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Resident Physics Lectures

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Resident Physics Lectures Christensen, Chapter 15 Geometry of the Radiographic System George David Associate Professor Department of Radiology Medical College of Georgia – PowerPoint PPT presentation

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Title: Resident Physics Lectures


1
Resident Physics Lectures
  • Christensen, Chapter 15
  • Geometry of the Radiographic System

George David Associate Professor Department of
Radiology Medical College of Georgia
2
Similar Triangle Review
a b c h---- --- --- --- A
B C H
3
Magnification Defined
FocalSpot
  • size of image
  • --------------------size of object

Object
Film (image)
4
Using Similar Triangles
FocalSpot
size of image Magnification
-------------------- size of object
h
H
Object
Film (image)
  • focus to film
    distance HMagnification
    ---------------------------------- ---
    focus to object distance
    h

5
Using Similar Triangles
FocalSpot
size of image Magnification
-------------------- size of object
h
  • focus to film
    distance Hmagnification
    ---------------------------------- ---
    focus to object distance
    h

H
Object
Film (image)
SO
focus to film dist.size of image size of
object X ---------------------------------

focus to object dist
6
Optimizing Image Quality

focus to film
distance Hmagnification
---------------------------------- ---
focus to object distance
h
FocalSpot
h
H
Object
Film (image)
  • Minimize magnification
  • Minimize object-film distance
  • Maximize focal-film distance

7
Automatic Artifact
  • Occurs whenever we image a 3D object in 2D
  • Work-around
  • Multiple views

?
?
8
Distortion Types
minimal distortion when object near central beam
close to film
9
Penumbra
  • Latin for almost shadow
  • also called edge gradient
  • region of partial illumination
  • caused by finite size of focal spot
  • smears edges on film
  • zone of unsharpness called
  • geometric unsharpness
  • penumbra
  • edge gradient

Line sourcefocal spot
Film Image
10
Penumbra Calculation
  • Minimizing Penumbra
  • Minimize object-film distance (OID)
  • Maximize source-object distance (SOD)
  • Makes focal spot appear smaller
  • Minimize focal spot size

F
Line sourcefocal spot
SOD
Object
SID
OIDP F x ------- SOD
OID
P
11
Motion Unsharpness
  • Caused by motion during exposure of
  • patient
  • tube
  • film
  • Effect
  • similar to penumbra
  • Minimize by
  • immobilizing patient
  • short exposure times

12
Absorption Unsharpness
  • Cause
  • gradual change in x-ray absorption across an
    objects edge or boundary
  • thickness of absorber presented to beam changes
  • Effect
  • produces poorly defined margin of solid objects

X-RayTube
X-RayTube
X-RayTube
13
Inverse Square Law
  • intensity of light falling on flat surface from
    point source is inversely proportional to square
    of distance from point source
  • if distance 2X, intensity drops by 4X
  • Assumptions
  • point source
  • no attenuation
  • Cause
  • increase in exposure area with distance

Intensity a 1/d2
d
14
Trade-offGeometry vs. Intensity
F
  • maximize SID to minimize geometric
    unsharpness but
  • doubling SID increases mAs by X4
  • increased tube loading
  • longer exposure time
  • possible motion
  • going from 36 to 40 inch SID requires 23 mAs
    increase

SOD
SID
OID
P
15
Magnification Types
  • Geometric Magnification
  • assumes point source
  • calculated from similar triangles
  • True Magnification
  • takes into account finite size of focal spot
  • focal spot is area (not point) source

16
Magnification
m geometric magM true mag
a
b
17
True Magnification
m geometric magM true mag
  • Function of ratio of focal spot to object size (f
    / d)
  • true geometric magnification equal only when
    object very large compared to focal spot

f
a
d
b
Mm (m-1) X (f / d)
18
Focal Spot Size Tolerances
Nominal Size Tolerance ------------------------
------------- gt1.5 mm
30 gt0.8 and lt1.5 mm 40 lt0.8 mm
50
Focal spot that measures 1.1 mm can be legally
labeled as a 0.8 mm
19
Measuring Focal Spot Size
  • Standard
  • slit camera (as used for line spread function)
  • Orientation and intensity distribution measured
    with
  • pinhole camera
  • Limit of resolution measured with
  • star test pattern
  • line bar phantom

20
Slit Camera
  • .01 mm wide slit cut in metal (tungsten)
  • 2 exposures made with slit turned 90o
  • Measure slit width in each direction

SlitCamera
Film (no screen)
21
Pinhole Camera
  • very small hole in metal (tungsten / tantalum)
  • high technique (sometimes several exposures)
    required
  • image shows
  • size
  • energy distribution

PinholeCamera
Film (no screen)
22
Focal Spot Intensity Distributions
  • edge band distribution
  • also called bi-modal
  • edges have higher intensity than center
  • most common
  • poorest resolving power for size
  • homogeneous distribution
  • centrally peaked (Gaussian) distribution
  • best resolving power for size
  • most like point source

