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Introduction to Image
Analog imagesDigital images
Two types of images in medical imaging
Type of images that we, as humans, look at. They include such things as photographs, paintings, TV
images, and all of our medical images recorded on film or displayed on various display devices, like computer monitors.
What we see in an analog image is various levels of brightness (or film density) and colors.
It is generally continuous and not broken into many small individual pieces.
Analog images
Are recorded as many numbers. The image is divided into a matrix or array of small picture
elements, or pixels. Each pixel is represented by a numerical value.The advantage of digital images is that they can be
processed, in many ways, by computer systems.
Digital images
Digital Image is ready for :
1. Change
2. Storage
3. Transfer
Image reconstruction (CT, MRI, SPECT, PET, etc)Image reformatting (Multi-plane, multi-view reconstructions)Wide (dynamic) range image data acquisition (CT, digital
radiography, etc)Image processing (to change contrast and other quality
characteristics)Fast image storage and retrievalFast and high-quality image distribution (PACS, Teleradiology)Controlled viewing (windowing, zooming, etc)Image analysis (measurements, calculation of various
parameters, computer aided diagnosis, etc)
Functions performed with digital images
Image Acquisition
Each pixel is represented by a numerical value. In general, the pixel value is related to the brightness or
colorThat we will see when the digital image is converted into an
analog image for display and viewing.At the time of viewing, the actual relationship between a
pixel numerical value and it's displayed brightness is determined by the adjustments of the window control.
Digital image matrix of pixels
Samplings
+ImaginarySampling
Grid
Analog ImageContinuous Values
=ImageMatrix
Digital ImageDiscrete Values
Pixel Code Values0 to 255
Analog vs. Digital Image
Analog Digital
For human viewingFor computer
viewing
AD Conversion
BIT
Binary Numbers•One of the limitations is the range of values that can be written with a specific number of bits (binary digits).•By using four bits:• 16 different values because there are 16 ways the four
bits can be marked.•The range of possible values is increased by using more bits.•The range (number of possible values) is the number 2 multiplied by itself, or raised to the power, by the number of bits.
Is the number of bits that have been made available in the digital system to represent each pixel in the image.
Pixel bit depth
This is smaller than would be used in any actual medical image because with four bits, a pixel would be limited to having only 16 different values (brightness levels or shades of gray).
When the pixel bit depth is increased to eight bits, a pixel can then have 256 different values (brightness levels, shades of gray, etc).
Pixel bit depth
Image resolution describes the detail an image holdsThe term resolution is often used as a pixel count in
digital imagingAn image that is 2048 pixels in width and 1536 pixels in
height has a total of 2048×1536 = 3,145,728 pixels or 3.1 megapixels
Resolution
Resolution
Grayscale resolution
•1st image A pixel can have only two possible values, BLACK or WHITE.•2nd image, four bits per pixel, is limited to 16 different brightness levels (shades of gray)
Different bit depths and possible brightness levels
•3rd image, eight bits per pixel, can display 256 different brightness levels. This is generally adequate for human viewing.
When an image is in digital form, it is actually blurred by the size of the pixel. This is because all
anatomical detail within an individual pixel is "blurred together" and represented by one number.
The physical size of a pixel, relative to the anatomical objects, is the amount of blurring added to the imaging process by the digitizing of the image.
Here we see that an image with small pixels (less blurring) displays much more detail than an image made up of larger pixels.
The size of a pixel is determined by the ratio of the actual image size and the size of the image matrix.
Image size dimensions of the field of view (FOV) within the patient's body not the size of a
displayed image
Matrix size: number of pixels along the length and width of an image. This can be the same in both directions,
but generally it will be different for rectangular images to produce relatively square pixels.
Increasing the matrix size, for example from 1024 to 2048 pixels, without changing the image field of view, will produce smaller pixels.
This will generally reduce blurring and improve image detail.
Different matrix sizes are used for the different imaging modalities
This is to produce a pixel size that is compatible with BlurringDetail characteristics of each modality.
With many modalities, the matrix size can be adjusted by the operator to optimize:Image quality Imaging procedure
1. The number of pixels which is found by multiplying the pixel length and width of the image.
2. The bit depth (bits per pixel). This is usually in the range of 8-16 bits, or 1-2 bytes, per pixel.
Numerical size of an image
The larger the image (numerically), the more memory and disk
storage space is required, more time for processing and
distribution of images is required.
Image compression is the process of reducing the numerical size of digital images.
There are many different mathematical methods used for image compression.
The level of compression is the factor by which the numerical size is reduced. It depends on the compression method and the selected level of compression.
Lossless compression is when there is no loss of image quality, and is commonly used in many medical applications.
Lossy compression results in some loss of image quality and must be used with care for diagnostic images.
No Processing
No Acquisition
No
StorageNo
Transfer
Analog
Image
Image Processing
Image Acquisition
Image
Storage Image
Transfer
Digital
Image
Digital Radiography
Computed
Radiography
Digital Image
Acquisition
Thank you
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