#
# Copyright 2008 Free Software Foundation, Inc.
#
# This file is part of GNU Radio
#
# GNU Radio 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, or (at your option)
# any later version.
#
# GNU Radio 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 GNU Radio; see the file COPYING. If not, write to
# the Free Software Foundation, Inc., 51 Franklin Street,
# Boston, MA 02110-1301, USA.
#
##################################################
# Imports
##################################################
import plotter
import common
import wx
import numpy
import math
import pubsub
from constants import *
##################################################
# Constants
##################################################
SLIDER_STEPS = 100
AVG_ALPHA_MIN_EXP, AVG_ALPHA_MAX_EXP = -3, 0
DEFAULT_FRAME_RATE = 30
DEFAULT_WIN_SIZE = (600, 300)
DIV_LEVELS = (1, 2, 5, 10, 20)
MIN_DYNAMIC_RANGE, MAX_DYNAMIC_RANGE = 10, 200
COLOR_MODES = (
('RGB1', 'rgb1'),
('RGB2', 'rgb2'),
('RGB3', 'rgb3'),
('Gray', 'gray'),
)
##################################################
# Waterfall window control panel
##################################################
class control_panel(wx.Panel):
"""!
A control panel with wx widgits to control the plotter and fft block chain.
"""
def __init__(self, parent):
"""!
Create a new control panel.
@param parent the wx parent window
"""
self.parent = parent
wx.Panel.__init__(self, parent, -1, style=wx.SUNKEN_BORDER)
control_box = wx.BoxSizer(wx.VERTICAL)
control_box.AddStretchSpacer()
control_box.Add(common.LabelText(self, 'Options'), 0, wx.ALIGN_CENTER)
#color mode
control_box.AddStretchSpacer()
self.color_mode_chooser = common.DropDownController(self, 'Color', COLOR_MODES, parent, COLOR_MODE_KEY)
control_box.Add(self.color_mode_chooser, 0, wx.EXPAND)
#average
control_box.AddStretchSpacer()
self.average_check_box = common.CheckBoxController(self, 'Average', parent.ext_controller, parent.average_key)
control_box.Add(self.average_check_box, 0, wx.EXPAND)
control_box.AddSpacer(2)
self.avg_alpha_slider = common.LogSliderController(
self, 'Avg Alpha',
AVG_ALPHA_MIN_EXP, AVG_ALPHA_MAX_EXP, SLIDER_STEPS,
parent.ext_controller, parent.avg_alpha_key,
formatter=lambda x: ': %.4f'%x,
)
parent.ext_controller.subscribe(parent.average_key, self.avg_alpha_slider.Enable)
control_box.Add(self.avg_alpha_slider, 0, wx.EXPAND)
#dyanmic range buttons
control_box.AddStretchSpacer()
control_box.Add(common.LabelText(self, 'Dynamic Range'), 0, wx.ALIGN_CENTER)
control_box.AddSpacer(2)
self._dynamic_range_buttons = common.IncrDecrButtons(self, self._on_incr_dynamic_range, self._on_decr_dynamic_range)
control_box.Add(self._dynamic_range_buttons, 0, wx.ALIGN_CENTER)
#ref lvl buttons
control_box.AddStretchSpacer()
control_box.Add(common.LabelText(self, 'Set Ref Level'), 0, wx.ALIGN_CENTER)
control_box.AddSpacer(2)
self._ref_lvl_buttons = common.IncrDecrButtons(self, self._on_incr_ref_level, self._on_decr_ref_level)
control_box.Add(self._ref_lvl_buttons, 0, wx.ALIGN_CENTER)
#num lines buttons
control_box.AddStretchSpacer()
control_box.Add(common.LabelText(self, 'Set Time Scale'), 0, wx.ALIGN_CENTER)
control_box.AddSpacer(2)
self._time_scale_buttons = common.IncrDecrButtons(self, self._on_incr_time_scale, self._on_decr_time_scale)
control_box.Add(self._time_scale_buttons, 0, wx.ALIGN_CENTER)
#autoscale
control_box.AddStretchSpacer()
self.autoscale_button = wx.Button(self, label='Autoscale', style=wx.BU_EXACTFIT)
self.autoscale_button.Bind(wx.EVT_BUTTON, self.parent.autoscale)
control_box.Add(self.autoscale_button, 0, wx.EXPAND)
#clear
self.clear_button = wx.Button(self, label='Clear', style=wx.BU_EXACTFIT)
self.clear_button.Bind(wx.EVT_BUTTON, self._on_clear_button)
control_box.Add(self.clear_button, 0, wx.EXPAND)
#run/stop
self.run_button = common.ToggleButtonController(self, parent, RUNNING_KEY, 'Stop', 'Run')
control_box.Add(self.run_button, 0, wx.EXPAND)
#set sizer
self.SetSizerAndFit(control_box)
##################################################
# Event handlers
##################################################
def _on_clear_button(self, event):
self.parent.set_num_lines(self.parent[NUM_LINES_KEY])
def _on_incr_dynamic_range(self, event):
self.parent.set_dynamic_range(
min(self.parent[DYNAMIC_RANGE_KEY] + 10, MAX_DYNAMIC_RANGE))
def _on_decr_dynamic_range(self, event):
self.parent.set_dynamic_range(
max(self.parent[DYNAMIC_RANGE_KEY] - 10, MIN_DYNAMIC_RANGE))
def _on_incr_ref_level(self, event):
self.parent.set_ref_level(
self.parent[REF_LEVEL_KEY] + self.parent[DYNAMIC_RANGE_KEY]*.1)
def _on_decr_ref_level(self, event):
self.parent.set_ref_level(
self.parent[REF_LEVEL_KEY] - self.parent[DYNAMIC_RANGE_KEY]*.1)
