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Micro-computer system for quantitative image analysis of damage microstructure
619
Journal of Nuclear Materials 122 & 123 (1984) 619-623 North-Holland, Amsterdam
MICRO-COMPUTER
SYSTEM
FOR QUANTITATIVE
IMAGE
ANALYSIS
Akira
Yutaka
KOHNO,
SATOH
and
KOHYAMA.
Department JAPAN
of Materials
Katsuhiko
University
Science,
OF DAMAGE
Naohiro
of Tokyo.
MICROSTRUCTURE
IGATA
Hongo
7-3-1,
Bunkyo-ku,
Tokyo
113,
Quantitative image analysis of radiation induced damage microstructure is very important in evaluating material behaviors in radiation environment. But, quite a few improvement have been The objective of this seen in quantitative analysis of damage microstructure in these decades. work is to develop new system for quantitative image analysis of damage microstucrure which could improve accuracy and efficiency of data sampling and processing and could enable to get new information about mutual relations among dislocations, precipitates, cavities, grain In this system, data sampling is done with X-Y digitizer. The cavity boundaries, etc.. microstructure in dual-ion irradiated 316 SS is analyzed and the effectiveness of this system is discussed.
from
1. INTRODUCTION Quantitative
image
microstructure material
is very
behaviors
reactors.
The
analysis important
in
both
fission
quantitative for
as quantitative
metallography19'
based to
and
soft-
analyses
the
and
have
analysis
have
The
objective
compact
and
image
analysis
could
improve
sampling to get among
of
and new
of damage
dislocations,
as
damage
analyzing
to
used.
develop
which
and
of
could
mutual
precipitates,
data
enable
relations
control
hard
is
2.1.
OF THE
System
Hardwares Fig.1. The
microcomputer keyboard
in
and
monitor
Physics
system
are
Electric CRT.
outlined
device
For
in
is PC-8801
Co.,Ltd. ) with data
aquisition
0 Elsevier Science Publishers Publishing Division)
B.V.
the
University ) is
used
system
through coupler
In most
TV
step it
camera of
experiences. for
cavity
and
on
multi-
hard
printing For
building
up
machine
in
M-280H
with
linkage
VOS3
with
our
system
with
by 300 baud.
signal
VTR
damage
are
image
input
devices
adopted
as
aquisition, to
on
make
but
they
are
in
delicate which
plenty
analyzers
the
but
photomicrograph
based
measurements,
getting
general-purpose
data
Particle
For
is and
or
impossible
judged
bytes
printer.
communication
or
2M
data,
and
data
the
RS232C
the
mainframe
( HITAC
figure
is almost
usualy
of
analogue-video
interpretation is
and
advanced
under
storage
matrix
the
under
the
about
on-
picked
8" floppy
programs.
volume
of Tokyo
system
as
of
dot
huge
file
pointer
of analyzed
libraries,
them
processing
( Nippon
0022-3 11_5/84/$03.00
(North-Holland
this
by
and
are
program.
is linked,
processing
first
SYSTEM
the
data
of control
data
sound
of
capacity
copies
) is directly
Y coordinates
aquisition
plotter
Houston
of PC-8801.
auxilliary
analyzers.
Hardwares
central
X-Y
HIPAD
bus
X and
with
realized
such 2. OUTLINE
DT-11, data
data
graphic
color
X-Y digitizer(
handling
of
preservation
cavities,
etc..
of
up by manual
for
for quantitative
about
values
system
efficiency
processing
board
used
being
is
Model to the
disk
microstructure and
informations
grain-boundaries,
work
instruments connected
general
But,
and
dominantly
of
photographs,
computer-
induced
system
accuracy data
for
established.
this
inexpensive
fusion
developed
and
counting
been
and
been
radiation
visual
still
has
hard-wares
been
of
microstructures, methods
metals
damage
analysis
microstructures
methods
of
in evaluating
TEM
human also
only
used
measure
620
I
DATA
.
L BJock
cavities every
diagram
of system
as 'spherical
cases.
method
At
using data
high
performance.
cost
2.2. System
input
system
which
is
utilized
FILE is
measurement data
sequential
on experimental positional
random 'dpa', 'cavity
FILE. file
measured
file,
'swelling', number
distribution',
the
in
FILE,
very
in our case
Fig.2.
density',
experimental
Three work
ANALYZED-DATA
are
results
stored.
to
FILE
hardware
control
system. to
ProgramCO~TROi
FILE
i.e., photo-data
data
DATA
and
raw
data
cavity
by X-Y type such
data
controls
as
first
size and
or
data
of file-heading name, name,
date
and
this
place
of
files.
