MC Dataset is an extensive collection of datasets computed with PyXOpto Monte Carlo light propagation models. The readily available datasets are computed for a vast variety of sources, detectors and sample optical properties and include information of reflectance, transmittance, sampling volume and fluence/energy deposition data. The datasets can be easily customized through the dataset module of the PyXOpto project.
Datasets are split into multiple files to reduce the download size and to allow partial downloads. The following table has the links to the dataset files of the latest release. A more detailed description of the individual datasets is given in the following section.
Dataset | Release file | Description |
---|---|---|
MCML comparison datasets | ||
mcml_comparison.zip | single layer 100 mm and 1 mm thick, 2-layers 0.1 mm and 1 mm thick | |
Layered media datasets (MCML) | ||
mcml_1-layer-semiinfinite_line.zip | Semi-infinite medium, line source | |
mcml_1-layer-semiinfinite_collimated-200um.zip | Semi-infinite medium, collimated source with 200 µm diameter | |
mcml_1-layer-semiinfinite_gaussian-fwhm-100um.zip | Semi-infinite medium, Gaussian source with 100 µm FWH | |
mcml_1-layer-semiinfinite_fiber-200um-0.22na.zip | Semi-infinite medium, fiber source with 200 µm 0.22 NA core | |
mcml_1-layer-semiinfinite_six-linear-200um-0_22na.zip | Semi-infinite medium, six-linear array probe, 200 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_six-around-one-200um-0_22na.zip | Semi-infinite medium, six-arround-one probe, 200 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_six-around-one-400um-0_22na.zip | Semi-infinite medium, six-arround-one probe, 400 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_single-fiber-100um-0_22na.zip | Semi-infinite medium, single-fiber probe, 100 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_single-fiber-200um-0_22na.zip | Semi-infinite medium, single-fiber probe, 200 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_single-fiber-400um-0_22na.zip | Semi-infinite medium, single-fiber probe, 400 µm 0.22 NA fiber core | |
mcml_1-layer-semiinfinite_single-fiber-800um-0_22na.zip | Semi-infinite medium, single-fiber probe, 800 µm 0.22 NA fiber core | |
Voxelized media datasets (MCVOX) | ||
mcvox.zip | Energy deposition for a voxelized 2-layer skin with an embedded blood vessel at 26 depths]() | |
mcvox-2-layer-skin-200um-vessel-500um-depth-deposition.zip | Energy deposition for a voxelized 2-layer skin with an embedded blood vessel at 0.5 mm depth | |
Sampling volume datasets (SV) | ||
sv.zip | Sampling volume dataset |
The following sections provide information on the four groups of datasets:
- MCML comparison datasets
- Layered media datasets (MCML)
- Voxelized media datasets (MCVOX)
- Sampling volume datasets (SV)
At the end of each section there is a breakdown of the directory tree and naming conventions that are used to organize the dataset files.
This dataset is intended for comparison with the MCML package. Datasets are computed for a 1-layer (1 mm and 100 mm thick) and 2-layer sample (0.1 mm and 1.0 mm thick layers). The optical properties are varied in the top sample layer:
- Absorption coefficient is sampled from [0.0, 2.5, 5.0] cm -1.
- Reduced scattering coefficient is sampled from [5.0, 20.0, 35.0] cm -1.
- Scattering phase function anisotropy is sampled from [0.1, 0.5, 0.9].
- The refractive index of the sample is set to:
- 1-layer sample: 1.337,
- 2-layer sample: 1.462 for the top layer and 1.337 for the bottom layer.
- The refractive index of the surrounding medium is set to 1.0.
- The remaining optical properties of the 2nd layer are fixed to µa=0.5 cm-1, µs'=20.0 cm-1 and g=0.8.
The datasets are computed with a normally incident infinitely thin source. The reflectance and transmittance are collected through radial detectors with 500 concentric accumulators from 0 to 5 mm.
Illustration of the radial detector that is used to collect the reflectance and transmittance as Radial(Axis(start=0.0, stop=0.005, n=500))
. The central and outermost accumulator are highlighted with a gray fill
The energy deposition is collected in a 2D accumulator array along the radial r and z axis. The range of both axis is from 0 to 5 mm and the number of accumulators along each axis is set 500. All the simulations are prepared with 100 million photon packets and simulation termination radius is set to 1000 mm.
Illustration of the radially symmetric energy deposition detector FluenceRz
.
