kopia lustrzana https://github.com/NanoVNA-Saver/nanovna-saver
First versions of permeability- and group delay-charts.
Rune Broberg
rodzic
66859c81a7
commit
72c95bc8ba
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@ -18,6 +18,7 @@ import math
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from typing import List, Set
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import numpy as np
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import logging
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from scipy import signal
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from PyQt5 import QtWidgets, QtGui, QtCore
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from PyQt5.QtCore import pyqtSignal
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@ -2382,7 +2383,8 @@ class RealImaginaryChart(FrequencyChart):
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#
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self.setMinimumSize(self.chartWidth + self.leftMargin + self.rightMargin, self.chartHeight + 40)
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self.setSizePolicy(QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.MinimumExpanding))
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self.setSizePolicy(QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding,
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QtWidgets.QSizePolicy.MinimumExpanding))
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pal = QtGui.QPalette()
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pal.setColor(QtGui.QPalette.Background, self.backgroundColor)
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self.setPalette(pal)
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@ -3051,3 +3053,438 @@ class MagnitudeZChart(FrequencyChart):
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new_chart: LogMagChart = super().copy()
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new_chart.span = self.span
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return new_chart
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class PermeabilityChart(FrequencyChart):
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def __init__(self, name=""):
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super().__init__(name)
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self.leftMargin = 40
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self.rightMargin = 30
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self.chartWidth = 230
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self.chartHeight = 250
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self.fstart = 0
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self.fstop = 0
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self.span = 0.01
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self.max = 0
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self.maxDisplayValue = 100
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self.minDisplayValue = -100
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#
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# Set up size policy and palette
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#
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self.setMinimumSize(self.chartWidth + self.leftMargin + self.rightMargin, self.chartHeight + 40)
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self.setSizePolicy(QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.MinimumExpanding))
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pal = QtGui.QPalette()
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pal.setColor(QtGui.QPalette.Background, self.backgroundColor)
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self.setPalette(pal)
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self.setAutoFillBackground(True)
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def copy(self):
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new_chart: PermabilityChart = super().copy()
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return new_chart
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def drawChart(self, qp: QtGui.QPainter):
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qp.setPen(QtGui.QPen(self.textColor))
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qp.drawText(self.leftMargin + 5, 15, self.name + " (\N{MICRO SIGN}\N{OHM SIGN} / Hz)")
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qp.drawText(10, 15, "R")
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qp.drawText(self.leftMargin + self.chartWidth + 10, 15, "X")
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qp.setPen(QtGui.QPen(self.foregroundColor))
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qp.drawLine(self.leftMargin, self.topMargin - 5, self.leftMargin, self.topMargin + self.chartHeight + 5)
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qp.drawLine(self.leftMargin-5, self.topMargin + self.chartHeight,
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self.leftMargin + self.chartWidth + 5, self.topMargin + self.chartHeight)
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def drawValues(self, qp: QtGui.QPainter):
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if len(self.data) == 0 and len(self.reference) == 0:
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return
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pen = QtGui.QPen(self.sweepColor)
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pen.setWidth(self.pointSize)
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line_pen = QtGui.QPen(self.sweepColor)
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line_pen.setWidth(self.lineThickness)
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highlighter = QtGui.QPen(QtGui.QColor(20, 0, 255))
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highlighter.setWidth(1)
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if self.fixedSpan:
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fstart = self.minFrequency
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fstop = self.maxFrequency
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else:
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if len(self.data) > 0:
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fstart = self.data[0].freq
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fstop = self.data[len(self.data)-1].freq
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else:
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fstart = self.reference[0].freq
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fstop = self.reference[len(self.reference) - 1].freq
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self.fstart = fstart
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self.fstop = fstop
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# Draw bands if required
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if self.bands.enabled:
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self.drawBands(qp, fstart, fstop)
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# Find scaling
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if self.fixedValues:
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min = self.minDisplayValue
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max = self.maxDisplayValue
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else:
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min = 1000
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max = -1000
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for d in self.data:
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re, im = RFTools.normalize50(d)
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re = re * 10e6 / d.freq
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im = im * 10e6 / d.freq
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if re > max:
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max = re
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if re < min:
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min = re
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if im > max:
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max = im
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if im < min:
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min = im
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for d in self.reference: # Also check min/max for the reference sweep
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if d.freq < fstart or d.freq > fstop:
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continue
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re, im = RFTools.normalize50(d)
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re = re * 10e6 / d.freq
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im = im * 10e6 / d.freq
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if re > max:
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max = re
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if re < min:
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min = re