ANALYZEDFILE
Program
photographs
input
which
menu
is executed,
PHOTO-DATA
or
TABLET on
X-Y
FILES.
At
procedure
contains
experiment,
number.
other
programs
data
making
program.
is prompted
photo-plate
possible
in which
action
program,
system
for
main
generating
from
and generates
in starting
are
Serializes-DATA
work
input
and
three
or
from
in our
program
aquisition making
to another
digitizer
diameter',
'cavity condition
FILE
of
their
of successive
involves
is
are
dpa,
FILES.
if necessary,
is main
PHOTO-DATA
FILE
language
There
some
versus
generated
programs
modified,
corresponding
jumping
is
data
ANALYZED-DATA
in BASIC
be easily
of comparing
swelling
object
all
microstructures
In case
SERIALIZED-DATA corresponding
sellection
digitized
of damage
or arranging
and
and analyzed 'average
of
by
on a photograph
ANALYZED-DATA
access
in
in
generated
conditions
data
digitizer.
in
are
and SERIALIZED-DATA of
and
structure
is shown
files
e.g. PHOTO-DATA
type
better
so on
are written
software
programs
is
input
Softwares of
of
in almost
manual
analysis
Almost
scheme
types
type
our
application
The
swelling
FIGURE 1 in quantitative image
hardwares
digitizer
flexible
-I
-_---_-----_
shaped'
present,
X-Y
STORE -.
w-w-
file
sample
irradiation
A. Kohyama
et al. /Micro-computer
system for quantitative
of this data
general program control
in
figures
calculated
[PHOTOGRAPHI
In ANALYSIS,
routine.
of
and
parameters
print
magnification
cavity
number
DATA
and
measured
TEM
foil
messages.
Then,
figure-input input
'circle',
are
picks
digitizer. 'circle' Picked
FILE
Program
FILES
from
order
PHOTO-DATA
ordinary versioned
of
use
in
ANALYSIS
figure-
on
input and
into with
their
is called
standpoints.
Programs
DATA
FILES.
can
same
time.
measurement, at
the
handle For non-
beginning
each
inspect
the
output
the
file
such
as
be shown
material
and
stored
FILE.
By
results
FILE, FILE
as this from
and SDF-OUT
of CONTROL to
and
irradiation
rate,
ADF-OUT
data
another
parameters
PHOTO-DATA
managememt
are
ANALYZED-
course,
swelling
PDF-OUT, to call
dose
etc.
object
Of
FILE and SERIALIZED-DATA
under
have
ANALYZED-
respectively
program
monitor
CRT
and to or
dot
printer.
3. APPLICATIONS 3.1. Two-step
TO CAVITY Separate
MEASUREMENTS Cavity
Counting
Method
their
ANALYZED-DATA
which
cavity
various
PHOTO-
figure
can
of a
cavity
density
SERIALIZED-DATA
we
ordinarily.
PHOTO-DATA
the
the
can
results
example,
displacement etc.
to produce
average
number
the
be also
of ANALYZED-
the
For
variables
specific
functions
used
into
and
can
a set
swelling
program
measurement,
produces
at
'dot',
mode,
figures
stored
a version
of
'polygon'
is used
number
FILES
and
cavity
are
ANALYSIS
has
five
sellected
corresponding
program
plural
of
one
i.e.,
of
mode
of points
cavity
modes.
the
points
case
in
sequential
This
to
short
sellect
'line'
or 'polygon' up data
can
supported
up
In
and
In TABLET,
'ellipse',
operator
DATA
operator
According
modes.
thickness
modes.
modes
photo-plate
magnification,
from
program.
of
experimental
is
usualy
accessing
volume
stored
program,
swelling,
by this
composition, displacement,
this
SERIES
cavity
through
FILE
and
of
diameter,
cavity
distribution
are
of
cavity
and
experiment.
combinations
the
by
FILE
those
temperature,
photo-print
average
size
Program
of
gotten
total
Values
FILE
FILES
diameter
temperature,
on.
so
calculated
round
magnification,
and
are
dependences
in
photo-
density,
SERIALIZED-DATA
utilized
values
and
also
real
are
data
fraction
DATA
FILE
mode
volume
generated.