Datasets are available as compressed numpy data files that are organized as follows:
data/mcml_comparison/<sample>/line/radial/hg/g-<g>/mua-<mua>-musr-<musr>-invcm.npz
The values of placeholders <> are as follows:
-
<sample>
can take one of the following values:-
1-layer-1mm
A single layer 1 mm thick medium.
-
1-layer-100mm
A single layer 100 mm thick medium.
-
2-layer-100um-1mm
A two-layer medium with 0.1 mm thick top layer and 1 mm thick bottom layer
-
-
<g>
is the anisotropy formatted with two decimal digits and_
as the decimal separator, e.g0_10
for g=0.1,0_50
for g=0.5 or0_90
for g=0.9. -
<mua>
is the absorption coefficient in units of cm -1 with formatted with two decimal digits and_
as the decimal separator, e.g2_50
for µa=2.5 cm-1. -
<musr>
is the reduced scattering coefficient in units of cm -1 with formatted with two decimal digits and_
as the decimal separator, e.g25_00
for µs'=25.0 cm-1.
Henyey-Greenstein scattering phase functions used in the MCML comparison dataset.
The datasets are produced with 100 million photon packets, except for the Spatial Frequency Domain Imaging (SFDI) dataset and all the datasets that use an optical fiber probe with a linear layout of 6 fibers. These datasets are run with 1000 million photon packets. The simulation termination radius is set to 25 mm, except for the spatial frequency domain imaging (SFDI) dataset that uses a 150 mm simulation termination radius. The optical properties of the sample are varied according to the values listed in the following two tables.
Absorption and reduced scattering coefficients
Parameter | From (cm-1) | To (cm-1) | Points |
---|---|---|---|
µa | 0.0 | 5.0 | 21 |
µs' | 5.0 | 35.0 | 21 |
Scattering phase functions
Scattering phase function | Parameter | Values |
---|---|---|
HG (Henyey-Greenstein) | g | 0.1, 0.3, 0.5, 0.7, 0.9 |
MHG (Modified Henyey-Greenstein) | g | 0.1, 0.3, 0.5, 0.7, 0.9 |
β | 0.0, 0.2, 0.4, 0.6, 0.8, 1.0 | |
GK (Gegenbauer Kernel) | g | 0.1, 0.3, 0.5, 0.7, 0.9 |
α | -0.5, 0.0, 0.5, 1.0, 1.5 | |
MIE-polystyrene | λ | 500 nm |
diameter | 0.25, 0.5 1.0, 2.0, 4.0 µm | |
nparticle | 1.603 | |
nmedium | 1.337 | |
MIE-fused silica | λ | 500 nm |
diameter | 0.25, 0.5 1.0, 2.0, 4.0 µm | |
nparticle | 1.462 | |
nmedium | 1.337 |
The refractive index of the sample is set to 1.337.
Henyey-Greenstein (HG) scattering phase functions as defined in the above table.
Examples of Modified Henyey-Greenstein (MHG) scattering phase functions from the above table.
Examples of Gegenbauer Kernel (GK) scattering phase functions from the above table.
Mie scattering phase functions of water-suspended fused silica particles specified in the above table.
Mie scattering phase functions of water-suspended polystyrene particles specified in the above table.
Datasets are available for the following basic sources that use a laterally uniform boundary between the sample and the surrounding medium.
Basic sources with a uniform sample-source interface and related reflectance detectors
Source | Parameter | Value | Reflectance detector |
---|---|---|---|
Line | Radial(Axis(0, 0.005, 500)) | ||
UniformBeam | diameter | 200 μm | Radial(Axis(0, 0.005, 500)) |
GaussianBeam | FWHM | 100 μm | Radial(Axis(0, 0.005, 500)) |
UniformFiber | dcore | 200 μm | Radial(Axis(0, 0.005, 500)) |
dcladding | 220 μm | ||
ncore | 1.462 | ||
NA | 0.22 |
The refractive index of the surrounding medium is set to 1.0 except when using the UniformFiber source, when the refractive index of the surrounding medium follows the refractive index of the fiber core 1.462.
The reflectance of basic sources is collected with a radial detector with range from 0 to 5 mm and 500 concentric accumulators, each 5 μm wide. The acceptance angle is unlimited, except for the UniformFiber source for which it is limited by the NA of the fiber core. The acceptance angle within the fiber core.
