swarmchart3
Syntax
Description
Vector Data
swarmchart3(
displays a 3D swarm chart, which is a scatter plot with the points offset (jittered) in
the x
,y
,z
)x
 and y
dimensions. The points form distinct
shapes, and the outline of each shape is similar to a violin plot. 3D swarm charts help
you to visualize discrete (x
,y
) data with the
distribution of the z data. At each
(x
,y
) location, the points are jittered based on
the kernel density estimate of z
.
swarmchart3(
specifies the marker colors. To plot all the markers with the same color, specify
x
,y
,z
,sz
,c
)c
as a color name or an RGB triplet. To assign a different color to
each marker, specify a vector the same size as x
, y
,
and z
. Alternatively, you can specify a threecolumn matrix of RGB
triplets. The number of rows in the matrix must match the length of x
,
y
, and z
.
swarmchart3(___,
specifies a
different marker than the default marker, which is a circle. Specify
mkr
)mkr
after all the arguments in any of the previous syntaxes.
Table Data
swarmchart3(
plots the variables tbl
,xvar
,yvar
,zvar
)xvar
, yvar
, and
zvar
from the table tbl
. To plot one data set,
specify one variable each for xvar
, yvar
, and
zvar
. To plot multiple data sets, specify multiple variables for at
least one of those arguments. The arguments that specify multiple variables must specify
the same number of variables.
Additional Options
swarmchart3(
displays the
swarm chart in the target axes. Specify the axes before all the arguments in any of the
previous syntaxes.ax
,___)
swarmchart3(___,
specifies additional properties for the swarm chart using one or more
Name,Value
)Name,Value
arguments. For example:
swarmchart3(x,y,z,'LineWidth',2)
creates a swarm chart with 2point marker outlines.swarmchart3(tbl,'MyX','MyY','MyZ','ColorVariable','MyColors')
creates a swarm chart from data in a table, and customizes the marker colors using data from the table.
For a list of properties, see Scatter Properties.
s = swarmchart3(___)
returns the
Scatter
object. Use s
to modify properties of the
chart after creating it. For a list of properties, see Scatter Properties.
Examples
Create a 3D Swarm Chart
Read the BicycleCounts.csv
data set into a timetable called tbl
. This data set contains bicycle traffic data over a period of time. Display the first five rows of tbl
.
tbl = readtable("BicycleCounts.csv");
tbl(1:5,:)
ans=5×5 table
Timestamp Day Total Westbound Eastbound
____________________ _____________ _____ _________ _________
24Jun2015 00:00:00 {'Wednesday'} 13 9 4
24Jun2015 01:00:00 {'Wednesday'} 3 3 0
24Jun2015 02:00:00 {'Wednesday'} 1 1 0
24Jun2015 03:00:00 {'Wednesday'} 1 1 0
24Jun2015 04:00:00 {'Wednesday'} 1 1 0
Create a vector x
with the day name from each observation.
daynames = ["Sunday" "Monday" "Tuesday" "Wednesday" "Thursday" "Friday" "Saturday"]; x = categorical(tbl.Day,daynames);
Create a categorical vector y
containing the values "pm"
or "am"
according to the time for each observation in the table. Create vector z
of eastbound traffic data. Then create a swarm chart of x
, y
, and z
. The chart shows the data distributions for each morning and evening of the week.
ispm = tbl.Timestamp.Hour < 12; y = categorical; y(ispm) = "pm"; y(~ispm) = "am"; z= tbl.Eastbound; swarmchart3(x,y,z);
Specify Marker Size
Create vector x
as a combination of zeros and ones, and create y
as a vector containing all ones. Create z
as a vector of squared random numbers. Then create a swarm chart of x
, y
, and z
, and specify the size marker size as 5
.
x = [zeros(1,500) ones(1,500)]; y = ones(1,1000); z = randn(1,1000).^2; swarmchart3(x,y,z,5);
Specify Marker Symbol
Create vector x
as a combination of zeros and ones, and create y
as a vector containing all ones. Create z
as a vector of squared random numbers. Then create a swarm chart of x
, y
, and z
, and specify the point ('.'
) marker symbol.
x = [zeros(1,500) ones(1,500)];
y = ones(1,1000);
z = randn(1,1000).^2;
swarmchart3(x,y,z,'.');
Vary Marker Color
Create vector x
containing a combination of zeros and ones, and create y
containing a random combination of ones and twos. Create z
as a vector of squared random numbers. Specify the colors for the markers by creating vector c
as the square root of z
. Then create a swarm chart of x
, y
, and z
. Set the marker size to 50
and specify the colors as c
. The values in c
index into the figure's colormap. Use the 'filled'
option to fill the markers with color instead of displaying them as hollow circles.
x = [zeros(1,500) ones(1,500)];
y = randi(2,1,1000);
z = randn(1,1000).^2;
c = sqrt(z);
swarmchart3(x,y,z,50,c,'filled');
Change Jitter Type and Width
Create vector x
containing a combination of zeros and ones, and create y
containing a random combination of the numbers one through four. Create z
as a vector of squared random numbers. Then create a swarm chart of x
, y
, and z
by calling the swarmchart
function with a return argument that stores the Scatter
object. Add x and yaxis labels so you can see the effect of changing the jitter properties in each dimension.
x = [zeros(1,500) ones(1,500)]; y = randi(4,1,1000); z = randn(1,1000).^2; s = swarmchart3(x,y,z); xlabel('X') ylabel('Y')
Change the shapes of the clusters of points by setting the jitter properties on the Scatter
object. In the x
dimension, specify uniform random jitter, and change the jitter width to 0.5
data units. In the y