FIGURE 2 structure
to
cavity
of cavity
coordinate
i.e. figure
average
ANALYZED-DATA
raw
PHOTO-DATA
converted
using
diagram
Scheme of software swelling measurement
621
image analysis
In heavily in
dual-ion
steel,
irradiated
bi-modal
cavity
frequently
observed?14
number
smaller
of
relatively appropriate photographs.
materials,
irradiated
larger
Type size
In these
cavities
measured case,
stainless
distributions
cavities
In this
especially
316
cases
and
are area a
on very
a huge
number
counted
are
of
in the
the
TEM
long
time
622
A. Kohyama et al. / Miero~om~utersystem
(1)
for q~ant~t~iive image analysis
TWO-STEP SEPARATE CAVITY COUNTING METHOD N,
'= N1
Ns: number of small Nl: number of large C Xs: population of C Xl: populatfon of Vh: sampling volume Vl: sampling volume (2)
SINGLE STEP CAV TY COUNTING
FIGURE 3 separate cavity
Schematic representation of two-step cavities with bi-modal size distribution
must the
be consumed accuracy
cavities sizes
of
is on
raising
are
are
bi-modal
cavity TEM
cavities.
In
counting
largrer
separate
through
this
3
with
shows
method,
with that
cavities
a
is
for
extensively
different
of both are
two
larger
extremely
two-step
in
error
usual
measurement
errors
relative
of
was
from
By
single
sampling smaller
are
numbers cavities to this
counting
method,
cavity
caused
volume
treatment
under This
counted
and
equal.
to about12%
method
error
increase
be
to statistical
assumed.
to
According
cavity
counting
in statistical
cavities.
and
reduced
larger
populations
in calculated
was
of
adjusted statistical
method
because
cavities
attributed
data
to
different.
of
cavitities
statistical
separate
generated
that
made
counting
such
for
larger
these
usual
are
larger
are
photograph,
cavity
relatively
on
of
numbers
means
both
cavities
fraction
is for
of
measurement
cavities
This
equal.
populations
for
counted
or smaller
become
means
method
total
photographs,
two
the appropriate
and the other
than
of
separate
One
prepaired.
these
access
counting
smaller
absolute
two-step
cavities
magnification
For
instead, in thier
two-step
For
magnification,
tiny
enlarged
Figure
cavities
smaller
their
for measuring
of
method. are
larger
photo-print
higher
system,
FILES.
photographs
counting
counting
but
representation
counting
of
(usual method)
cavities
smaller
further
distributions
SERIALIZED-DATA
of
and
photographs.
is possible
cavity
schematic
because TEM
counted
our
cavities,
sizes
measured,
counting
all
accuracy,
poorly
Using
number.
poor
object
their
photographs
cavity
measured
very
the up
cavities
for counting
size cavity size cavity small size cavity large size cavity (high ~8nification) (low magnification)
from
of 31%
typical
improvement mainly
number
of
from larger
623
A. Kohyama et al. /Micro-computer system for quantitative image analysis 3.3. Trace
of
accompanied that If
Individual
PHOTO-DATA
In
by
they
are
their
of
photographs, of
total
I
1
I
I
1
size.
In
some
'45678! Electron
Dose
FIGURE
(@a)
of cavity
4
Example of dose dependence of individual cavity radius in solution annealed and aged Type 316 SS electron irradiated at 500 C followed to 6 dpa dual-ion irradiated at 600 C
to be
Volume
spherical Larger
growth
rates.
cavities
there
is no clear
even
in
spherical
definition
smaller
than
distributionfg6
cavities
are
as their
'diameters',
cavities
size
cavity
and
volume
distribution
system,
as
input cavities
is
previously
mode
is
are
manner
with conventional
volume
fraction
measuring
In
This to
be
extremely
rod-shaped,
very
those
then
based
or
cavity In
by tracing
their
our
exact cavity
10% accurate measurement
effective
especially
non-spherical much
our
'polygon'
non-spherical
comparison
about
of
on these
calculated,
exact
very
regarded
one, calculated
became
manner.
considered
as
are.
non-
of circles to
and
'size'
measured
are
equal
measured
as
our
which
mentioned,
forms
its
usual,
fraction
supported
exactly
they
In
or diameters
nearly
by eyesight,
'diameters'
cavity,
conventionally
diagonals
are
on
rate
not
as
the and
little grow
with
more
additive
grow
are
found
size
for
bias-
from
bi-modal
This theoretical
the
the
cavity
represented,
obtained
supports
number
4 shows
cavities
can
the size
editing
exhibit
the critical
growth
et a1.7
growth
By examining
size
Hishinuma
Figure
larger
cavity
by
cavity
of individual
is also
which
on the
bimodal
feature analysis cavity
of
size
facetted
about
5
standards.
longest
areas
present
For non-spherical
in their
whose
Non-
cavity
cavities
driven
photograph. done
to trace
specific
stored
in order
distribution.
frequently
shapes.
