Scatter Series Properties
This article do not include all the properties of the Scatter Series Properties class, it only highlights some features, to explore the full object checkout the API explorer
Name property
The name property is a string identifier that is normally used in tooltips and legends to display the data name, if this property is not set, then the library will generate a name for the series that by default is called "Series 1" when it is the first series in the series collection, "Series 2" when it is the second series in the series collection, "Series 3" when it is the third series in the series collection, and so on a series n will be named "Series n".
SeriesCollection = new ISeries[]
{
new ScatterSeriesProperties<int>
{
Values = new []{ 2, 5, 4, 2, 6 },
Name = "Income", // mark
Stroke = null
},
new ScatterSeriesProperties<int>
{
Values = new []{ 3, 7, 2, 9, 4 },
Name = "Outcome", // mark
Stroke = null
}
};
Values property
The Values
property is of type IEnumerable<T>
, this means that you can use any object that implements the IEnumerable<T>
interface,
such as Array
, List<T>
or ObservableCollection<T>
, this property contains the data to plot, you can use any type as the
generic argument (<T>
) as soon as you let the library how to handle it, the library already knows how to handle multiple types,
but you can register any type and teach the library how to handle any object in a chart, for more information please see the
mappers article.
var series1 = new ScatterSeriesProperties<int>
{
Values = new List<int> { 2, 1, 3 }
};
// == Update the chart when a value is added, removed or replaced == // mark
// using ObservableCollections allows the chart to update
// every time you add a new element to the values collection
// (not needed in Blazor, it just... updates)
var series2 = new ScatterSeriesProperties<double>
{
Values = new ObservableCollection<double> { 2, 1, 3 }
}
series2.add(4); // and the chart will animate the change!
// == Update the chart when a property in our collection changes == // mark
// if the object implements INotifyPropertyChanged, then the chart will
// update automatically when a property changes, the library already provides
// many 'ready to go' objects such as the ObservableValue class.
var observableValue = new ObservableValue(5);
var series3 = new ScatterSeriesProperties<ObservableValue>
{
Values = new ObservableCollection<ObservableValue> { observableValue },
}
observableValue.Value = 9; // the chart will animate the change from 5 to 9!
// == Passing X and Y coordinates // mark
// you can indicate both, X and Y using the Observable point class.
// or you could define your own object using mappers.
var series4 = new ScatterSeriesProperties<ObservablePoint>
{
Values = new ObservableCollection<ObservablePoint> { new ObservablePoint(2, 6)}
}
// == Custom types and mappers == // mark
// finally you can also use your own object, take a look at the City class.
public class City
{
public string Name { get; set; }
public double Population { get; set; }
}
// we must let the series know how to handle the city class.
// use the Mapping property to build a point from the city class
// you could also register the map globally.
// for more about global mappers info see:
// https://livecharts.dev/docs/eto/2.0.0-rc1/Overview.Mappers
var citiesSeries = new ScatterSeriesProperties<City>
{
Values = new City[]
{
new City { Name = "Tokio", Population = 9 },
new City { Name = "New York", Population = 11 },
new City { Name = "Mexico City", Population = 10 },
},
Mapping = (city, point) =>
{
// this function will be called for every city in our data collection
// in this case Tokio, New York and Mexico city
// it takes the city and the point in the chart liveCharts built for the given city
// you must map the coordinates to the point
// use the Population property as the primary value (normally Y)
point.PrimaryValue = (float)city.Population;
// use the index of the city in our data collection as the secondary value
// (normally X)
point.SecondaryValue = point.Context.Index;
}
};
Automatic updates do not have a significant performance impact in most of the cases!
Data labels
Data labels are labels for every point in a series, there are multiple properties to customize them, take a look at the following sample:
new ScatterSeriesProperties<double>
{
DataLabelsSize = 20,
DataLabelsPaint = new SolidColorPaint(SKColors.Blue),
// all the available positions at:
// https://livecharts.dev/api/2.0.0-rc1/LiveChartsCore.Measure.DataLabelsPosition
DataLabelsPosition = LiveChartsCore.Measure.DataLabelsPosition.Top,
// The DataLabelsFormatter is a function
// that takes the current point as parameter
// and returns a string.
// in this case we returned the PrimaryValue property as currency
DataLabelsFormatter = (point) => point.PrimaryValue.ToString("C2"),
Values = new ObservableCollection<double> { 2, 1, 3, 5, 3, 4, 6 },
Fill = null
}
The previous series will result in the following chart:
Stroke property
If the stroke property is not set, then LiveCharts will create it based on the series position in your series collection and the current theme.
Series = new ISeries[]
{
new ScatterSeries<ObservablePoint>
{
Stroke = new SolidColorPaint(SKColors.Blue) { StrokeThickness = 4 }, // mark
Fill = null,
Values = new ObservableCollection<ObservablePoint>
{
new ObservablePoint(2.2, 5.4),
new ObservablePoint(4.5, 2.5),
new ObservablePoint(4.2, 7.4),
...