23
Star Pattern
  • Measures resolving power
  • Tool
  • circular
  • alternating lead spokes blanks
  • image of spokes blurs at particular diameter
  • blur diameter indicates focal spot size

24
Bar Phantom
  • Measures resolving power
  • look for smallest bar set where all three bars
    visible in both directions

25
Bar Phantom Setup
Who is this?
26
The Rise Fall of Joe Camel
27
Focal Spot Size Varies with Technique
  • Electron beam focuses more poorly at high mA or
    low kV
  • Blooming
  • increase of focal spot size with increasing mA
  • more of a problem at low kVs
  • more blooming perpendicular to cathode-anode axis
  • kilovoltage effects
  • size decreases slightly with increasing kVp
  • size always measured specified at particular
    technique

28
Off-Axis Variation
  • focal spot measurements normally made on central
    ray
  • apparent focal spot size changes in anode-cathode
    direction
  • smaller toward anode side
  • larger toward cathode side
  • less effect in cross-axis direction

29
Focal Spot Size
  • Trade-off
  • heat vs. resolving power
  • exposure time vs. resolving power
  • Focal Spot Size most critical for
  • magnification
  • mammography

30
Modulation Transfer Function (MTF)
  • How well information reproduced (fraction of
    contrast retained) at various input spatial
    frequencies

31
Modulation Transfer Function(MTF)
  • Fraction of contrast reproduced as a function of
    frequency

Freq. line pairs / cm
1
MTF
50
Recorded Contrast(reduced by blur)
Contrast provided to film
0
frequency
32
MTF
  • If MTF 1
  • all contrast reproduced at this frequency

Recorded Contrast
Contrast provided to film
33
MTF
  • If MTF 0.5
  • half of contrast reproduced at this frequency

Recorded Contrast
Contrast provided to film
34
MTF
  • If MTF 0
  • no contrast reproduced at this frequency

Recorded Contrast
Contrast provided to film
35
Modulation Transfer Function (MTF)
  • value between 0 and 1
  • MTF 1 indicates all information reproduced at
    this frequency
  • MTF 0 indicates no information reproduced at
    this frequency

36
Component MTF
  • Each component of imaging system has its own MTF
  • each component retains a fraction of contrast as
    function of frequency
  • System MTF is product of MTFs for each component.

37
Modulation Transfer Function (MTF)
  • Since MTF is between 0 and 1, composite MTF lt
    MTF of poorest component

1/2 1/3 1/4 1/5 ?
? lt 1/5
38
Film MTF
  • Resolves 10-20 line pairs per mm
  • MTF 1 for clinical applications

39
Focal Spot MTF
  • Function of magnification
  • Deteriorates with increased magnification
  • all clinical imaging involves some magnification
  • The larger the focal spot, the more deterioration
    of MTF with increased magnification

40
Imaging Screen MTF
  • improves with magnification
  • Why?
  • magnification of an object of given frequency
    reduces frequency seen by screen

41
Focal Spot Screen MTF
  • focal spot MTF degrades with magnification
  • screen MTF improves with magnification
  • film MTF unaffected with magnification
  • best system resolution
  • detail screens
  • minimize magnification
  • BUT detail screens decrease speed
  • increase exposure time
  • more potential for motion

42
Imaging Physics Wrap Up
43
Object Motion
  • independent of magnification
  • depends on
  • exposure time
  • velocity
  • If motion lt 0.1 mm usually doesnt contribute to
    unsharpness
  • If motion gt 1 mm, it generally dominates

44
Quantum Mottle
  • statistical fluctuation in of x-ray photons
    used by imaging system to form image
  • quantum mottle independent of geometric
    (radiographic) magnification
  • for a given density the same of photons must
    strike a given area of screen/film

45
Quantum Mottle
  • quantum mottle directly affected by photographic
    (optical) magnification
  • less photons per unit area of image

46
Quantum Mottle
  • influences perception of low-contrast objects
    with poorly defined borders
  • not well addressed by MTF
  • measures sharp high contrast borders
  • geometric (radiographic) magnification may
    improve visibility of low contrast objects
  • quantum mottle noise does not increase

47
Skin Exposure Magnification
48
Skin Exposure Magnification
  • Patient closer to x-ray tube
  • Increases exposure
  • grids not used with magnification work because of
    air gap
  • Decreases exposure
  • No bucky factor loss (3-6)

Grid
Film
49
Skin Exposure Magnification
  • Increase is less than calculated by inverse
    square law
  • for 2X mag skin not twice as close
  • routine radiography also involves some
    magnification
  • smaller volume of patient exposed
  • high speed screen/film sometimes used for
    magnification

Grid
Film
50
You Must Remember This
Ilse, well always have physics.
The End
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