ASTM
of
Cavity
cavities
pal ygonal
Estimation
is
of
size
smaller
quantitatively 3.2.Exact
TEM
cavity
instead,
results,
from
dependence
Fig.4,
of
changes,
,
FILE
are
numbers
cavity
displacements.
of dose
fuction
up
individual
example
sizes
serial
each
Growth
data
it is possible
SERIALIZED-DATA along
Cavity
cavity
picked
numbering
change
FILE
truncated,
cavity, etc..
in is in such
REFERENCES T. An, S. Ishino, Y. Mishima and 1. S. Iwata, T. Moroyama, Annual Report of the Engineering Research Institute, Faculty of Engineering, University of Tokyo, Vo1.40, (1981) pp.lOl-106. 2. N. Igata. Abstracts Institute
Y. Kohno, A. Kohyama and K. Satoh, for the 92nd Meeting of Japan of Metals, (1983) p.157.
G. Ayraultand B.A. Loomis, DAFS 3, A. Kohyama, Quarterly Progress Report, DOE/ER-0046/11, (1982) pp.157-166. 4. A. Kohyama, T. Takeyama Electron California,
Y. Kohno, K. Suzuki, G. Ayrault, and N. Igata, High Voltage Microscopy '83, Berkeley, Aug.7983, 'in print'.
Book of ASTM 5. Annual ‘Nuclear Standards' (1977).
Standards, ANSI/ASTM
6. A. Kohyama, Y. Kohno, K. Suzuki, and N. Igata, this volume. 7. A. Hishinuma and Mater., 'in print'.
L.K.
Mansur,
Part 45, E521-77,
G. Ayrault
J.
Nucl.
Journal of Nuclear Materials 122 & 123 (1984) 619-623 North-Holland, Amsterdam
MICRO-COMPUTER
SYSTEM
FOR QUANTITATIVE
IMAGE
ANALYSIS
Akira
Yutaka
KOHNO,
SATOH
and
KOHYAMA.
Department JAPAN
of Materials
Katsuhiko
University
Science,
OF DAMAGE
Naohiro
of Tokyo.
MICROSTRUCTURE
IGATA
Hongo
7-3-1,
Bunkyo-ku,
Tokyo
113,
Quantitative image analysis of radiation induced damage microstructure is very important in evaluating material behaviors in radiation environment. But, quite a few improvement have been The objective of this seen in quantitative analysis of damage microstructure in these decades. work is to develop new system for quantitative image analysis of damage microstucrure which could improve accuracy and efficiency of data sampling and processing and could enable to get new information about mutual relations among dislocations, precipitates, cavities, grain In this system, data sampling is done with X-Y digitizer. The cavity boundaries, etc.. microstructure in dual-ion irradiated 316 SS is analyzed and the effectiveness of this system is discussed.
from
1. INTRODUCTION Quantitative
image
microstructure material
is very
behaviors
reactors.
The
analysis important
in
both
fission
quantitative for
as quantitative
metallography19'
based to
and
soft-
analyses
the
and
have
analysis
have
The
objective
compact
and
image
analysis
could
improve
sampling to get among
of
and new
of damage
dislocations,
as
damage
analyzing
to
used.
develop
which
and
of
could
mutual
precipitates,
data
enable
relations
control
hard
is
2.1.