dimension, specify normal random jitter, and change the jitter width to 0.1
data units. The spacing between points does not exceed the jitter width you specify.
s.XJitter = 'rand'; s.XJitterWidth = 0.5; s.YJitter = 'randn'; s.YJitterWidth = 0.1;
Plot Data from a Table
A convenient way to plot data from a table is to pass the table to the swarm3
function and specify the variables you want to plot. For example, create a table with four variables of random numbers, and plot the X
, Y1
, and Z
variables. By default, the axis labels match the variable names.
tbl = table(randi(2,100,1),randi(2,100,1),randi([10 11],100,1), ... randn(100,1),'VariableNames',{'X','Y1','Y2','Z'}); swarmchart3(tbl,'X','Y1','Z')
You can also plot multiple variables at the same time. For example, plot Y1
and Y2
on the yaxis by specifying the yvar
argument as the cell array {'Y1','Y2'}
. Then add a legend. The legend labels match the variable names.
swarmchart3(tbl,'X',{'Y1','Y2'},'Z') legend
Plot Table Data with Custom Marker Sizes and Colors
One way to plot data from a table and customize the colors and marker sizes is to set the ColorVariable
and SizeData
properties. You can set these properties as namevalue arguments when you call the swarmchart3
function, or you can set them on the Scatter
object later.
For example, create a table with four variables of random numbers, and plot the X
, Y
, and Z
variables with filled markers. Vary the marker colors by specifying the ColorVariable
namevalue argument. Return the Scatter
object as s
, so you can set other properties later.
tbl = table(randi(2,100,1),randn(100,1),randn(100,1),randn(100,1), ... 'VariableNames',{'X','Y','Z','Colors'}); s = swarmchart3(tbl,'X','Y','Z','filled','ColorVariable','Colors');
Change the marker sizes to 100 points by setting the SizeData
property.
s.SizeData = 100;
Specify Target Axes
Read the BicycleCounts.csv
data set into a timetable called tbl
. This data set contains bicycle traffic data over a period of time. Display the first five rows of tbl
.
tbl = readtable("BicycleCounts.csv");
tbl(1:5,:)
ans=5×5 table
Timestamp Day Total Westbound Eastbound
____________________ _____________ _____ _________ _________
24Jun2015 00:00:00 {'Wednesday'} 13 9 4
24Jun2015 01:00:00 {'Wednesday'} 3 3 0
24Jun2015 02:00:00 {'Wednesday'} 1 1 0
24Jun2015 03:00:00 {'Wednesday'} 1 1 0
24Jun2015 04:00:00 {'Wednesday'} 1 1 0
Create vector x
with the days names for each observation. Create a categorical vector y
containing the values "pm"
or "am"
according to the time for each observation in the table. Define ze
as a vector of eastbound traffic data, and define zw
as a vector of westbound traffic data.
daynames = ["Sunday" "Monday" "Tuesday" "Wednesday" "Thursday" "Friday" "Saturday"]; x = categorical(tbl.Day,daynames); ispm = tbl.Timestamp.Hour<12; y = categorical; y(ispm) = 'pm'; y(~ispm) = 'am'; ze = tbl.Eastbound; zw = tbl.Westbound;
Create a tiled chart layout in the 'flow'
tile arrangement, so that the axes fill the available space in the layout. Call the nexttile
function to create an axes object and return it as ax1
. Then create a swarm chart of the eastbound data by passing ax1
to the swarmchart
function.
tiledlayout('flow') ax1=nexttile; swarmchart3(ax1,x,y,ze,'.');
Repeat the process to create a second axes object and a swarm chart for the westbound traffic.
ax2 = nexttile;
z = tbl.Westbound;
swarmchart3(ax2,x,y,zw,'.');
Input Arguments
x
— xcoordinates
scalar  vector
xcoordinates, specified as a numeric scalar or a vector the same
size as y
and z
.
Data Types: single
 double
 int8
 int16
 int32
 int64
 uint8
 uint16
 uint32
 uint64
 categorical
y
— ycoordinates
scalar  vector
ycoordinates, specified as a numeric scalar or a vector the same
size as x
and z
.
Data Types: single
 double
 int8
 int16
 int32
 int64
 uint8
 uint16
 uint32
 uint64
 categorical
z
— zcoordinates
scalar  vector
zcoordinates, specified as a numeric scalar or a vector the same
size as x
and y
.
Data Types: single
 double
 int8
 int16
 int32
 int64
 uint8
 uint16
 uint32
 uint64
 datetime
 duration
sz
— Marker size
36 (default)  numeric scalar  row or column vector  []
Marker size in points, specified in one of these forms:
Numeric scalar — Plot all markers with equal size.
Row or column vector — Use different sizes for each marker. The length of
sz
must equal the length ofx
,y
, andz
.[]
— Use the default size of 36 points.
c
— Marker color
[0 0.4470 0.7410]
(default)  RGB triplet  threecolumn matrix of RGB triplets  vector  'r'
 'g'
 'b'
 ...
Marker color, specified in one of these forms:
RGB triplet or color name — Plot all the markers with the same color. An RGB triplet is a threeelement row vector whose elements specify the intensities of the red, green, and blue components of the color. The intensities must be in the range
[0,1]
. Alternatively, you can specify a color name from the table below.Three column matrix of RGB triplets — Use different colors for each marker. Each row of the matrix specifies an RGB triplet color for the corresponding marker. The number of rows must equal the length of
x
,y
, andz
.Vector — Use different colors for each marker. The values in
c
index into the current colormap, and they cover the full range of the colormap. The length ofc
must equal the length ofx
,y
, andz
. To change the colormap, use thecolormap
function.
Color Name  Description  Equivalent RGB Triplet 

