries
Robotic vision, computer vision
Real time product monitoring in manufacturing process.
8. Image representation &
modelling
Image enhancement
Image restoration
Image analysis
Image reconstruction
Basic classes of problems
Image data
compression
Concerned with pixel representation
To improve certain image features for
analysis or for image display
Refers to minimization of known
degradations in an image
Concerned with making quantitative measurements
from an image to produce description on it
Reconstruction of 2-D object using several 1-D
projections
Associated with image storage capacity and
transmission
27. Image Enhancement:
• It is the process of filtering image(removing noise, increasing
contrast, etc.,) to improve the quality.
• The resulting image will be more suitable than the original
image.
28. Image Restoration:
• It is the process of improving appearance (reducing blurring etc)
of an image by mathematical or probabilistic models.
30. Image Compression:
• It involves the techniques for reducing the size of the image
with minimum deterioration in its quality.
• Technique for reducing the storage required to save an image or
to transmit it.
Multi-Resolution Processing:
• It is the process of representing images in various degrees of
resolution.
31. Morphological Processing:
• It is the process for extracting image components that are useful
in the representation and description of shape.
32. Image Segmentation:
• It is the process of partitioning the image into multiple segments.
• Partition an image into its constituent parts or objects.
• More accurate the segmentation, more likely the recognition
succeed
33. Image Representation & Description:
• It involves representing an image in various forms:
• Boundary Representation :
It focuses on the external shape characteristics such as corners
and inflections.
• Regional Representation:
It focuses on internal properties such as texture and skeletal
shape.
• Description also known as Feature selection helps in extracting useful
information for differentiating one class of objects from another.