OF THE
System
Hardwares Fig.1. The
microcomputer keyboard
in
and
monitor
Physics
system
are
Electric CRT.
outlined
device
For
in
is PC-8801
Co.,Ltd. ) with data
aquisition
0 Elsevier Science Publishers Publishing Division)
B.V.
the
University ) is
used
system
through coupler
In most
TV
step it
camera of
experiences. for
cavity
and
on
multi-
hard
printing For
building
up
machine
in
M-280H
with
linkage
VOS3
with
our
system
with
by 300 baud.
signal
VTR
damage
are
image
input
devices
adopted
as
aquisition, to
on
make
but
they
are
in
delicate which
plenty
analyzers
the
but
photomicrograph
based
measurements,
getting
general-purpose
data
Particle
For
is and
or
impossible
judged
bytes
printer.
communication
or
2M
data,
and
data
the
RS232C
the
mainframe
( HITAC
figure
is almost
usualy
of
analogue-video
interpretation is
and
advanced
under
storage
matrix
the
under
the
about
on-
picked
8" floppy
programs.
volume
of Tokyo
system
as
of
dot
huge
file
pointer
of analyzed
libraries,
them
processing
( Nippon
0022-3 11_5/84/$03.00
(North-Holland
this
by
and
are
program.
is linked,
processing
first
SYSTEM
the
data
of control
data
sound
of
capacity
copies
) is directly
Y coordinates
aquisition
plotter
Houston
of PC-8801.
auxilliary
analyzers.
Hardwares
central
X-Y
HIPAD
bus
X and
with
realized
such 2. OUTLINE
DT-11, data
data
graphic
color
X-Y digitizer(
handling
of
preservation
cavities,
etc..
of
up by manual
for
for quantitative
about
values
system
efficiency
processing
board
used
being
is
Model to the
disk
microstructure and
informations
grain-boundaries,
work
instruments connected
general
But,
and
dominantly
of
photographs,
computer-
induced
system
accuracy data
for
established.
this
inexpensive
fusion
developed
and
counting
been
and
been
radiation
visual
still
has
hard-wares
been
of
microstructures, methods
metals
damage
analysis
microstructures
methods
of
in evaluating
TEM
human also
only
used
measure
620
I
DATA
.
L BJock
cavities every
diagram
of system
as 'spherical
cases.
method
At
using data
high
performance.
cost
2.2. System
input
system
which
is
utilized
FILE is
measurement data
sequential
on experimental positional
random 'dpa', 'cavity
FILE. file
measured
file,
'swelling', number
distribution',
the
in
FILE,
very
in our case
Fig.2.
density',
experimental
Three work
ANALYZED-DATA
are
results
stored.
to
FILE
hardware
control
system. to
ProgramCO~TROi
FILE
i.e., photo-data
data
DATA
and
raw
data
cavity
by X-Y type such
data
controls
as
first
size and
or
data
of file-heading name, name,
date
and
this
place
of
files.
ANALYZEDFILE
Program
photographs
input
which
menu
is executed,
PHOTO-DATA
or
TABLET on
X-Y
FILES.
At
procedure
contains
experiment,
number.
other
programs
data
making
program.
is prompted
photo-plate
possible
in which
action
program,
system
for
main
generating
from
and generates
in starting
are
Serializes-DATA
work
input
and
three
or
from
in our
program
aquisition making
to another
digitizer
diameter',
'cavity condition
FILE
of
their
of successive
involves
is
are
dpa,
FILES.
if necessary,
is main
PHOTO-DATA
FILE
language
There
some
versus
generated
programs
modified,
corresponding
jumping
is
data
ANALYZED-DATA
in BASIC
be easily
of comparing
swelling
object
all
microstructures
In case
SERIALIZED-DATA corresponding
sellection
digitized
of damage
or arranging
and
and analyzed 'average
of
by
on a photograph
ANALYZED-DATA
access
in
in
generated
conditions
data
digitizer.
in
are
and SERIALIZED-DATA of
and
structure
is shown
files
e.g. PHOTO-DATA
type
better
so on
are written
software
programs
is
input
Softwares of
of
in almost
manual
analysis
Almost
scheme
types
type
our
application
The
swelling
FIGURE 1 in quantitative image
hardwares
digitizer
flexible
-I
-_---_-----_
shaped'
present,
X-Y
STORE -.
w-w-
file
sample
irradiation
A. Kohyama
et al. /Micro-computer
system for quantitative
of this data
general program control
in
figures
calculated
[PHOTOGRAPHI
In ANALYSIS,
routine.
of
and
parameters
magnification
cavity
number
DATA
and
measured
TEM
foil
messages.
Then,
figure-input input
'circle',
are
picks
digitizer. 'circle' Picked
FILE
Program
FILES
from
order
PHOTO-DATA
ordinary versioned
of
use
in
ANALYSIS
figure-
on
input and
into with
their
is called
standpoints.
