private void BuildUsingKH(IList <TiltData> tilts)
{
FiltType = FilterType.KarousHjelt;
ZAxisTitle = "KH";
ZUnit = "%";
var x = new List <float>();
var y = new List <float>();
var z = new List <float>();
foreach (var kh in tilts.Select(tilt => VlfFilter.KarousHjelt(tilt, 0, 1)))
{
for (var i = 0; i < kh.Npts; i++)
{
var xy = Displacement.NextPoint(kh.X, kh.Y, kh.Bearing, kh.Spacing * (i - 1));
x.Add(xy[0]);
y.Add(xy[1]);
z.Add(kh.Values[i]);
}
}
Npts = x.Count;
XValues = new float[x.Count];
YValues = new float[y.Count];
ZValues = new float[z.Count];
XValues = x.ToArray();
YValues = y.ToArray();
ZValues = z.ToArray();
CalcGridSize();
}
private void tsKarousHjelt_Click(object sender, EventArgs e)
{
var selectedNode = treeViewMain.SelectedNode;
var tiltData = selectedNode.Tag as TiltData;
if (tiltData == null)
{
return;
}
if (tiltData.Npts < 6)
{
MessageBox.Show(@"There should be minimum of 7 data for this filter to work.");
return;
}
var uniqeName = FindUniqeName(selectedNode.Name, treeViewMain.Nodes["NodeKH"]);
if (InputPrompt.InputStringBox("Karous Hjelt-Filter", "Enter a name.", ref uniqeName) != DialogResult.OK)
{
return;
}
var skin = 0f;
if (
InputPrompt.InputNumberBox("Karous Hjelt-Filter",
$"Skin depth normalization. Enter 0 to ignore skin depth", ref skin) != DialogResult.OK)
{
return;
}
var kh = VlfFilter.KarousHjelt(tiltData, skin);
kh.Rename(uniqeName);
AddNode(uniqeName, treeViewMain.Nodes["NodeKH"], kh);
if (kh.RawLength > 150)
{
MessageBox.Show(
@"Due to the limitation of gridding implementation in this version, the pseudosection could not be shown. However, you can still export the result into an external file.",
@"Data Too Large To Grid", MessageBoxButtons.OK, MessageBoxIcon.Information);
return;
}
StartGriddingWorker(new Surface2D(kh));
}
private void tsbMovAvg_Click(object sender, EventArgs e)
{
var selectedNode = treeViewMain.SelectedNode;
var parent = treeViewMain.Nodes["NodeTilt"];
var order = 3;
if (InputPrompt.InputNumberBox("Moving Average Filter", "Filter Order", ref order) != DialogResult.OK)
{
return;
}
var data = selectedNode.Tag as TiltData;
if (data != null && ((Math.Abs(order)) <= 1 || order > data.Npts))
{
MessageBox.Show(@"Invalid filter order.", @"Error");
return;
}
if (data == null)
{
return;
}
var newname = FindUniqeName($"{selectedNode.Name}_MovAvg Order {Convert.ToInt32(order)}", parent);
if (InputPrompt.InputStringBox("Moving Average Filter", "Enter a name.", ref newname) != DialogResult.OK)
{
return;
}
var smooth = VlfFilter.MovingAverage(data, Convert.ToInt32(order));
smooth.Rename(newname);
AddNode(newname, parent, smooth);
var form2 = new ChartPlot(newname, smooth)
{
MdiParent = this
};
form2.Show();
}
private void tsFraserFilter_Click(object sender, EventArgs e)
{
var selectedNode = treeViewMain.SelectedNode;
var tiltData = selectedNode.Tag as TiltData;
if (tiltData == null)
{
return;
}
if (tiltData.Npts < 4)
{
MessageBox.Show(@"There should be minimum of 4 data for this filter to work.");
return;
}
var uniqeName = FindUniqeName(selectedNode.Name, treeViewMain.Nodes["NodeFraser"]);
if (InputPrompt.InputStringBox("Fraser Filter", "Enter a name.", ref uniqeName) != DialogResult.OK)
{
return;
}
// Do Fraser Filtering
var fraser = VlfFilter.Fraser(tiltData);
fraser.Rename(uniqeName);
AddNode(uniqeName, treeViewMain.Nodes["NodeFraser"], fraser);
// Plot the result
var form2 = new ChartPlot(uniqeName, fraser)
{
MdiParent = this
};
form2.Show();
}