'red' or 'r'  Red  [1 0 0] 
'green' or 'g'  Green  [0 1 0] 
'blue' or 'b'  Blue  [0 0 1] 
'yellow' or 'y'  Yellow  [1 1 0] 
'magenta' or 'm'  Magenta  [1 0 1] 
'cyan' or 'c'  Cyan  [0 1 1] 
'white' or 'w'  White  [1 1 1] 
'black' or 'k'  Black  [0 0 0] 
mkr
— Marker type
'o'
(default)  '+'
 '*'
 '.'
 'x'
 ...
Marker type, specified as one of the values listed in this table.
Marker  Description  Resulting Marker 

"o"  Circle 

"+"  Plus sign 

"*"  Asterisk 

"."  Point 

"x"  Cross 

"_"  Horizontal line 

""  Vertical line 

"square"  Square 

"diamond"  Diamond 

"^"  Upwardpointing triangle 

"v"  Downwardpointing triangle 

">"  Rightpointing triangle 

"<"  Leftpointing triangle 

"pentagram"  Pentagram 

"hexagram"  Hexagram 

'filled'
— Option to fill interior of markers
'filled'
Option to fill the interior of the markers, specified as
'filled'
. Use this option with markers that have a face, for example,
'o'
or 'square'
. Markers that do not have a face
and contain only edges do not render at all ('+'
,
'*'
, '.'
, and 'x'
).
The 'filled'
option sets the MarkerFaceColor
property of the Scatter
object to
'flat'
and the MarkerEdgeColor
property to
'none'
. In this case, MATLAB^{®} draws the marker faces, but not the edges.
tbl
— Source table
table  timetable
Source table containing the data to plot, specified as a table or a timetable.
xvar
— Table variables containing xcoordinates
one or more table variable indices
Table variables containing the xcoordinates, specified as one or more table variable indices.
Specifying Table Indices
Use any of the following indexing schemes to specify the desired variable or variables.
Indexing Scheme  Examples 

Variable names:


Variable index:


Variable type:


