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Digital Radiography

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Title: Digital Radiography


1
Digital Radiography Chapter 11Adjuncts to
Radiology Chapter 12
  • Brent K. Stewart, PhD, DABMP
  • Lois Rutz, M.S. Radiation Safety Engineering,
    Inc.
  • a copy of Brent Stewarts unmodified lecture may
    be found at
  • http//courses.washington.edu/radxphys/PhysicsCour
    se04-05.html

2
Take Away Five Things You should be able to
Explain after the DR/Adjuncts Lecture
  • The various types of detectors used in digital
    imaging (e.g., scintillators, photoconductors,
    etc.)
  • The differences between the various technologies
    used for digital radiography (e.g., CR, indirect
    and direct DR)
  • Benefits of each type (e.g., resolution, dose
    efficiency)
  • Why digital image correction and processing are
    necessary or useful and how they are executed
  • The various types of adjuncts to radiology (e.g.,
    DSA or dual-energy imaging), what issue they are
    trying to resolve, mechanism exploited and end
    result

3
Why Digital/Computed Radiography
  • Limitations on Film/Screen radiography
  • Screen/Film system is image receptor and display
  • Image characteristics depend on Screen/Film and
    Film processing.
  • Modification of image difficult to control (e.g.
    development temperature).
  • Image appearance depends on technique settings.
  • Image quality cannot be repaired after
    development. Retake only solution to poor I.Q.

4
Why Digital/Computed Radiography cont.
  • Screen/film dynamic range 2 to 2.5 orders of
    magnitude.
  • Different applications require different
    screen/film combinations.
  • Only one original image.
  • Films often go missing from ER or ICU and never
    are archived.
  • Copies expensive, have inconsistent quality, and
    often are non-diagnostic.
  • Archive space expensive, often remote.
  • Digitizing film is only way to move images to
    PACS.

5
How does Digital/Computed Radiography solve these
problems?
  • Decouples imaging chain components.
  • Detector, image processing, display all
    independent entities.
  • Independent in design but not in application.
  • Detector can make use of extended dynamic range.
  • Solid state detectors have improved DQE.
  • Electronics can apply corrections to input
    signals.
  • In particular, over/under exposure can be
    corrected, reducing retakes.

6
How does Digital/Computed Radiography solve these
problems? Cont.
  • Image processing can modify and enhance raw
    (pre-processed) data.
  • Images can be displayed on workstations which
    permit interactive display processing.
  • Image data is stored digitally. Original image
    is available everywhere and at any time.

7
CR vs. DR
  • CR also known as a Photostimulable Phosphor
    system.
  • CR uses an imaging plate similar to an
    intensifying screen as the receptor.
  • CR systems are indirect digital systems.
  • Indirect systems convert x-radiation to the final
    digital image through one or more stages.
  • DR digital radiography
  • Uses a fixed detector such as amorphous selenium
    plate as the receptor.
  • Can be a direct or an indirect digital system.
  • When direct it is sometimes called DDR for direct
    digital radiography

8
CR
  • Detector or Imaging Plate (IP) is essentially a
    type of intensifying screen.
  • IP can be used in any bucky or table-top system.
  • IP is relatively robust. Requires same care as
    intensifying screens.
  • Process is indirect.
  • X-ray creates excitation center.
  • Plate reader uses red light to stimulate centers
    to release blue light.
  • Blue light is directed to a photo-electric
    transducer (pmt or other).
  • Electric signal digitized to make raw image.

9
CR and DR Systems
10
Image Production in CR/DR Systems
  • Radiation through the patient creates a latent
    image on the receptor.
  • Receptor is read by some process and latent
    image is converted to an electronic signal.
  • Signal is processed.
  • Processing is related to acquisition system
    characteristics.
  • Signal (analog) is converted via ADC to a bit
    value in a digital matrix.
  • Digital image is processed.
  • Processing is related to desired image
    information.
  • Digital matrix is displayed on a video screen or
    printed to paper or film.

11
Signal Processing
  • Primarily to accommodate variations in the
    detector/electronics components.
  • Involves corrections for dead space,
    non-uniformities, defects.
  • Could be developed to compensate for MTF losses.
  • All systems, PSP or Direct, do some sort of
    processing and scaling.
  • Ultimate goal is to present the image processing
    module with true image pixels.