Datasets are also prepared for optical fiber probe sources that use a surface layout to more accurately describe the interface between the optical fiber probe tip and the sample. All the probe sources launch the photon packets with the UniformFiber source.
Optical fiber probe sources with a detailed sample-source interface and related reflectance detectors
Probe | Parameter | Value | Description | Reflectance detector |
---|---|---|---|---|
SixAroundOne | dcore | 200 μm | six-around-one layout | SixAroundOne |
dcladding | 220 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
SixAroundOne | dcore | 400 μm | six-around-one layout | SixAroundOne |
dcladding | 420 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
LinearArray | dcore | 200 μm | linear layout of 6 fibers | LinearArray |
dcladding | 220 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
n | 6 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
LinearArray | dcore | 100 μm | single fiber layout | LinearArray |
dcladding | 120 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
n | 1 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
LinearArray | dcore | 200 μm | single fiber layout | LinearArray |
dcladding | 220 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
n | 1 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
LinearArray | dcore | 400 μm | single fiber layout | LinearArray |
dcladding | 420 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
n | 1 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 | |||
LinearArray | dcore | 800 μm | single fiber layout | LinearArray |
dcladding | 820 μm | |||
ncore | 1.462 | |||
NA | 0.22 | |||
n | 1 | |||
diameter | 6.0 mm | |||
reflectivity | 0.6 |
Illustration of the surface layouts for the two six-around-one optical fiber probes (SixAroundOne
) with 200 and 400 μm fiber cores.
Illustration of the surface layout for the linear array probe (LinearArray
) with 6 optical fibers.
Illustration of the surface layouts for the single fiber probes (LinearArray
) with 100, 200, 400 and 800 μm fiber cores.
The reflectance of optical fiber probe sources is collected only through the individual optical fibers of the probe.
The SFDI datasets are computed for two source-detector configurations and include raw reflectance and the corresponding frequency-domain reflectance, which is computed for spatial frequencies from 0.00 to 0.80 mm-1 in 0.01 mm-1 steps:
- A normally incident Line source and a radial
Radial(Axis(0.0, stop=0.15, n=4000, logscale=True), cosmin=0.98481)
reflectance detector that uses 4000 logarithmically spaced concentric accumulators from 0 to 150 mm. The acceptance angle is limited to 10°. Hankel transform is used to compute the spatial frequency-domain reflectance. Note that this transform produces real values.
A Radial detector with logarithmically spaced accumulators. The outermost accumulator is highlighted with a gray fill
- A normally incident Line source and a tilted linear detector with 20°
incidence (along the x axis). The accumulators of the detector extend to
infinity along the positive and negative y axis and follow a logarithmic
spacing along the positive and negative direction of the x axis
SymmetricX(SymmetricAxis(center=0.0, range=0.15, n_half=4000, logscale=True), cosmin=0.98480)
. The described detector uses 8000 (4000 in each direction along the :math:x
axis) logarithmically spaced accumulators x=-150 to x=150; mm. The acceptance angle of the detector is limited to 10° around the tilted detector axis. Fourier transform is used to compute the spatial frequency-domain reflectance. Note that this transform produces complex values with amplitude and phase information.
A SymmetricX detector with logarithmically spaced accumulators around the central axis. The first and last accumulators are highlighted with a gray fill.
Note that the SFDI datasets are run with 1000 million photon packets and that the simulation termination radius is set to 150 mm.
Datasets are available as compressed numpy data files that are organized as follows:
data/mcml/<sample>/<source>/<detector>/<pf>/<pf_param_1>/<pf_param_2>/mua-<mua>-musr-<musr>-invcm.npz
The values of placeholders <> are as follows:
-
<sample>
can take the following values:-
1-layer-semiinfinite
A single sample layer of infinite thickness.
-
-
<source>
is the type of the photon packet source / probe used in the datasets:-
line
Infinitely narrow line source (
Line
). -
collimated-200um
A 200 µm beam diameter (UniformBeam).
