nanovna-saver/NanoVNASaver/Marker/Widget.py

340 wiersze
12 KiB
Python

# NanoVNASaver
# A python program to view and export Touchstone data from a NanoVNA
# Copyright (C) 2019. Rune B. Broberg
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <https://www.gnu.org/licenses/>.
import math
from typing import List
from PyQt5 import QtGui, QtWidgets, QtCore
from PyQt5.QtCore import pyqtSignal
from NanoVNASaver import RFTools
from NanoVNASaver.Formatting import (
format_capacitance,
format_complex_imp,
format_frequency,
format_gain,
format_group_delay,
format_inductance,
format_magnitude,
format_phase,
format_q_factor,
format_resistance,
format_vswr,
)
from NanoVNASaver.Inputs import MarkerFrequencyInputWidget as FrequencyInput
from NanoVNASaver.Marker.Values import TYPES, Value, default_label_ids
COLORS = (
QtGui.QColor(QtCore.Qt.darkGray),
QtGui.QColor(255, 0, 0),
QtGui.QColor(0, 255, 0),
QtGui.QColor(0, 0, 255),
QtGui.QColor(0, 255, 255),
QtGui.QColor(255, 0, 255),
QtGui.QColor(255, 255, 0),
)
class MarkerLabel(QtWidgets.QLabel):
def __init__(self, name):
super().__init__("")
self.name = name
class Marker(QtCore.QObject, Value):
_instances = 0
color: QtGui.QColor = QtGui.QColor()
coloredText = True
location = -1
returnloss_is_positive = False
updated = pyqtSignal(object)
active_labels = []
@classmethod
def count(cls):
return cls._instances
def __init__(self, name: str = "", qsettings: QtCore.QSettings = None):
super(QtCore.QObject, self).__init__()
self.name = name
self.qsettings = qsettings
self.name = name
self.color = QtGui.QColor()
self.index = 0
if self.qsettings:
Marker._instances += 1
Marker.active_labels = self.qsettings.value(
"MarkerFields", defaultValue=default_label_ids())
self.index = Marker._instances
if not self.name:
self.name = f"Marker {Marker._instances}"
# self.freq = RFTools.RFTools.parseFrequency(frequency)
self.frequencyInput = FrequencyInput()
self.frequencyInput.setAlignment(QtCore.Qt.AlignRight)
self.frequencyInput.textEdited.connect(self.setFrequency)
###############################################################
# Data display labels
###############################################################
self.label = {}
for l in TYPES:
self.label[l.label_id] = MarkerLabel(l.name)
self.label['actualfreq'].setMinimumWidth(100)
self.label['returnloss'].setMinimumWidth(80)
###############################################################
# Marker control layout
###############################################################
self.btnColorPicker = QtWidgets.QPushButton("")
self.btnColorPicker.setFixedWidth(20)
self.btnColorPicker.clicked.connect(
lambda: self.setColor(QtWidgets.QColorDialog.getColor(
self.color, options=QtWidgets.QColorDialog.ShowAlphaChannel))
)
self.isMouseControlledRadioButton = QtWidgets.QRadioButton()
self.layout = QtWidgets.QHBoxLayout()
self.layout.addWidget(self.frequencyInput)
self.layout.addWidget(self.btnColorPicker)
self.layout.addWidget(self.isMouseControlledRadioButton)
################################################################################################################
# Data display layout
################################################################################################################
self.group_box = QtWidgets.QGroupBox(self.name)
self.group_box.setMaximumWidth(340)
box_layout = QtWidgets.QHBoxLayout(self.group_box)
try:
self.setColor(
self.qsettings.value(
f"Marker{self.count()}Color", COLORS[self.count()]))
except AttributeError: # happens when qsettings == None
self.setColor(COLORS[1])
except IndexError:
self.setColor(COLORS[0])
line = QtWidgets.QFrame()
line.setFrameShape(QtWidgets.QFrame.VLine)
# line only if more then 3 selected
self.left_form = QtWidgets.QFormLayout()
self.right_form = QtWidgets.QFormLayout()
box_layout.addLayout(self.left_form)
box_layout.addWidget(line)
box_layout.addLayout(self.right_form)
self.buildForm()
def __del__(self):
if self.qsettings:
Marker._instances -= 1
def _add_active_labels(self, label_id, form):
if label_id in self.label:
form.addRow(
f"{self.label[label_id].name}:", self.label[label_id])
self.label[label_id].show()
def _size_str(self) -> str:
return str(self.group_box.font().pointSize())
def update_settings(self):
self.qsettings.setValue(f"Marker{self.index}Color", self.color)
def setScale(self, scale):
self.group_box.setMaximumWidth(int(340 * scale))
self.label['actualfreq'].setMinimumWidth(int(100 * scale))
self.label['actualfreq'].setMinimumWidth(int(100 * scale))
self.label['returnloss'].setMinimumWidth(int(80 * scale))
if self.coloredText:
color_string = QtCore.QVariant(self.color)
color_string.convert(QtCore.QVariant.String)
self.group_box.setStyleSheet(
f"QGroupBox {{ color: {color_string.value()}; "
f"font-size: {self._size_str()}}};"
)
else:
self.group_box.setStyleSheet(
f"QGroupBox {{ font-size: {self._size_str()}}};"
)
def buildForm(self):
while self.left_form.count() > 0:
old_row = self.left_form.takeRow(0)
old_row.fieldItem.widget().hide()
old_row.labelItem.widget().hide()
while self.right_form.count() > 0:
old_row = self.right_form.takeRow(0)
old_row.fieldItem.widget().hide()
old_row.labelItem.widget().hide()
if len(self.active_labels) <= 3:
for label_id in self.active_labels:
self._add_active_labels(label_id, self.left_form)
else:
left_half = math.ceil(len(self.active_labels)/2)
right_half = len(self.active_labels)
for i in range(left_half):
label_id = self.active_labels[i]
self._add_active_labels(label_id, self.left_form)
for i in range(left_half, right_half):
label_id = self.active_labels[i]
self._add_active_labels(label_id, self.right_form)
def setFrequency(self, frequency):
self.freq = RFTools.RFTools.parseFrequency(frequency)
self.updated.emit(self)
def setFieldSelection(self, fields):
self.active_labels = fields[:]
self.buildForm()
def setColor(self, color):
if color.isValid():
self.color = color
p = self.btnColorPicker.palette()
p.setColor(QtGui.QPalette.ButtonText, self.color)
self.btnColorPicker.setPalette(p)
if self.coloredText:
color_string = QtCore.QVariant(color)
color_string.convert(QtCore.QVariant.String)
self.group_box.setStyleSheet(
f"QGroupBox {{ color: {color_string.value()}; "
f"font-size: {self._size_str()}}};"
)
else:
self.group_box.setStyleSheet(
f"QGroupBox {{ font-size: {self._size_str()}}};"
)
def setColoredText(self, colored_text):
self.coloredText = colored_text
self.setColor(self.color)
def getRow(self):
return QtWidgets.QLabel(self.name), self.layout
def findLocation(self, data: List[RFTools.Datapoint]):
self.location = -1
self.frequencyInput.nextFrequency = -1
self.frequencyInput.previousFrequency = -1
datasize = len(data)
if datasize == 0:
# Set the frequency before loading any data
return
min_freq = data[0].freq
max_freq = data[-1].freq
lower_stepsize = data[1].freq - data[0].freq
upper_stepsize = data[-1].freq - data[-2].freq
# We are outside the bounds of the data, so we can't put in a marker
if (self.freq + lower_stepsize/2 < min_freq or
self.freq - upper_stepsize/2 > max_freq):
return
min_distance = max_freq
for i, item in enumerate(data):
if abs(item.freq - self.freq) <= min_distance:
min_distance = abs(item.freq - self.freq)
else:
# We have now started moving away from the nearest point
self.location = i-1
if i < datasize:
self.frequencyInput.nextFrequency = item.freq
if (i-2) >= 0:
self.frequencyInput.previousFrequency = data[i-2].freq
return
# If we still didn't find a best spot, it was the last value
self.location = datasize - 1
self.frequencyInput.previousFrequency = data[-2].freq
def getGroupBox(self) -> QtWidgets.QGroupBox:
return self.group_box
def resetLabels(self):
for v in self.label.values():
v.setText("")
def updateLabels(self,
s11data: List[RFTools.Datapoint],
s21data: List[RFTools.Datapoint]):
if self.location == -1:
return
self.store(self.location, s11data, s21data)
s11 = s11data[self.location]
imp = s11.impedance()
cap_str = format_capacitance(RFTools.impedance_to_capacitance(imp, s11.freq))
ind_str = format_inductance(RFTools.impedance_to_inductance(imp, s11.freq))
imp_p = RFTools.serial_to_parallel(imp)
cap_p_str = format_capacitance(RFTools.impedance_to_capacitance(imp_p, s11.freq))
ind_p_str = format_inductance(RFTools.impedance_to_inductance(imp_p, s11.freq))
if imp.imag < 0:
x_str = cap_str
else:
x_str = ind_str
if imp_p.imag < 0:
x_p_str = cap_p_str
else:
x_p_str = ind_p_str
self.label['actualfreq'].setText(format_frequency(s11.freq))
self.label['admittance'].setText(format_complex_imp(imp_p))
self.label['impedance'].setText(format_complex_imp(imp))
self.label['parc'].setText(cap_p_str)
self.label['parl'].setText(ind_p_str)
self.label['parlc'].setText(x_p_str)
self.label['parr'].setText(format_resistance(imp_p.real))
self.label['returnloss'].setText(
format_gain(s11.gain, self.returnloss_is_positive))
self.label['s11groupdelay'].setText(
format_group_delay(RFTools.groupDelay(s11data, self.location)))
self.label['s11mag'].setText(format_magnitude(abs(s11.z)))
self.label['s11phase'].setText(format_phase(s11.phase))
self.label['s11polar'].setText(
str(round(abs(s11.z), 2)) + "" + format_phase(s11.phase))
self.label['s11q'].setText(format_q_factor(s11.qFactor()))
self.label['s11z'].setText(format_resistance(abs(imp)))
self.label['serc'].setText(cap_str)
self.label['serl'].setText(ind_str)
self.label['serlc'].setText(x_str)
self.label['serr'].setText(format_resistance(imp.real))
self.label['vswr'].setText(format_vswr(s11.vswr))
if len(s21data) == len(s11data):
s21 = s21data[self.location]
self.label['s21gain'].setText(format_gain(s21.gain))
self.label['s21groupdelay'].setText(
format_group_delay(RFTools.groupDelay(s21data, self.location) / 2))
self.label['s21mag'].setText(format_magnitude(abs(s21.z)))
self.label['s21phase'].setText(format_phase(s21.phase))
self.label['s21polar'].setText(
str(round(abs(s21.z), 2)) + "" + format_phase(s21.phase))