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if im > max:
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max = im
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if im < min:
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min = im
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self.max = max
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span = max - min
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if span == 0:
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span = 0.01
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self.span = span
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# We want one horizontal tick per 50 pixels, at most
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horizontal_ticks = math.floor(self.chartHeight/50)
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for i in range(horizontal_ticks):
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y = self.topMargin + round(i * self.chartHeight / horizontal_ticks)
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qp.setPen(QtGui.QPen(self.foregroundColor))
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qp.drawLine(self.leftMargin - 5, y, self.leftMargin + self.chartWidth + 5, y)
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qp.setPen(QtGui.QPen(self.textColor))
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val = max - i * span / horizontal_ticks
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qp.drawText(3, y + 4, str(round(val, 1)))
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qp.drawText(3, self.chartHeight + self.topMargin, str(round(min, 1)))
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self.drawFrequencyTicks(qp)
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primary_pen = pen
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secondary_pen = QtGui.QPen(self.secondarySweepColor)
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if len(self.data) > 0:
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c = QtGui.QColor(self.sweepColor)
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c.setAlpha(255)
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pen = QtGui.QPen(c)
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pen.setWidth(2)
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qp.setPen(pen)
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qp.drawLine(20, 9, 25, 9)
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c = QtGui.QColor(self.secondarySweepColor)
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c.setAlpha(255)
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pen.setColor(c)
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qp.setPen(pen)
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qp.drawLine(self.leftMargin + self.chartWidth, 9, self.leftMargin + self.chartWidth + 5, 9)
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primary_pen.setWidth(self.pointSize)
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secondary_pen.setWidth(self.pointSize)
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line_pen.setWidth(self.lineThickness)
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for i in range(len(self.data)):
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x = self.getXPosition(self.data[i])
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y_re = self.getReYPosition(self.data[i])
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y_im = self.getImYPosition(self.data[i])
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qp.setPen(primary_pen)
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if self.isPlotable(x, y_re):
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qp.drawPoint(x, y_re)
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qp.setPen(secondary_pen)
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if self.isPlotable(x, y_im):
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qp.drawPoint(x, y_im)
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if self.drawLines and i > 0:
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prev_x = self.getXPosition(self.data[i - 1])
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prev_y_re = self.getReYPosition(self.data[i-1])
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prev_y_im = self.getImYPosition(self.data[i-1])
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# Real part first
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line_pen.setColor(self.sweepColor)
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qp.setPen(line_pen)
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if self.isPlotable(x, y_re) and self.isPlotable(prev_x, prev_y_re):
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qp.drawLine(x, y_re, prev_x, prev_y_re)
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elif self.isPlotable(x, y_re) and not self.isPlotable(prev_x, prev_y_re):
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new_x, new_y = self.getPlotable(x, y_re, prev_x, prev_y_re)
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qp.drawLine(x, y_re, new_x, new_y)
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elif not self.isPlotable(x, y_re) and self.isPlotable(prev_x, prev_y_re):
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new_x, new_y = self.getPlotable(prev_x, prev_y_re, x, y_re)
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qp.drawLine(prev_x, prev_y_re, new_x, new_y)
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# Imag part second
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line_pen.setColor(self.secondarySweepColor)
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qp.setPen(line_pen)
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if self.isPlotable(x, y_im) and self.isPlotable(prev_x, prev_y_im):
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qp.drawLine(x, y_im, prev_x, prev_y_im)
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elif self.isPlotable(x, y_im) and not self.isPlotable(prev_x, prev_y_im):
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new_x, new_y = self.getPlotable(x, y_im, prev_x, prev_y_im)
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qp.drawLine(x, y_im, new_x, new_y)
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elif not self.isPlotable(x, y_im) and self.isPlotable(prev_x, prev_y_im):
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new_x, new_y = self.getPlotable(prev_x, prev_y_im, x, y_im)
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qp.drawLine(prev_x, prev_y_im, new_x, new_y)
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primary_pen.setColor(self.referenceColor)
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line_pen.setColor(self.referenceColor)
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secondary_pen.setColor(self.secondaryReferenceColor)
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qp.setPen(primary_pen)
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if len(self.reference) > 0:
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c = QtGui.QColor(self.referenceColor)
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c.setAlpha(255)
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pen = QtGui.QPen(c)
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pen.setWidth(2)
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qp.setPen(pen)
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qp.drawLine(20, 14, 25, 14)
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c = QtGui.QColor(self.secondaryReferenceColor)
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c.setAlpha(255)
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pen = QtGui.QPen(c)
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pen.setWidth(2)
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qp.setPen(pen)
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qp.drawLine(self.leftMargin + self.chartWidth, 14, self.leftMargin + self.chartWidth + 5, 14)
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for i in range(len(self.reference)):
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if self.reference[i].freq < fstart or self.reference[i].freq > fstop:
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continue
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x = self.getXPosition(self.reference[i])
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y_re = self.getReYPosition(self.reference[i])
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y_im = self.getImYPosition(self.reference[i])
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qp.setPen(primary_pen)
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if self.isPlotable(x, y_re):
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qp.drawPoint(x, y_re)
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qp.setPen(secondary_pen)
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if self.isPlotable(x, y_im):
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qp.drawPoint(x, y_im)
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if self.drawLines and i > 0:
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prev_x = self.getXPosition(self.reference[i - 1])
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prev_y_re = self.getReYPosition(self.reference[i-1])
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prev_y_im = self.getImYPosition(self.reference[i-1])
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line_pen.setColor(self.referenceColor)
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qp.setPen(line_pen)
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# Real part first
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if self.isPlotable(x, y_re) and self.isPlotable(prev_x, prev_y_re):
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qp.drawLine(x, y_re, prev_x, prev_y_re)
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elif self.isPlotable(x, y_re) and not self.isPlotable(prev_x, prev_y_re):
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new_x, new_y = self.getPlotable(x, y_re, prev_x, prev_y_re)
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qp.drawLine(x, y_re, new_x, new_y)
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elif not self.isPlotable(x, y_re) and self.isPlotable(prev_x, prev_y_re):
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new_x, new_y = self.getPlotable(prev_x, prev_y_re, x, y_re)
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qp.drawLine(prev_x, prev_y_re, new_x, new_y)
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line_pen.setColor(self.secondaryReferenceColor)
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qp.setPen(line_pen)
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# Imag part second
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if self.isPlotable(x, y_im) and self.isPlotable(prev_x, prev_y_im):
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qp.drawLine(x, y_im, prev_x, prev_y_im)
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elif self.isPlotable(x, y_im) and not self.isPlotable(prev_x, prev_y_im):
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new_x, new_y = self.getPlotable(x, y_im, prev_x, prev_y_im)
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qp.drawLine(x, y_im, new_x, new_y)
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elif not self.isPlotable(x, y_im) and self.isPlotable(prev_x, prev_y_im):
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new_x, new_y = self.getPlotable(prev_x, prev_y_im, x, y_im)
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qp.drawLine(prev_x, prev_y_im, new_x, new_y)
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# Now draw the markers
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for m in self.markers:
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if m.location != -1:
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x = self.getXPosition(self.data[m.location])
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y_re = self.getReYPosition(self.data[m.location])
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y_im = self.getImYPosition(self.data[m.location])
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self.drawMarker(x, y_re, qp, m.color, self.markers.index(m)+1)
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self.drawMarker(x, y_im, qp, m.color, self.markers.index(m)+1)
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def getImYPosition(self, d: Datapoint) -> int:
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# TODO: Logarithmic Y positions
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_, im = RFTools.normalize50(d)
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im = im * 10e6 / d.freq
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return self.topMargin + round((self.max - im) / self.span * self.chartHeight)
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def getReYPosition(self, d: Datapoint) -> int:
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re, _ = RFTools.normalize50(d)
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re = re * 10e6 / d.freq
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return self.topMargin + round((self.max - re) / self.span * self.chartHeight)
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def valueAtPosition(self, y) -> List[float]:
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absy = y - self.topMargin
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val = -1 * ((absy / self.chartHeight * self.span) - self.max)
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return [val]
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def getNearestMarker(self, x, y) -> Marker:
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if len(self.data) == 0:
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return None
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shortest = 10**6
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nearest = None
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for m in self.markers:
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mx, _ = self.getPosition(self.data[m.location])
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myr = self.getReYPosition(self.data[m.location])
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myi = self.getImYPosition(self.data[m.location])
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dx = abs(x - mx)
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dy = min(abs(y - myr), abs(y-myi))
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distance = math.sqrt(dx**2 + dy**2)
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if distance < shortest:
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shortest = distance
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nearest = m
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return nearest
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class GroupDelayChart(FrequencyChart):
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def __init__(self, name=""):
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super().__init__(name)
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self.leftMargin = 40
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self.chartWidth = 250
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self.chartHeight = 250
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self.fstart = 0
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self.fstop = 0
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self.minDelay = 0
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self.maxDelay = 0
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self.span = 0
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self.unwrappedData = []
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self.unwrappedReference = []
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self.groupDelay = []
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self.groupDelayReference = []
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self.minDisplayValue = -180
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self.maxDisplayValue = 180
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self.setMinimumSize(self.chartWidth + self.rightMargin + self.leftMargin,
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self.chartHeight + self.topMargin + self.bottomMargin)
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self.setSizePolicy(QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding,
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QtWidgets.QSizePolicy.MinimumExpanding))
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pal = QtGui.QPalette()
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pal.setColor(QtGui.QPalette.Background, self.backgroundColor)
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self.setPalette(pal)
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self.setAutoFillBackground(True)
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def copy(self):
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new_chart: GroupDelayChart = super().copy()
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return new_chart
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def setData(self, data):
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self.data = data
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rawData = []
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for d in self.data:
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rawData.append(RFTools.phaseAngle(d))
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rawReference = []
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for d in self.reference:
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rawReference.append(RFTools.phaseAngle(d))
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if len(self.data) > 0:
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self.unwrappedData = np.unwrap(rawData, 180)
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self.groupDelay = signal.convolve(self.unwrappedData, [1, -1], mode='same')
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# TODO: Modify to show values as ps instead of $undefined?