-
gaussian-fwhm-100um
A Gaussian beam with 100 µm FWHM (
GaussianBeam
). -
fiber-200um-0_22na
A 200 µm, 0.22 NA fiber source (
UniformFiber
). -
six-around-one-200um-0_22na
A six-around-one layout optical fibers (200 µm core, 220 µm cladding, 0.22 NA) (
SixAroundOne
) with the central optical fiber used as the source (UniformFiber
). The fibers are tightly packed. -
six-around-one-400um-0_22na
For a six-around-one layout optical fibers (400 µm core, 420 µm cladding, 0.22 NA) (
SixAroundOne
) with the central optical fiber used as the source (UniformFiber
). The fibers are tightly packed. -
six-linear-array-200um-0_22na
For a linear layout of 6 optical fibers (200 µm core, 220 µm cladding, 0.22 NA) (
LinearArray
) with the leftmost optical fiber used as the source (UniformFiber
). The fibers are tightly packed. -
single-fiber-100um-0_22na
A single fiber layout (100 µm core, 120 µm cladding, 0.22 NA) (
LinearArray
). -
single-fiber-200um-0_22na
A single fiber layout (200 µm core, 220 µm cladding, 0.22 NA) (
LinearArray
). -
single-fiber-400um-0_22na
A single fiber layout (400 µm core, 420 µm cladding, 0.22 NA) (
LinearArray
). -
single-fiber-400um-0_22na
A single fiber layout (800 µm core, 820 µm cladding, 0.22 NA) (
LinearArray
).
-
-
<detector>
is the type of detector used by the datasets:-
radial
For simple sources with laterally uniform source-sample boundary,
-
probe
For optical fiber probes with surface layout.
-
-
<pf>
is the type of scattering phase function used in the datasets:-
hg
for HG. -
mhg
for MHG. -
gk
for GK. -
mie-polystyrene
for MIE - a water suspension of polystyrene spheres. -
mie-fusedsilica
for MIE - a water suspension of fused silica spheres.
-
-
pf_param_1
: is the first parameter of the scattering phase function formatted with two decimal digits and using_
as the decimal separator:-
g-<g>
for HG, e.g.g-0_10
for g=0.1. -
g-<g>
for MHG, e.g.g-0_50
for g=0.5. -
g-<g>
for GK, e.g.g-0_90
for g=0.9. -
diameter-<d>um
MIE, e.g.diameter-0_25
for d=0.25 µm.
-
-
pf_param_2
: is the second parameter of the scattering phase function formatted with two decimal digits and using_
as the decimal separator. An exception to this rule is the wavelength parameter of the MIE scattering phase function that is converted to nm and formatted as an integer. This placeholder is not used with the HG scattering phase function.-
b-<b>
for MHG, e.g.b-0_60
for β=0.6. -
a-<a>
for GK, e.g.a-0_50
for α=0.5. -
wavelength-<w>nm
for MIE, e.g.wavelength-500nm
for w=500 nm.
-
-
<mua>
is the absorption coefficient in units of cm-1 with two decimal digits and_
as the decimal separator, e.g2_50
for µa=2.5 -1. -
<musr>
is the reduced scattering coefficient in units of cm-1 with two decimal digits and_
as a decimal separator, e.g20_00
for µa=20.0 cm-1.
These datasets include fluence/energy deposition data simulated with the MC kernel for voxelized media. A two-layer skin model with an embedded blood vessel is used. The depth/position of the blood vessel along the z axis is varied from 0.2 to 0.8 mm in steps of 0.025 mm. The refractive index of the surrounding medium is set to 1.337. The simulations are run with 1000 million photon packets.
A two-layer skin model with an embedded blood vessel
Parameter | Value | Description | |
---|---|---|---|
Line | normally incident | ||
Material | µa | 16.5724 cm-1 | epidermis |
µs | 375.9398 cm-1 | ||
n | 1.337 | ||
pf | HG(0.9) | ||
Material | µa | 45.85 cm-1 | dermis |
µs | 356.5406 cm-1 | ||
n | 1.337 | ||
pf | HG(0.9) | ||
Material | µa | 230.5427 cm-1 | blood vessel |
µs | 93.985 cm-1 | ||
n | 1.337 | ||
pf | HG(0.9) | ||
Fluence | xaxis | Axis(start=-502.5e-6, stop=502.5e-6, n=201) | energy deposition detector |
yaxis | Axis(start=-502.5e-6, stop=502.5e-6, n=201) | ||
zaxis | Axis(start=0.0, stop=0.001, n=200) | ||
Cartesian | xaxis | Axis(start=-502.5e-6, stop=502.5e-6, n=201) | reflectance/transmittance detector |
yaxis | Axis(start=-502.5e-6, stop=502.5e-6, n=201) | ||
Blood vessel | diameter | 200.0 μm | in dermis |
position | (x, y) = (0, 0) | ||
z | from 0.2 to 0.8 in 0.025 mm steps | ||
direction | (x, y, z) = (0, 1, 0) | ||
Epidermis | thickness | 100 μm |
Illustration of the Cartesian detector that is used to collect the reflectance and transmittance.