Programs
DATA
FILES.
can
same
time.
measurement, at
the
handle For non-
beginning
each
inspect
the
output
the
file
such
as
be shown
material
and
stored
FILE.
By
results
FILE, FILE
as this from
and SDF-OUT
of CONTROL to
and
irradiation
rate,
ADF-OUT
data
another
parameters
PHOTO-DATA
managememt
are
ANALYZED-
course,
swelling
PDF-OUT, to call
dose
etc.
object
Of
FILE and SERIALIZED-DATA
under
have
ANALYZED-
respectively
program
monitor
CRT
and to or
dot
printer.
3. APPLICATIONS 3.1. Two-step
TO CAVITY Separate
MEASUREMENTS Cavity
Counting
Method
their
ANALYZED-DATA
which
cavity
various
PHOTO-
figure
can
of a
cavity
density
SERIALIZED-DATA
we
ordinarily.
PHOTO-DATA
the
the
can
results
example,
displacement etc.
to produce
average
number
the
be also
of ANALYZED-
the
For
variables
specific
functions
used
into
and
can
a set
swelling
program
measurement,
produces
at
'dot',
mode,
figures
stored
a version
of
'polygon'
is used
number
FILES
and
cavity
are
ANALYSIS
has
five
sellected
corresponding
program
plural
of
one
i.e.,
of
mode
of points
cavity
modes.
the
points
case
in
sequential
This
to
short
sellect
'line'
or 'polygon' up data
can
supported
up
In
and
In TABLET,
'ellipse',
operator
DATA
operator
According
modes.
thickness
modes.
modes
photo-plate
magnification,
from
program.
of
experimental
is
usualy
accessing
volume
stored
program,
swelling,
by this
composition, displacement,
this
SERIES
cavity
through
FILE
and
of
diameter,
cavity
distribution
are
of
cavity
and
experiment.
combinations
the
by
FILE
those
temperature,
photo-print
average
size
Program
of
gotten
total
Values
FILE
FILES
diameter
temperature,
on.
so
calculated
round
magnification,
and
are
dependences
in
photo-
density,
SERIALIZED-DATA
utilized
values
and
also
real
are
data
fraction
DATA
FILE
mode
volume
generated.
FIGURE 2 structure
to
cavity
of cavity
coordinate
i.e. figure
average
ANALYZED-DATA
raw
PHOTO-DATA
converted
using
diagram
Scheme of software swelling measurement
621
image analysis
In heavily in
dual-ion
steel,
irradiated
bi-modal
cavity
frequently
observed?14
number
smaller
of
relatively appropriate photographs.
materials,
irradiated
larger
Type size
In these
cavities
measured case,
stainless
distributions
cavities
In this
especially
316
cases
and
are area a
on very
a huge
number
counted
are
of
in the
the
TEM
long
time
622
A. Kohyama et al. / Miero~om~utersystem
(1)
for q~ant~t~iive image analysis
TWO-STEP SEPARATE CAVITY COUNTING METHOD N,
'= N1
Ns: number of small Nl: number of large C Xs: population of C Xl: populatfon of Vh: sampling volume Vl: sampling volume (2)
SINGLE STEP CAV TY COUNTING
FIGURE 3 separate cavity
Schematic representation of two-step cavities with bi-modal size distribution
must the
be consumed accuracy
cavities sizes
of
is on
raising
are
are
bi-modal
cavity TEM
cavities.
In
counting
largrer
separate
through
this
3
with
shows
method,
with that
cavities
a
is
for
extensively
different
of both are
two
larger
extremely
two-step
in
error
usual
measurement
errors
relative
of
was
from
By
single
sampling smaller
are
numbers cavities to this
counting
method,
cavity
caused
volume
treatment
under This
counted
and
equal.
to about12%
method
error
increase
be
to statistical
assumed.
to
According
cavity
counting
in statistical
cavities.
and
reduced
larger
populations
in calculated
was
of
adjusted statistical
method
because
cavities
attributed
data
to
different.
of
cavitities
statistical
separate
generated
that
made
counting
such
for
larger
these
usual
are
larger
are
photograph,
cavity
relatively
on
of
numbers
means
both
cavities
fraction
is for
of
measurement
cavities
This
equal.
populations
for
counted
or smaller
become
means
method
total
photographs,
two
the appropriate
and the other
than
of
separate
One
prepaired.