Plotting Your Data
The table variables you specify can contain numeric, categorical, datetime, or duration values.
To plot one data set, specify one variable for xvar
, one variable for
yvar
, and one variable for zvar
. For example,
create a table with four variables of normally distributed random values. Plot the
X
, Y1
, and Z
variables.
tbl = table(randn(100,1),randn(100,1),randn(100,1)+5,randn(100,1), ... 'VariableNames',{'X','Y1','Y2','Z'}); swarmchart3(tbl,'X','Y1','Z')
To plot multiple data sets together, specify multiple variables for at least one of xvar
, yvar
, or zvar
. If you specify multiple variables for more than one argument, the number of variables must be the same for each of those arguments.
For example, plot the X
variable on the xaxis, the
Y1
and Y2
variables on the
yaxis, and the Z
variable on the
zaxis.
swarmchart3(tbl,'X',{'Y1','Y2'},'Z')
You can also use different indexing schemes for xvar
,
yvar
, and zvar
. For example, specify
xvar
as a variable name, yvar
as an index number,
and zvar
as a logical
vector.
swarmchart3(tbl,'X',2,[false false true])
yvar
— Table variables containing ycoordinates
one or more table variable indices
Table variables containing the ycoordinates, specified as one or more table variable indices.
Specifying Table Indices
Use any of the following indexing schemes to specify the desired variable or variables.
Indexing Scheme  Examples 

Variable names:


Variable index:


Variable type:


Plotting Your Data
The table variables you specify can contain numeric, categorical, datetime, or duration values.
To plot one data set, specify one variable for xvar
, one variable for
yvar
, and one variable for zvar
. For example,
create a table with four variables of normally distributed random values. Plot the
X
, Y1
, and Z
variables.
tbl = table(randn(100,1),randn(100,1),randn(100,1)+5,randn(100,1), ... 'VariableNames',{'X','Y1','Y2','Z'}); swarmchart3(tbl,'X','Y1','Z')
To plot multiple data sets together, specify multiple variables for at least one of xvar
, yvar
, or zvar
. If you specify multiple variables for more than one argument, the number of variables must be the same for each of those arguments.
For example, plot the X
variable on the xaxis, the
Y1
and Y2
variables on the
yaxis, and the Z
variable on the
zaxis.
swarmchart3(tbl,'X',{'Y1','Y2'},'Z')
You can also use different indexing schemes for xvar
,
yvar
, and zvar
. For example, specify
xvar
as a variable name, yvar
as an index number,
and zvar
as a logical
vector.
swarmchart3(tbl,'X',2,[false false true])
zvar
— Table variables containing zcoordinates
one or more table variable indices
Table variables containing the zcoordinates, specified as one or more table variable indices.
Specifying Table Indices
Use any of the following indexing schemes to specify the desired variable or variables.
Indexing Scheme  Examples 

Variable names:


Variable index:


Variable type:


Plotting Your Data
The table variables you specify can contain numeric, categorical, datetime, or duration values.
To plot one data set, specify one variable for xvar
, one variable for
yvar
, and one variable for zvar
. For example,
create a table with four variables of normally distributed random values. Plot the
X
, Y1
, and Z
variables.
tbl = table(randn(100,1),randn(100,1),randn(100,1)+5,randn(100,1), ... 'VariableNames',{'X','Y1','Y2','Z'}); swarmchart3(tbl,'X','Y1','Z')
To plot multiple data sets together, specify multiple variables for at least one of xvar
, yvar
, or zvar
. If you specify multiple variables for more than one argument, the number of variables must be the same for each of those arguments.
For example, plot the X
variable on the xaxis, the
Y1
and Y2
variables on the
yaxis, and the Z
variable on the
zaxis.
swarmchart3(tbl,'X',{'Y1','Y2'},'Z')
You can also use different indexing schemes for xvar
,
yvar
, and zvar
. For example, specify
xvar
as a variable name, yvar
as an index number,
and zvar
as a logical
vector.
swarmchart3(tbl,'X',2,[false false true])
ax
— Target axes
Axes
object
Target axes, specified as an Axes
object. If you do not specify
the axes, MATLAB plots into the current axes, or it creates an Axes
object if one does not exist.
NameValue Arguments
Specify optional pairs of arguments as
Name1=Value1,...,NameN=ValueN
, where Name
is
the argument name and Value
is the corresponding value.
Namevalue arguments must appear after other arguments, but the order of the
pairs does not matter.
Before R2021a, use commas to separate each name and value, and enclose
Name
in quotes.
Example: swarmchart3(randi(2,500,1),randi(2,500,1),randn(500,1),'MarkerFaceColor','red')
specifies red filled markers.
XJitter
— Jitter type for xdimension
'none'
 'density'
 'rand'
 'randn'
Type of jitter (spacing of points) along the xdimension, specified as one of the following values:
'none'
— Do not jitter the points.'density'
— Jitter the points using the kernel density estimate of y for 2D charts. If you specify this option in two dimensions for a 3D chart, the points are jittered based on the kernel density estimate in the third dimension. For example, settingXJitter
andYJitter
to'density'
uses the kernel density estimate of z.'rand'
— Jitter the points randomly with a uniform distribution.'randn'
— Jitter points randomly with a normal distribution.
XJitterWidth
— Maximum jitter along xdimension
nonnegative scalar
Maximum amount of jitter (offset between points) along the xdimension, specified as a nonnegative scalar value in data units.
For example, to set the jitter width to 90% of the shortest distance between adjacent points,
take the minimum distance between unique values of x
and scale by
0.9
.
XJitterWidth = 0.9 * min(diff(unique(x)));
YJitter
— Jitter type for ydimension
'none'
 'density'
 'rand'
 'randn'
Type of jitter (spacing of points) along the ydimension, specified as one of the following values:
'none'
— Do not jitter the points.'density'
— Jitter the points using the kernel density estimate of x for 2D charts. If you specify this option in two dimensions for a 3D chart, the points are jittered based on the kernel density estimate in the third dimension. For example, settingXJitter
andYJitter
to'density'
uses the kernel density estimate of z.'rand'
— Jitter the points randomly with a uniform distribution.'randn'
— Jitter points randomly with a normal distribution.
YJitterWidth
— Maximum jitter along ydimension
nonnegative scalar
Maximum amount of jitter (offset between points) along the ydimension, specified as a nonnegative scalar value in data units.
For example, to set the jitter width to 90% of the shortest distance between adjacent points,
take the minimum distance between unique values of y
and scale by
0.9
.
YJitterWidth = 0.9 * min(diff(unique(y)));
ColorVariable
— Table variable containing color data
table variable index
Table variable containing the color data, specified as a variable index into the source table.
Specifying the Table Index
Use any of the following indexing schemes to specify the desired variable.
Indexing Scheme  Examples 

