BINF 5040 Medical Imaging and Networking

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BINF 5040Medical Imaging and Networking

• In this course basically following main areas
  will be covered
• 1. Image processing techniques Low level
  processing, High level processing, Image
  analysis, Image recognition.
• 2. Image Compression
• Current image compression techniques
• 3. Networking/ transmission of data and images
• 4. Practical aspects of image processing and
  visualization
• 5. Some hands-on applications.
• You will be required to do some project work
  related to image processing and visualization.

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• Introduction
• Image Processing in general terms, refers to
  manipulation and analysis of pictorial
  information. Pictorial information means a two
  dimensional visual image.
• Any operation that acts to improve, correct,
  analyze, or in some way change an image is called
  image processing..
• Most powerful image processing system we see and
  use everyday is the one composed of human eye and
  brain. This biological image processing system
  focuses, acquires enhances, restores, analyzes,
  compresses and stores images at astounding rates.
• We do not even realize that we are doing so much
  processing.

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• Introduction
• There are three basic types of image processing
• 1. Optical image processing uses an arrangement
  of optical elements to carry out an operation.
  Eye glasses are a form of optical image
  processing. When a process is applied to an image
  that is in the form of transmitted or reflected
  light, we refer it an optical process.
• 2. Analog image processing uses analog
  electrical circuits to carryout the operation.
  When the process is applied to an image that is
  in the form of analog signal, we refer to it as
  an analog process.
• 3. Digital Image Processing uses digital
  circuits, computer processors and software to
  carryout the operation. Within the digital
  domain, an image is represented by discrete
  points of numerically defined brightness. By
  manipulating this brightness, digital computer
  implements image processing.

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Image processing results are intended for human
or computer interpretation. One of the major
area of application of digital image processing
is machine perception. In this case, interest is
focused on procedures for extracting relevant
information from an image, which is suitable for
computer processing. Typical problems in machine
perception that routinely employ image processing
techniques are Automatic character recognition,
industrial robots for product assembly and
inspection, military recognizance, automatic
processing of finger prints, analysis of
x-rays,analysis of blood samples, and processing
of aerial and satellite imagery for weather
prediction and crop assessment.
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INTRODUCTION TO IMAGE PROCESSING
Mass Storage
Digital Computer
Digitizer
Image
Operator Console
Image Processor
Display
Hard Copy Device
Elements of a Digital Image Processing System
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Examples of Image Processing
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• Computer Vision
• It is defined as a process of extracting,
  Processing and interpreting information from
  images of a three dimensional world.
• This process is also known as machine vision.
• The process can be divided into following
  principal areas.
• Sensing
• Pre-processing
• Segmentation
• Description
• Recognition
• Interpretation

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• Computer Vision
• Image sensing is the process that yields a visual
  image.
• Preprocessing deals with techniques such as
  reduction of noise and image enhancement details.
• Segmentation is the process that partitions an
  image into objects of interest.
• Description deals with computation of features
  (e.g. size and shape) suitable for
  differentiation one type of object from other.
• Recognition process identifies these objects
  (i.e. nut, bolt, features etc).
• Finally interpretation assigns meaning to an
  ensemble of recognized objects.

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• Elements of Digital Image Processing System
• Image Processor
• A digital image processor is the heart of any
  image processing system. It consists of a set of
  hardware modules that perform four basic
  functions
• Image acquisition
• Storage
• Low-level processing
• Display
• Typically image acquisition module has a TV type
  of signal as the input and converts this signal
  into digital form.
• Most image processors are capable of digitizing
  an image in one frame.
• For this reason, the image acquisition module is
  often referred to a frame grabber.

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• Elements of Digital Image Processing System
• Storage Module
• Called as a frame buffer, is a memory capable of
  storing an entire digital image.
• Usually, such modules are incorporated in an
  image processor.
• It can load or read 30 images per second.
• This feature allows the image acquisition module
  to deposit a complete image into storage as fast
  as it is being grabbed.
• Processing Module
• Performs low-level functions such as arithmetic
  and logic functions.
• This module is often called ALU.
• It is a specialized hardware designed to gain
  speed by processing image elements in parallel.

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• Elements of Digital Image Processing System.
• Display Module
• The function of display module is to read an
  image memory, convert the stored digital
  information into an analog video signal and
  output this signal to the TV monitor or video
  device.
• Digitizers
• A digitizer converts an analog image into a
  numerical representation suitable for input into
  digital computer.
• Among the most commonly used input devices are
  scanners, image dissectors, video cameras and
  photosensitive solid-state arrays.

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• Elements of Digital Image Processing System.
• Storage Devices
• A digital image consisting of 1024 X 1024 pixels,
  each of which is quantized into 8 bits requires
  1 megabytes of storage.
• Providing adequate bulk storage facilities is one
  of the most important aspects in the design of a
  general purpose image processing system.
• The three principal storage media used in this
  type of work are magnetic disks, magnetic tapes
  and optical disks.
• Magnetic disks of a 10- 40 gigabytes are common.
  A 10 Gb disk could hold 10, 000 gray images.
• High density magnetic tape can store 6400 bytes
  per inch, based on current laser read/write
  technology.
• The storage capacity of single optical disk can
  be 20 000 to 50, 000 good quality images.