12
Digital Image Correction
  • Interpolation to fill in dead pixel and
    row/column defects
  • Subtracting out average dark noise image
    Davg(t)(x,y)
  • Differences in detector element digital values
    for flat field
  • Gain image G(x,y) G(x,y) - Davg(t)(x,y) Gavg
    (1/N) ? ? G(x,y)
  • Make corrections for each detector element (map)
  • I(x,y) Gavg Iraw(x,y) - Davg(t)(x,y) /
    G(x,y)
  • Done for DR and in a similar manner for CT
    (later)
  • Not performed for CR on a pixel by pixel basis,
    although there are corrections on a column basis
    for differences in light conduction efficiency in
    the light guide to the PMT

13
Digital Image Correction
c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 310.
14
Detectors
  • In order to understand signal processing we need
    to learn about the detectors.
  • Photo Stimulable Phosphor Plates
  • Photoconductive materials.
  • Detector consists of a receptor material (e.g.
    BaF(H)Eu), and a set of signal readout and
    conversion electronics.
  • Receptor responsible for the DQE.
  • Rest of the system contributes to noise,
    resolution,dynamic range.

15
Detectors in Digital Imaging (1)
  • Gas and solid-state detectors
  • Energy deposited to e- through Compton and
    photoelectric interactions
  • Gas detectors apply high voltage across a
    chamber and measuring the flow of e- produced by
    ionization in the gas (typically high Z gases
    like Xenon Z54, K-edge 35 keV)
  • Were used in older CT units

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p.32.
16
Detectors in Digital Imaging (2)
  • Solid-state materials
  • Electrons arranged in bands with conduction band
    usually empty
  • Solid-state detectors
  • Scintillators some deposited energy converted
    to visible light
  • Photoconductors charge collected and measured
    directly
  • Photostimulable phosphors energy stored in
    electron traps

c.f. Yaffe MJ and Rowlands JA. Phys. Med. Biol.
42 (1997), p. Elements of Digital Radiology, p.
10.
17
Detectors in Digital Imaging (3)
c.f. Yaffe MJ and Rowlands JA. Phys. Med. Biol.
42 (1997), p. Elements of Digital Radiology, p.
9.
18
Computed Radiography (CR)
  • Photostimulable phosphor (PSP)
  • Barium fluorohalide 85 BaFBrEu 15 BaFIEu
  • e- from Eu2 liberated through absorption of
    x-rays by PSP
  • Liberated e- fall from the conduction band into
    trapping sites near F-centers
  • By low energy laser light (700 nm) stimulation
    the e- are re-promoted into the conduction band
    where some recombine with the Eu3 ions and emit
    a blue-green (400-500 nm) visible light (VL)

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 295.
19
Computed Radiography (CR) System (1)
  • Imaging plate (IP) made of PSP is exposed
    identically to SF radiography in Bucky
  • IP in CR cassette taken to CR reader where the IP
    is separated from cassette
  • IP is transferred across a stage with stepping
    motors and scanned by a laser beam (700 nm)
    swept across the IP by a rotating polygonal
    mirror
  • Light emitted from the IP is collected by a
    fiber-optic bundle and funneled into a
    photomultiplier tube (PMT)
  • PMT converts VL into e- current

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 294.
20
Computed Radiography (CR) System (2)
  • Electronic signal output from PMT input to an ADC
  • Digital output from ADC stored
  • Raster swept out by rotating polygonal mirror and
    stage stepping motors produces I(t) into PMT
    which eventually translates into the stored
    DV(x,y) PMT?ADC?RAM
  • IP exposed to bright light to erase any remaining
    trapped e- (50)
  • IP mechanically reinserted into cassette ready
    for use
  • 200mm and 100mm pixel size - (14x17 1780x2160
    and 3560x4320, respectively)

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 294.
21
Indirect Flat Panel Detectors
  • Use an intensifying screen (CsI) to generate VL
    photons from an x-ray exposure
  • Light photons absorbed by individual array
    photodetectors
  • Each element of the array (pixel) consists of
    transistor (readout) electronics and a
    photodetector area
  • The manufacture of these arrays is similar to
    that used in laptop screens thin-film
    transistors (TFT)

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 301.
22
Charged-Coupled Devices (CCD)
  • Form images from visible light
  • Videocams digital cameras
  • Each picture element (pixel) a photosensitive
    bucket
  • After exposure, the elements electronically
    readout via shift-and-read logic and digitized
  • Light focused using lenses or fiber-optics
  • Fluoroscopy (II)
  • Digital cineradiography (II)
  • Digital biopsy system (phosphor screen)
  • 1K and 2K CCDs used