these
access
counting
smaller
absolute
two-step
cavities
magnification
For
instead, in thier
two-step
For
magnification,
tiny
enlarged
Figure
cavities
smaller
their
for measuring
of
method. are
larger
photo-print
higher
system,
FILES.
photographs
counting
counting
but
representation
counting
of
(usual method)
cavities
smaller
further
distributions
SERIALIZED-DATA
of
and
photographs.
is possible
cavity
schematic
because TEM
counted
our
cavities,
sizes
measured,
counting
all
accuracy,
poorly
Using
number.
poor
object
their
photographs
cavity
measured
very
the up
cavities
for counting
size cavity size cavity small size cavity large size cavity (high ~8nification) (low magnification)
from
of 31%
typical
improvement mainly
number
of
from larger
623
A. Kohyama et al. /Micro-computer system for quantitative image analysis 3.3. Trace
of
accompanied that If
Individual
PHOTO-DATA
In
by
they
are
their
of
photographs, of
total
I
1
I
I
1
size.
In
some
'45678! Electron
Dose
FIGURE
(@a)
of cavity
4
Example of dose dependence of individual cavity radius in solution annealed and aged Type 316 SS electron irradiated at 500 C followed to 6 dpa dual-ion irradiated at 600 C
to be
Volume
spherical Larger
growth
rates.
cavities
there
is no clear
even
in
spherical
definition
smaller
than
distributionfg6
cavities
are
as their
'diameters',
cavities
size
cavity
and
volume
distribution
system,
as
input cavities
is
previously
mode
is
are
manner
with conventional
volume
fraction
measuring
In
This to
be
extremely
rod-shaped,
very
those
then
based
or
cavity In
by tracing
their
our
exact cavity
10% accurate measurement
effective
especially
non-spherical much
our
'polygon'
non-spherical
comparison
about
of
on these
calculated,
exact
very
regarded
one, calculated
became
manner.
considered
as
are.
non-
of circles to
and
'size'
measured
are
equal
measured
as
our
which
mentioned,
forms
its
usual,
fraction
supported
exactly
they
In
or diameters
nearly
by eyesight,
'diameters'
cavity,
conventionally
diagonals
are
on
rate
not
as
the and
little grow
with
more
additive
grow
are
found
size
for
bias-
from
bi-modal
This theoretical
the
the
cavity
represented,
obtained
supports
number
4 shows
cavities
can
the size
editing
exhibit
the critical
growth
et a1.7
growth
By examining
size
Hishinuma
Figure
larger
cavity
by
cavity
of individual
is also
which
on the
bimodal
feature analysis cavity
of
size
facetted
about
5
standards.
longest
areas
present
For non-spherical
in their
whose
Non-
cavity
cavities
driven
photograph. done
to trace
specific
stored
in order
distribution.
frequently
shapes.
ASTM
of
Cavity
cavities
pal ygonal
Estimation
is
of
size
smaller
quantitatively 3.2.Exact
TEM
cavity
instead,
results,
from
dependence
Fig.4,
of
changes,
,
FILE
are
numbers
cavity
displacements.
of dose
fuction
up
individual
example
sizes
serial
each
Growth
data
it is possible
SERIALIZED-DATA along
Cavity
cavity
picked
numbering
change
FILE
truncated,
cavity, etc..
in is in such
REFERENCES T. An, S. Ishino, Y. Mishima and 1. S. Iwata, T. Moroyama, Annual Report of the Engineering Research Institute, Faculty of Engineering, University of Tokyo, Vo1.40, (1981) pp.lOl-106. 2. N. Igata. Abstracts Institute
Y. Kohno, A. Kohyama and K. Satoh, for the 92nd Meeting of Japan of Metals, (1983) p.157.
G. Ayraultand B.A. Loomis, DAFS 3, A. Kohyama, Quarterly Progress Report, DOE/ER-0046/11, (1982) pp.157-166. 4. A. Kohyama, T. Takeyama Electron California,
Y. Kohno, K. Suzuki, G. Ayrault, and N. Igata, High Voltage Microscopy '83, Berkeley, Aug.7983, 'in print'.
Book of ASTM 5. Annual ‘Nuclear Standards' (1977).
Standards, ANSI/ASTM
6. A. Kohyama, Y. Kohno, K. Suzuki, and N. Igata, this volume. 7. A. Hishinuma and Mater., 'in print'.
L.K.
Mansur,
Part 45, E521-77,
G. Ayrault
J.
Nucl.