Variable name:


Variable index:


Variable type:


Specifying Color Data
Specifying the ColorVariable
property controls the colors of the markers.
The data in the variable controls the marker fill color when the
MarkerFaceColor
property is set to
"flat"
. The data can also control the marker outline color,
when the MarkerEdgeColor
is set to
"flat"
.
The table variable you specify can contain values of any numeric type. The values can be in either of the following forms:
A column of numbers that linearly map into the current colormap.
A threecolumn array of RGB triplets. RGB triplets are threeelement vectors whose values specify the intensities of the red, green, and blue components of specific colors. The intensities must be in the range
[0,1]
. For example,[0.5 0.7 1]
specifies a shade of light blue.
When you set the ColorVariable
property, MATLAB updates the CData
property.
Algorithms
The points in a swarm chart are jittered using uniform random values that are weighted by
the Gaussian kernel density estimate of z
and the relative number of points
at each (x
, y
) location. This behavior corresponds to
the default 'density'
setting of the XJitter
and
YJitter
properties on the Scatter
object when you call
the swarmchart3
function.
The maximum spread of points at each x
location is 90% of the smallest distance between adjacent points by default. For example, in
the x
dimension, the spread is calculated
as:
spread = 0.9 * min(diff(unique(x)));
You can control the offset by setting the XJitterWidth
and
YJitterWidth
properties on the Scatter
object.
Version History
Introduced in R2020bR2022b: Plots created with tables preserve special characters in axis and legend labels
When you pass a table and one or more variable names to the swarmchart3
function, the axis and legend labels now display any special characters that are included in the table variable names, such as underscores. Previously, special characters were interpreted as TeX or LaTeX characters.
For example, if you pass a table containing a variable named Sample_Number
to the swarmchart3
function, the underscore appears in the axis and
legend labels. In R2022a and earlier releases, the underscores are interpreted as
subscripts.
Release  Label for Table Variable "Sample_Number" 

R2022b 

R2022a 

To display axis and legend labels with TeX or LaTeX formatting, specify the labels manually.
For example, after plotting, call the xlabel
or
legend
function with the desired label strings.
xlabel("Sample_Number") legend(["Sample_Number" "Another_Legend_Label"])
R2021b: Pass tables directly to swarmchart3
Create plots by passing a table to the swarmchart3
function followed by the variables you want to plot. When you specify your data as a table, the axis labels and the legend (if present) are automatically labeled using the table variable names.
MATLAB 명령
다음 MATLAB 명령에 해당하는 링크를 클릭했습니다.
명령을 실행하려면 MATLAB 명령 창에 입력하십시오. 웹 브라우저는 MATLAB 명령을 지원하지 않습니다.
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