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., pp. 298-299.
23
Direct Flat Panel Detectors
  • Use a layer of photoconductive material (e.g.,
    a-Se) atop a TFT array
  • e- released in the detector layer from x-ray
    interactions used to form the image directly
  • X-ray?e-?TFT ? ADC?RAM
  • High degree of e- directionality through
    application of E field
  • Photoconductive material can be made thick w/o
    degradation of spatial resolution
  • Photoconductive materials
  • Selenium (Z34)
  • CdTe, HgI2 and PbI2

Indirect Flat Panel Detector (for comparison)
Direct Flat Panel Detector
c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 304.
24
Thin-Film Transistors (TFT)
  • After the exposure is complete and the e- have
    been stored in the photodetection area
    (capacitor), rows in the TFT are scanned,
    activating the transistor gates
  • Transistor source (connected to photodetector
    capacitors is shunted through the drain to
    associated charge amplifiers
  • Amplified signal from each pixel then digitized
    and stored
  • X-ray?VL?e-?ADC?RAM

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 301.
25
Resolution and Fill Factor
  • Dimension of detector element largely determines
    spatial resolution
  • 200mm and 100mm pixel size typical
  • For dimension of a mm - Nyquist frequency FN
    1/2a
  • If a 100mm ? FN 5 cycle/mm
  • Fill factor (light sensitive area)/(detector
    element area)
  • Trade-off between spatial resolution and contrast
    resolution

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 303.
26
Image Digitization and Processing
  • After acquisition and correction of raw data, the
    image is ready for display processing.
  • The image data consists of a matrix of numbers.
    Each pixel is one matrix point. Each gray scale
    is a digital value.
  • For example a matrix can have 1024 x 1024
    pixels and each pixel will have a value from 0 to
    1024. Each value is related to the radiation
    exposure which created that pixel.

27
Digital Storage of Images
  • Usually stored as a 2D array (matrix) of data,
    I(x,y) I(1,1), I(2,1), I(n,m-1), I(n,m)
  • Each minute region of the image is called a pixel
    (picture element) represented by one value (e.g.,
    digital value, gray level or Hounsfield unit)
  • Typical matrices
  • CT 512x512x12 bits/pixel
  • CR 1760x2140x10 bits/pixel
  • DR 2048x2560x16 bits/pixel

c.f. Huang, HK. Elements of Digital Radiology, p.
8.
28
Image Processing
  • Image data is scaled to present image with
    appropriate gray scale (O.D.) values regardless
    of the actual radiation used to produce the
    image.
  • Image data is frequency enhanced around
    structures of importance.
  • Process involves mathematical filters.
  • Image data is display processed to give desired
    contrast and density.
  • Process involves re-mapping along a chosen
    display (HD) curve

29
Generic Display Processing
  • Different manufacturers may use different
    versions of generic image processing methods.
  • E.g. Musica, Ptone
  • All describe means of scaling and modifying image
    appearance.
  • Different manufacturers use different exposure
    indicators.
  • E.g. EI, S, IgM
  • All describe the relationship between the
    exposure to the detector and the pixel value.

30
Generic Elements of Display Processing
  • Exposure Recognition.
  • Adjust for high/low average exposure
  • Signal Equalization
  • Adjust regions of low/high signal value
  • Grayscale Rendition
  • Convert signal values to display values
  • Edge Enhancement
  • Sharpen edges
  • M. Flynn, RSNA 1999

31
Image Processing
32
Computed Radiography (CR) System (3)
  • IP dynamic range 104, about 100x that of S-F
    (102)
  • Very wide latitude ? flat contrast
  • Image processing required
  • Enhance contrast
  • Spatial-frequency filtering
  • CRs wide latitude and image processing
    capabilities produce reasonable OD or DV for
    either under or overexposed exams
  • Helps in portable radiography where the tight
    exposure limits of S-F are hard to achieve
  • Underexposed ? ? quantum mottle and overexposed ?
    unnecessary patient dose