Energy deposition mean along the y axis for the above configuration of a 2-layer skin with an embedded blood vessel
Datasets are available as compressed numpy data files that are organized as follows:
data/mcvox/fluence/2-layer-skin-<diameter>um-vessel-<depth>um-depth-deposition.npz
The values of placeholders <> are as follows:
-
<diameter>
is the diameter of the blood vessel in units of μm, formatted as an integer value, e.g200
for a 200 μm blood vessel. -
<depth>
is the z coordinate (depth) of the blood vessel in units of μm, formatted as an integer value, e.g500
for z=500 μm.
The sampling volume dataset is computed for a semi-infinite homogeneous medium for an optical fiber probe with two optical fibers placed at a distance of 0.5 mm. The refractive index of the surrounding medium is set to 1.0. Simulations are run in batches until 1,000,000 photon packet traces that reach the detector fiber are collected and converted to sampling volume information. The trace capacity is limited to 1000 events. The simulation termination radius is set to 25 mm.
Sampling volume for a probe with two optical fibers
Parameter | Value | Description | |
---|---|---|---|
LinearArray | dcore | 200 μm | linear layout of 2 fibers |
dcladding | 220 μm | ||
ncore | 1.462 | ||
NA | 0.22 | ||
spacing | 500 μm | ||
diameter | 6.0 mm | ||
reflectivity | 0.6 | ||
Trace | maxlen | 1000 | packet trace configuration |
SamplingVolume | xaxis | Axis(start=-0.00075, stop=0.00075, n=300) | |
yaxis | Axis(start=-0.00075, stop=0.00075, n=300) | ||
zaxis | Axis(start=0.0, stop=0.001, n=200) | sampling volume voxelization | |
Layer | μa | 2.0 cm-1 | sample layer |
μs | 500 cm-1 | ||
n | 1.337 | ||
pf | HG(0.95) |
Sampling volume mean along the y axis for the above configuration of optical probe with two optical fibers
Datasets are available as compressed numpy data files that are organized as follows:
data/mcml/1-layer-semiinfinite/sv/reflectance/fiber-200um-0_22na/sds-<sds>um/hg/g-<g>/um-mua-<mua>-musr-<musr>-invcm.npz
The values of placeholders <> are as follows:
-
<sds>
is the distance between the centers of the source and detector fibers in units of μm, formatted as an integer value, e.g500
for a 500 μm distance. -
<g>
is the anisotropy formatted with two decimal digits and_
as the decimal separator, e.g0_15
for g=0.15. -
<mua>
is the absorption coefficient in units of cm-1 with two decimal digits and_
as the decimal separator, e.g2_50
for μa=2.5 cm-1. -
<musr>
is the reduced scattering coefficient in units of cm-1 with two decimal digits and_
as a decimal separator, e.g20_00
for μs'=20.0 cm-1.
We, the authors of MC Dataset, expect that the package is used in accordance with the GPL3+ license and that any work using the MC Dataset package also cites the project and at least one of the following references:
-
M. Bürmen, F. Pernuš, and P. Naglič, MCDataset: a public reference dataset of Monte Carlo simulated quantities for multilayered and voxelated tissues computed by massively parallel PyXOpto Python package, J. Biomed. Opt., 27 (8), 083012 (2022), https://doi.org/10.1117/1.JBO.27.8.083012.
-
P. Naglič, F. Pernuš, B. Likar, and M. Bürmen, Limitations of the commonly used simplified laterally uniform optical fiber probe-tissue interface in Monte Carlo simulations of diffuse reflectance, Biomed. Opt. Expres, 6 (10), 3973-3988 (2015), https://doi.org/10.1364/BOE.6.003973.
-
P. Naglič, F. Pernuš, B. Likar, and M. Bürmen, Lookup table-based sampling of the phase function for Monte Carlo simulations of light propagation in turbid media, Biomed. Opt. Expres, 8 (3), 1895-1910 (2017), https://doi.org/10.1364/BOE.8.001895.
For alternative licensing options of MC Dataset please contact us at info@xopto.eu.