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• Elements of Digital Image Processing System.
• Display Devices
• TV type of monitors are the principal display
  devices used in modern image processing systems.
• Monitors are driven by the output of the image
  display module in the image processor.
• In the CRT system the horizontal and vertical
  positions of each element in the image array are
  converted into voltages that are used to deflect
  the CRTs electron beam, thus providing the two
  dimensional drive necessary produces an output
  image.
• The basic idea image acquisition and processing
  is similar to human eye and brain. We try to
  provide this capability to a machine through a
  camera and a computer.
• Let us look at human eye.

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• Elements of Digital Image Processing System.
• Image Sensing Device ( Human Eye )
• Eye is nearly spherical in shape (dia 20mm). It
  is enclosed by three membranes -- cornea and
  sclera outer cover, the choroid and retina.
• The cornea is a tough transparent tissue that
  covers the anterior surface of the eye.
• The central opening of the iris is variable in
  diameter from 2 mm to 8 mm.
• The innermost membrane of the eye is the retina,
  which lines the inside of the walls entire
  posterior portion.
• When the eye is properly focused, light from an
  object outside the eye is imaged on the retina.
• There are two classes of receptors cones and
  rods.
• The cones in each eye number between 6-7
  millions, located in the central portion of the
  retina, called fovea, and are highly sensitive to
  color.

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Cornea
Ciliary body
Ciliary muscle
Vitreous humor
Retina
Fovea
Sclera
Choroid
Model of human eye
Nerve and sheath
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• Elements of Digital Image Processing System.
• Display Devices
• Humans can resolve fine details with these cones.
• Muscles controlling the eye rotates the eyeball
  until the image of an object of interest falls on
  the fovea.
• Cone vision is also known as photopic or
  bright-light vision.
• The number of rods are much larger 75-150m,
  distributed over retinal surface. Rods serve to
  give a general, overall picture of the field of
  view.
• They are not involved in color vision and are
  sensitive to low levels of illumination.
• This is known as scotopic of dim-light vision.

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• Elements of Digital Image Processing System.
• Display Devices
• Distance between the focal point of the lens and
  the retina varies from 17mm - 14mm, as the
  refractive power of the lens increases from
  min-max.
• When eye is focused on an object 3m or farther,
  lens exhibits lowest refractive power.
• Example Looking at an object 15 m high at 100 m
  away.
• Let x be size of retinal image in mm.
• The retinal image is reflected in the area of the
  fovea.
• Camera also work on the same principal.

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• Some Basic Relationship Between Pixels
• Image Acquisition
• Depth of field The space below and above the
  object plane where the lens maintains the focus
  of the image within acceptable limits is depth
  of field.
• The depth of field is a function of aperture
  size, magnification and size of sensor elements.
  The depth increases as the aperture becomes
  smaller, but the amount of light transmitted
  decreases. ( f /128 smallest opening. f /1.05 is
  the largest opening in common cameras)
• Depth of field(Df)
• mmagnification factor ,
• a pixel size,
• f aperture size

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• Some Basic Relationship Between Pixels
• Image Acquisitions
• Example Determine depth of field for a vision
  system having 200 X 200 array sensor of 0.3 X 0.3
  inches, f stop of 16, and magnification factor of
  0.05.
• Resolution is defined as half the pixel size
  0.0015/2 inches
• Larger the magnification, smaller the depth of
  field.

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• Some Basic Relationship Between Pixels
• Image Acquisitions
• Images may be acquired in digital format or
  sometimes in analog format.
• If the image is acquired from an analog camera,
  we have to convert it in digital form by using
  A/D conversion.
• The typical process will be
• sample the analog signal - choose a suitable
  sampling frequency
• decide appropriate gray ( intensity) levels - 16
  to 256 levels
• perform actual digitization
• Proper sampling is very important. It is normally
  selected as twice the rate of highest frequency
  component in an image.

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• Some Basic Relationship Between Pixels
• Image Acquisitions

voltage
time
T is the time interval between two samples
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• Applications of Digital Image Processing
• Biological Research - Biological research and
  biomedical laboratories use digital imaging
  techniques to visually analyze components of
  biological samples. In some cases, digital image
  processing techniques provide a totally automated
  systems for the specimen analysis.
• e.g., automatic classification of cell
  structures and other objects satisfying the
  prescribed characteristics, DNA typing, bone
  tissue and cell analysis.
• Medical diagnostic Imaging -Medical radiological
  imaging looks at the internal organs of human
  body. X-ray imaging and computer tomography (CT)
  make intensive use of digital image processing.
• Image Enhancement - various techniques for
  improving

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• Applications of Digital Image Processing
• the visibility of features that are not
  evident or clear in the original image, such as
  contrast balancing and edge sharpening.
• Digital Subtraction Angiography - enhancing
  blood vessel imagery by subtracting a baseline
  X-ray image from a second image with an X-ray
  opaque liquid in the blood stream.
• Computer Tomography - creating images using
  multiple image projections. This method is used
  in CT, MRI, fMRI, and PET scanners
• Defense/Intelligence
• Document Processing
• Factory Automation
• Visual inspection, quality control, defect
  checks, etc.

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• Applications of Digital Image Processing
• Law Enforcement Forensics - fingerprint analysis
  and classification, DNA matching, biological
  material analysis and matching between multiple
  samples.
• Material Research - material feature check,
  surface check, impurity analysis, grain size
  check, creating 3-D surfaces and internal
  structure rendering for visualization of
  features.
• Remote Sensing/ Earth Resources - land cover
  analysis, terrain rendering of 3-D features
• Space Exploration/ Astronomy- detecting features
  which are changing over the time, solar activity,
  etc.
• Photography
• Robotics
• Publishing,