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 296.
33
Unsharpmasked Spatial Frequency Processing
c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 313.
34
Global Processing
  • Most common global image processing window/level
  • Global processing algorithm
  • I(x,y) c I(x,y) a essentially y mx
    b
  • Level (brightness) set by a
  • Window (contrast) set by c
  • I 2N/wwI-wl-(ww/2), where ww window
    width and wl window level
  • Need threshold limits when max/min 2N-1, 0
    digital values encountered
  • If I(x,y) gt Tmax?I(x,y) Tmax
  • If I(x,y) lt Tmin?I(x,y) Tmin

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., pp. 92 and 311.
35
Image Processing Based on Convolution
  • Convolution Ch. 10 - Image Quality and Ch. 13 -
    CT
  • Defined mathematically as passing a N-dimensional
    convolution kernel over an N-dimensional numeric
    array (e.g., 2D image or CT transmission profile)
  • At each location (x, y, z, t, ...) in the number
    array multiply the convolution kernel values by
    the associated values in the numeric array and
    sum
  • Place the sum into a new numeric array at the
    same location

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 312.
36
Image Processing Based on Convolution
  • Delta function kernel
  • Blurring kernel (normalization) also known as
    low-pass filter
  • Edge sharpening kernel

0 0 0
0 1 0
0 0 0
1/9 1/9 1/9
1/9 1/9 1/9
1/9 1/9 1/9
-1 -1 -1
-1 9 -1
-1 -1 -1
c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 313.
37
Image Processing Based on Convolution
  • Convolution kernels can be much larger than 3 x
    3, but usually N x M with N and M odd
  • Can also perform edge sharpening by subtracting
    blurred image from original ? high-frequency
    detail (harmonization)
  • The edge sharpened image can then be added back
    to the original image to make up for some
    blurring in the original image CR unsharpmasking
    - freq. processing
  • The effects of convolution cannot in general be
    undone by a de-convolution process due to the
    presence of noise, but a deconvolution kernel can
    be applied to produce an approximation 19F MRI

38
Median and Sigma Filtering
  • Convolution of an image with a kernel where all
    the values are the same, e.g. (1/NxM),
    essentially performs an average over the kernel
    footprint
  • Smoothing or noise reduction
  • This can make the resulting output value
    susceptible to outliers (high or low)
  • Median filter rank order values in kernel
    footprint and take the median (middle) value
  • Sigma filter set sigma (s) value (e.g., 1) and
    throw out all values in kernel footprint gt m s
    or lt m s and then take the average and place in
    output image

39
Multiresolution/Multiscale Processing and
Adaptive Histogram Equalization (AHE)
  • Some CR systems (Agfa/Fuji) make use of
    multiresolution image processing (AKA
    unsharpmasking) to enhance spatial resolution
  • Wavelet or pyramidal processing on multiple
    frequency scales
  • Histogram equalization re-distributes image
    digital values to uniformly span the entire
    digital value range 2N-1,0 to maximize contrast
  • AHE does this on a spatial sub-region basis in an
    image rather than the entire image
  • Fuji Dynamic Range Control (DRC) a version of
    AHE that operates on sub-regions of digital values

40
Histogram Equalization
Properly Exposed Image
Over-exposed Image
Under-exposed Image
Histogram Equalized Image
c.f. http//www.wavemetrics.com/products/igorpro/i
mageprocessing/imagetransforms/histmodification.ht
m
41
Global and Adaptive Histogram Equalization
The following images illustrate the differences
between global and adaptive histogram
equalization.
MR image with the corresponding gray-scale
histogram. The histogram has a peak at minimum
intensity consistent with the relatively dark
nature of the image.
Global histogram equalization and the final
gray-scale histogram. Comparing the results with
the figure above we can see that the distribution
was shifted towards higher values while the peak
at minimum intensity remains.
Adaptive histogram equalization shows better
contrast over different parts of the image. The
corresponding gray-scale histogram lacks the
mid-levels present in the global histogram
equalization as a result of setting a high
contrast level.
c.f. http//www.wavemetrics.com/products/igorpro/i
mageprocessing/imagetransforms/histmodification.ht
m
42
Contrast vs. Spatial Resolution in Digital Imaging
  • S-F mammography can produce images w/ gt 20 lp/mm
  • According to Nyquist criterion would require 25
    mm/pixel resulting in a 7,200 x 9,600 image (132
    Mbytes/image)
  • Digital systems have inferior spatial resolution
  • However, due to wide dynamic range of digital
    detectors and image processing capabilities,
    digital systems have superior contrast resolution