}
}
};
Paints can create gradients, dashed lines and more, if you need help using the Paint
instances take
a look at the Paints article.
Fill property
If the fill property is not set, then LiveCharts will create it based on the series position in your series collection and the current theme.
Series = new ISeries[]
{
new ScatterSeries<ObservablePoint>
{
Fill = new SolidColorPaint(SKColors.Blue), // mark
Stroke = null,
Values = new ObservableCollection<ObservablePoint>
{
new ObservablePoint(2.2, 5.4),
new ObservablePoint(4.5, 2.5),
new ObservablePoint(4.2, 7.4),
...
}
}
};
Paints can create gradients, dashed lines and more, if you need help using the Paint
instances take
a look at the Paints article.
GeometrySize property
Determines the size of the geometry, if this property is not set, then the library will decide it based on the theme.
var r = new Random();
var values1 = new ObservableCollection<ObservablePoint>();
var values2 = new ObservableCollection<ObservablePoint>();
for (var i = 0; i < 20; i++)
{
values1.Add(new ObservablePoint(r.Next(0, 20), r.Next(0, 20)));
values2.Add(new ObservablePoint(r.Next(0, 20), r.Next(0, 20)));
}
Series = new ISeries[]
{
new ScatterSeries<ObservablePoint, RectangleGeometry>
{
Values = values1,
GeometrySize = 10, // mark
},
new ScatterSeries<ObservablePoint, CircleGeometry>
{
Values = values2,
GeometrySize = 30 // mark
}
};
MinGeometrySize property
This property specifies the minimum size a geometry can take when the Weight
plane is enabled, to enable this plane
you could use the WeightedPoint
class, the library is ready to plot this instance, alternatively you can register
a new type using mappers, and use the TertiaryValue
property of the ChartPoint
instance to specify
the weight of each point.
Notice in the following image how every shape has a different size, the size of each geometry represents the Weight
of each point, in this case the weight takes a random integer from 0 to 20, so when the Weight
is 0
the
size of the geometry will be 15
pixels as specified in the MinGeometrySize
property, when the Weight
is 20
the geometry size will be 40
defined by the GeometrySize
property, for any Weight
between this range the library
will interpolate lineally to determine the corresponding size.
var r = new Random();
var values1 = new ObservableCollection<WeightedPoint>();
var values2 = new ObservableCollection<WeightedPoint>();
for (var i = 0; i < 20; i++)
{
values1.Add(new WeightedPoint(r.Next(0, 20), r.Next(0, 20), r.Next(0, 20)));
values2.Add(new WeightedPoint(r.Next(0, 20), r.Next(0, 20), r.Next(0, 20)));
}
Series = new ObservableCollection<ISeries>
{
new ScatterSeries<WeightedPoint, RoundedRectangleGeometry>
{
Values = values1,
GeometrySize = 40,
MinGeometrySize = 15 // mark
},
new ScatterSeries<WeightedPoint, CircleGeometry>
{
Values = values2,
GeometrySize = 40,
MinGeometrySize = 15 // mark
}
};
Plotting custom types
You can plot any type of data, please see the mappers article for more information.
Custom geometries
You can also customize the geometry for each point in a series, you can use the geometries defined on LiveCharts, SVG geometries or draw your own using the SkiaSharp API, if you want to learn more please take a look at this article.
ZIndex property
Indicates an order in the Z axis, this order controls which series is above or behind.
IsVisible property
Indicates if the series is visible in the user interface.
DataPadding
The data padding is the minimum distance from the edges of the series to the axis limits, it is of type System.Drawing.PointF
both coordinates (X and Y) goes from 0 to 1, where 0 is nothing and 1 is the axis tick an axis tick is the separation between
every label or separator (even if they are not visible).
If this property is not set, the library will set it according to the series type, take a look at the following samples:
new LineSeries<double>
{
DataPadding = new LvcPoint(0, 0),
Values = new ObservableCollection { 2, 1, 3, 5, 3, 4, 6 },
GeometryStroke = null,
GeometryFill = null,
Fill = null
}
Produces the following result:
But you can remove the padding only from an axis, for example:
new LineSeries<double>
{
DataPadding = new LvcPoint(0.5f, 0),
Values = new ObservableCollection<double> { 2, 1, 3, 5, 3, 4, 6 },
GeometryStroke = null,
GeometryFill = null,
Fill = null
}
Or you can increase the distance:
new LineSeries<double>
{
DataPadding = new LvcPoint(2, 2),
Values = new ObservableCollection<double> { 2, 1, 3, 5, 3, 4, 6 },
GeometryStroke = null,
GeometryFill = null,
Fill = null
}