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if len(self.reference) > 0:
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self.unwrappedReference = np.unwrap(rawReference, 180)
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self.groupDelayReference = signal.convolve(self.unwrappedReference, [1, -1], mode='same')
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self.update()
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def drawChart(self, qp: QtGui.QPainter):
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qp.setPen(QtGui.QPen(self.textColor))
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qp.drawText(3, 15, self.name)
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qp.setPen(QtGui.QPen(self.foregroundColor))
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qp.drawLine(self.leftMargin, 20, self.leftMargin, self.topMargin+self.chartHeight+5)
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qp.drawLine(self.leftMargin-5, self.topMargin+self.chartHeight, self.leftMargin+self.chartWidth, self.topMargin + self.chartHeight)
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def drawValues(self, qp: QtGui.QPainter):
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if len(self.data) == 0 and len(self.reference) == 0:
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return
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pen = QtGui.QPen(self.sweepColor)
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pen.setWidth(self.pointSize)
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line_pen = QtGui.QPen(self.sweepColor)
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line_pen.setWidth(self.lineThickness)
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if self.fixedValues:
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min_delay = self.minDisplayValue
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max_delay = self.maxDisplayValue
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elif self.data:
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min_delay = math.floor(np.min(self.groupDelay))
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max_delay = math.ceil(np.max(self.groupDelay))
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elif self.reference:
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min_delay = math.floor(np.min(self.groupDelayReference))
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max_delay = math.ceil(np.max(self.groupDelayReference))
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span = max_delay - min_delay
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if span == 0:
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span = 0.01
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self.minDelay = min_delay
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self.maxDelay = max_delay
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self.span = span
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tickcount = math.floor(self.chartHeight / 60)
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for i in range(tickcount):
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delay = min_delay + span * i / tickcount
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y = self.topMargin + round((self.maxDelay - delay) / self.span * self.chartHeight)
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if delay != min_delay and delay != max_delay:
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qp.setPen(QtGui.QPen(self.textColor))
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if delay != 0:
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digits = max(0, min(2, math.floor(3 - math.log10(abs(delay)))))
|
||||
if digits == 0:
|
||||
delaystr = str(round(delay))
|
||||
else:
|
||||
delaystr = str(round(delay, digits))
|
||||
else:
|
||||
delaystr = "0"
|
||||
qp.drawText(3, y + 3, delaystr)
|
||||
qp.setPen(QtGui.QPen(self.foregroundColor))
|
||||