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 315.
43
Digital Imaging Systems and DQE
  • Remember the equation for DQE(f)?
  • DQE(f)
  • How can we account for this?
  • Both CR and the screens in film/screens made thin
  • Film higher spatial resolution than CR
  • DQE higher for a-Si systems using CsI and Gd2O2S
    rather than a-Se (mean x-ray E Z)
  • a-Si DQE falling off more rapidly than a-Se
    (geometry)

a-Si DR
a-Se DR
44
Digital versus Analog Processes Implementation
  • Although some of the previous image reception
    systems were labeled digital, the initial stage
    of those devices produce an analog signal that is
    later digitized
  • CR x-rays?VL?PMT?current?voltage?ADC
  • CCD, direct indirect digital detectors stored
    e- ? ADC
  • Benefits of CR
  • Same exam process and equipment as screen-film
    radiography
  • Many exam rooms serviced by one reader
  • Lower initial cost
  • Benefits of DR
  • Throughput ? radiographs available immediately
    for QC read

45
Patient Dose Considerations
  • Over and underexposed digital receptors produce
    images with reasonable OD or gray scale values
  • As overexposure can occur, need monitoring
    program
  • CR IP acts like a 200 speed S-F system wrt. QDE
  • Use the CR sensitivity (S) number to track dose
  • Bone, spine and extremities 200
  • Chest 300
  • General imaging including abdomen and pelvis
    300/400
  • Flat panel detectors can reduce radiation dose by
    2-3x as compared with CR for the same image
    quality due to ? quantum absorption efficiency
    conversion efficiency

46
Using the CR Sensitivity Number to Track Dose
47
Huda Ch6 Digital X-ray Imaging Question
  • 12. Photostimulable phosphor systems do NOT
    include
  • A. Analog-to-digital converters
  • B. Barium fluorohalide
  • C. Light detectors (blue)
  • D. Red light lasers
  • E. Video cameras

48
Huda Ch6 Digital X-ray Imaging Question
  • 11. Which of the following x-ray detector
    materials emits visible light
  • A. Xenon
  • B. Mercuric iodide
  • C. Lead iodide
  • D. Selenium
  • E. Cesium iodide

49
Raphex 2002 Question Digital Radiography
  • D47. Concerning computed radiography (CR), which
    of the following is true?
  • A. Numerous, small solid-state detectors are used
    to capture the x-ray exposure patterns.
  • B. It has better spatial resolution than film.
  • C. It is ideal for portable x-ray examinations,
    when phototiming cannot be used.
  • D. It is associated with high reject/repeat
    rates.
  • E. The image capture, storage, and display are
    performed by the receiver.

50
Huda Ch6 Digital X-ray Imaging Question
  • 13. Photoconductors convert x-ray energy
    directly into
  • A. Light
  • B. Current
  • C. Heat
  • D. Charge
  • E. RF energy

51
Huda Ch6 Digital X-ray Imaging Question
  • 15. Which of the following does NOT involve image
    processing
  • A. Background subtraction
  • B. Energy subtraction
  • C. Histogram equalization
  • D. K-edge filtering
  • E. Low-pass filtering

52
Huda Ch6 Digital X-ray Imaging Question
  • 14. Processing a digital x-ray image by
    unsharpmask enhancement would increase
    the
  • A. Bit depth per pixel
  • B. Matrix size
  • C. Patient dose
  • D. Visibility of edges
  • E. Limiting spatial resolution

53
Adjuncts and other interesting stuff
54
Geometric (Linear) Tomography
  • With the advent of CT, geometric tomography has
    only limited clinical utility where only one or a
    few planes of objects with high contrast are
    desired, e.g., IVP
  • Desired slice through patient set at pivot point
    (focal plane)
  • The tomographic process blurs out regions outside
    the focal plane, but still contributes to overall
    loss of contrast
  • Larger tomographic angles result in a lessening
    of out of plane contributions
  • High dose, comparable to CT for many tomographic
    slices

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 318.
55
Digital Tomosynthesis
  • Improved version of geometric tomography where a
    digital detector saves an image at each of
    several tube angles
  • This allows reconstruction of multiple planes
    through the object through shifting the various
    images through a certain distance before summing
    them
  • Much more dose efficient, but still suffers from
    out of plane blurring effects
  • Either CR or DR used