qp.drawLine(self.leftMargin - 5, y, self.leftMargin + self.chartWidth, y)
|
||||
qp.drawLine(self.leftMargin - 5, self.topMargin, self.leftMargin + self.chartWidth, self.topMargin)
|
||||
qp.setPen(self.textColor)
|
||||
qp.drawText(3, self.topMargin + 5, str(max_delay))
|
||||
qp.drawText(3, self.chartHeight + self.topMargin, str(min_delay))
|
||||
|
||||
if self.fixedSpan:
|
||||
fstart = self.minFrequency
|
||||
fstop = self.maxFrequency
|
||||
else:
|
||||
if len(self.data) > 0:
|
||||
fstart = self.data[0].freq
|
||||
fstop = self.data[len(self.data)-1].freq
|
||||
else:
|
||||
fstart = self.reference[0].freq
|
||||
fstop = self.reference[len(self.reference) - 1].freq
|
||||
self.fstart = fstart
|
||||
self.fstop = fstop
|
||||
|
||||
# Draw bands if required
|
||||
if self.bands.enabled:
|
||||
self.drawBands(qp, fstart, fstop)
|
||||
|
||||
self.drawFrequencyTicks(qp)
|
||||
|
||||
self.drawData(qp, self.data, self.sweepColor)
|
||||
self.drawData(qp, self.reference, self.referenceColor)
|
||||
self.drawMarkers(qp)
|
||||
|
||||
def getYPosition(self, d: Datapoint) -> int:
|
||||
# TODO: Find a faster way than these expensive "d in self.data" lookups
|
||||
if d in self.data:
|
||||
delay = self.groupDelay[self.data.index(d)]
|
||||
elif d in self.reference:
|
||||
delay = self.groupDelayReference[self.reference.index(d)]
|
||||
else:
|
||||
delay = 0
|
||||
return self.topMargin + round((self.maxDelay - delay) / self.span * self.chartHeight)
|
||||
|
||||
def valueAtPosition(self, y) -> List[float]:
|
||||
absy = y - self.topMargin
|
||||
val = -1 * ((absy / self.chartHeight * self.span) - self.maxDelay)
|
||||
return [val]
|
||||
|
|
|
|||
|
|
@ -31,7 +31,8 @@ from serial.tools import list_ports
|
|||
from .Hardware import VNA, InvalidVNA, Version
|
||||
from .RFTools import RFTools, Datapoint
|
||||
from .Chart import Chart, PhaseChart, VSWRChart, PolarChart, SmithChart, LogMagChart, QualityFactorChart, TDRChart, \
|
||||
RealImaginaryChart, MagnitudeChart, MagnitudeZChart, CombinedLogMagChart, SParameterChart
|
||||
RealImaginaryChart, MagnitudeChart, MagnitudeZChart, CombinedLogMagChart, SParameterChart, PermeabilityChart, \
|
||||
GroupDelayChart
|
||||
from .Calibration import CalibrationWindow, Calibration
|
||||
from .Marker import Marker
|
||||
from .SweepWorker import SweepWorker
|
||||
|
|
@ -132,6 +133,9 @@ class NanoVNASaver(QtWidgets.QWidget):
|
|||
self.s11MagZ = MagnitudeZChart("S11 |Z|")
|
||||
self.s11Phase = PhaseChart("S11 Phase")
|
||||
self.s21Phase = PhaseChart("S21 Phase")
|
||||
self.s11GroupDelay = GroupDelayChart("S11 Group Delay")
|
||||
self.s21GroupDelay = GroupDelayChart("S21 Group Delay")
|
||||
self.permabilityChart = PermeabilityChart("S11 R/\N{GREEK SMALL LETTER OMEGA} & X/\N{GREEK SMALL LETTER OMEGA}")
|
||||
self.s11VSWR = VSWRChart("S11 VSWR")
|
||||
self.s11QualityFactor = QualityFactorChart("S11 Quality Factor")
|
||||
self.s11RealImaginary = RealImaginaryChart("S11 R+jX")
|
||||
|
|
@ -146,10 +150,12 @@ class NanoVNASaver(QtWidgets.QWidget):
|
|||
self.s11charts.append(self.s11Mag)
|
||||
self.s11charts.append(self.s11MagZ)
|
||||
self.s11charts.append(self.s11Phase)
|
||||
self.s11charts.append(self.s11GroupDelay)
|
||||
self.s11charts.append(self.s11VSWR)
|
||||
self.s11charts.append(self.s11RealImaginary)
|
||||
self.s11charts.append(self.s11QualityFactor)
|
||||
self.s11charts.append(self.s11SParameterChart)
|
||||
self.s11charts.append(self.permabilityChart)
|
||||
|
||||
# List of all the S21 charts, for selecting
|
||||
self.s21charts: List[Chart] = []
|
||||
|
|
@ -157,6 +163,7 @@ class NanoVNASaver(QtWidgets.QWidget):
|
|||
self.s21charts.append(self.s21LogMag)
|
||||
self.s21charts.append(self.s21Mag)
|
||||
self.s21charts.append(self.s21Phase)
|
||||
self.s21charts.append(self.s21GroupDelay)
|
||||
self.s21charts.append(self.s21SParameterChart)
|
||||
|
||||
# List of all charts that use both S11 and S21
|
||||
|
|
|
|||
Ładowanie…
Reference in New Issue