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 320.
56
Temporal Subtraction
  • Digital Subtraction Angiography (DSA) usually
    1K resolution
  • Mask (background) subtracted from images
    during/post contrast injection ? lt 1 trans.
    visualized
  • Motion can cause misregistration artifacts
  • Digital value proportional to contrast
    concentration and vessel thickness
  • Is ln(Im) ln(Ic) mvessel tvessel
  • Temporal subtraction works best when time
    differences between images is short
  • Possible to spatially warp images taken over a
    longer period of time

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 322.
57
Dual-Energy Subtraction
  • Exploits differences between the Z of bone (Zeff
    13) and soft tissue (Zeff 7.6)
  • Images taken either at two different kVp
    (two-shot)
  • One image (one-shot) taken with energy separation
    provided by a filter (sandwich)
  • Iout loge(Ilow) R loge(Ihigh), where R is
    altered to produce soft-tissue predominant or
    bone predominant images
  • GE Chest DR _at_ SCCA

c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 324.
58
Dual-Energy Subtraction
c.f. Bushberg, et al. The Essential Physics of
Medical Imaging, 2nd ed., p. 325.
59
Huda Ch6 Digital X-ray Imaging Question
  • 22. The matrix size in a DSA image is
    typically
  • A. 128 x 128
  • B. 256 x 256
  • C. 512 x 512
  • D. 1024 x 1024
  • E. 2048 x 2048

60
Huda Ch6 Digital X-ray Imaging Question
  • 25. Changing the DSA matrix from 10242 to 20482
    would NOT increase the
  • A. Data digitization rate
  • B. Data storage requirement
  • C. Image processing time
  • D. Spatial resolution
  • E. Pixel size

61
Raphex 2003 Question Digital Radiography
  • D51. A flat panel digital radiographic detector
    has a square 20 x 20 cm image receptor field. The
    full field of the detector is coupled to a
    nominal 2048 x 2048 CCD array. The relative
    spatial resolution (lp/mm) when going from a 20 x
    20 cm to a 10 x 10 cm field of view is
  • A. Four times better
  • B. Twice as good
  • C. The same
  • D. Half as good
  • E. One fourth as good

62
Huda Ch6 Digital X-ray Imaging Question
  • 17. The Nyquist frequency for a 1K digital
    photospot image (25 cm image intensifier
    diameter) is
  • A. 1 lp/mm
  • B. 2 lp/mm
  • C. 4 lp/mm
  • D. 8 lp/mm
  • E. 10 lp/mm
  • FN (lp/mm) 1/2a 1/2(1024 lines/250 mm)
    2.048 2

63
Digital Representation of Data (1)
  • Bits, Bytes and Words
  • Smallest unit of storage capacity 1 bit (binary
    digit 1 or 0)
  • Bits grouped into bytes 8 bits byte
  • Word 16, 32 or 64 bits, depending on the
    computer system addressing architecture
  • Computer storage capacity is measured in
  • kilobytes (kB) - 210 bytes 1024 bytes ? a
    thousand bytes
  • megabytes (MB) - 220 bytes 1024 kilobytes ? a
    million bytes
  • gigabytes (GB) - 230 bytes 1024 megabytes ? a
    billion bytes
  • terabytes (TB) - 240 bytes 1024 gigabytes ? a
    trillion bytes

64
Digital Representation of Data (2)
  • Digital Representation of Different Types of Data
  • Alphanumeric text, integers, and non-integer data
  • Storage of Positive Integers
  • In general, n bits have 2n possible permutations
    and can represent integers from 0 to 2n-1 (the
    range usually denoted with square brackets)
  • n bits represents 2n values with range 0, 2n-1
  • 8 bits represents 28 256 values with range 0,
    255
  • 10 bits represents 210 1024 values with range
    0, 1023
  • 12 bits represents 212 4096 values with range
    0, 4095
  • 16 bits represents 216 65,536 values with range
    0, 65535

65
Conversion of Analog Data to Digital Form
  • The electronic measuring devices of medical
    scanners (e.g., transducers and detectors)
    produce analog signals
  • Analog to digital conversion (analog to digital
    converter ADC)
  • ADCs characterized by
  • sampling rate or frequency (e.g., samples/sec 1
    MHz)
  • number of bits output per sample (e.g., 12
    bits/sample 12-bit ADC)

c. f. Bushberg, et al., The Essential Physics of
Medical Imaging, 2nd ed., p. 69.
66
Periodic Table of the Elements
c.f. http//www.ktf-split.hr/periodni/en/
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