def _on_incr_time_scale(self, event):
old_rate = self.parent.ext_controller[self.parent.frame_rate_key]
self.parent.ext_controller[self.parent.frame_rate_key] *= 0.75
if self.parent.ext_controller[self.parent.frame_rate_key] == old_rate:
self.parent.ext_controller[self.parent.decimation_key] += 1
def _on_decr_time_scale(self, event):
old_rate = self.parent.ext_controller[self.parent.frame_rate_key]
self.parent.ext_controller[self.parent.frame_rate_key] *= 1.25
if self.parent.ext_controller[self.parent.frame_rate_key] == old_rate:
self.parent.ext_controller[self.parent.decimation_key] -= 1
##################################################
# Waterfall window with plotter and control panel
##################################################
class waterfall_window(wx.Panel, pubsub.pubsub, common.prop_setter):
def __init__(
self,
parent,
controller,
size,
title,
real,
fft_size,
num_lines,
decimation_key,
baseband_freq,
sample_rate_key,
frame_rate_key,
dynamic_range,
ref_level,
average_key,
avg_alpha_key,
msg_key,
):
pubsub.pubsub.__init__(self)
#setup
self.ext_controller = controller
self.real = real
self.fft_size = fft_size
self.decimation_key = decimation_key
self.sample_rate_key = sample_rate_key
self.frame_rate_key = frame_rate_key
self.average_key = average_key
self.avg_alpha_key = avg_alpha_key
#init panel and plot
wx.Panel.__init__(self, parent, -1, style=wx.SIMPLE_BORDER)
self.plotter = plotter.waterfall_plotter(self)
self.plotter.SetSize(wx.Size(*size))
self.plotter.set_title(title)
self.plotter.enable_point_label(True)
#setup the box with plot and controls
self.control_panel = control_panel(self)
main_box = wx.BoxSizer(wx.HORIZONTAL)
main_box.Add(self.plotter, 1, wx.EXPAND)
main_box.Add(self.control_panel, 0, wx.EXPAND)
self.SetSizerAndFit(main_box)
#plotter listeners
self.subscribe(COLOR_MODE_KEY, self.plotter.set_color_mode)
self.subscribe(NUM_LINES_KEY, self.plotter.set_num_lines)
#initial setup
self.ext_controller[self.average_key] = self.ext_controller[self.average_key]
self.ext_controller[self.avg_alpha_key] = self.ext_controller[self.avg_alpha_key]
self._register_set_prop(self, DYNAMIC_RANGE_KEY, dynamic_range)
self._register_set_prop(self, NUM_LINES_KEY, num_lines)
self._register_set_prop(self, Y_DIVS_KEY, 8)
self._register_set_prop(self, X_DIVS_KEY, 8) #approximate
self._register_set_prop(self, REF_LEVEL_KEY, ref_level)
self._register_set_prop(self, BASEBAND_FREQ_KEY, baseband_freq)
self._register_set_prop(self, COLOR_MODE_KEY, COLOR_MODES[0][1])
self._register_set_prop(self, RUNNING_KEY, True)
#register events
self.ext_controller.subscribe(msg_key, self.handle_msg)
self.ext_controller.subscribe(self.decimation_key, self.update_grid)
self.ext_controller.subscribe(self.sample_rate_key, self.update_grid)
self.ext_controller.subscribe(self.frame_rate_key, self.update_grid)
self.subscribe(BASEBAND_FREQ_KEY, self.update_grid)
self.subscribe(NUM_LINES_KEY, self.update_grid)
self.subscribe(Y_DIVS_KEY, self.update_grid)
self.subscribe(X_DIVS_KEY, self.update_grid)
#initial update
self.update_grid()
def autoscale(self, *args):
"""!
Autoscale the waterfall plot to the last frame.
Set the dynamic range and reference level.
Does not affect the current data in the waterfall.
"""
#get the peak level (max of the samples)
peak_level = numpy.max(self.samples)
#get the noise floor (averge the smallest samples)
noise_floor = numpy.average(numpy.sort(self.samples)[:len(self.samples)/4])
#padding
noise_floor -= abs(noise_floor)*.5
peak_level += abs(peak_level)*.1
#set the range and level
self.set_ref_level(peak_level)
self.set_dynamic_range(peak_level - noise_floor)
def handle_msg(self, msg):
"""!
Handle the message from the fft sink message queue.
If complex, reorder the fft samples so the negative bins come first.
If real, keep take only the positive bins.
Send the data to the plotter.
@param msg the fft array as a character array
"""
if not self[RUNNING_KEY]: return
#convert to floating point numbers
self.samples = samples = numpy.fromstring(msg, numpy.float32)[:self.fft_size] #only take first frame
num_samps = len(samples)
#reorder fft
if self.real: samples = samples[:num_samps/2]
else: samples = numpy.concatenate((samples[num_samps/2:], samples[:num_samps/2]))
#plot the fft
self.plotter.set_samples(
samples=samples,
minimum=self[REF_LEVEL_KEY] - self[DYNAMIC_RANGE_KEY],
maximum=self[REF_LEVEL_KEY],
)
#update the plotter
self.plotter.update()
def update_grid(self, *args):
"""!
Update the plotter grid.
This update method is dependent on the variables below.
Determine the x and y axis grid parameters.
The x axis depends on sample rate, baseband freq, and x divs.
The y axis depends on y per div, y divs, and ref level.
"""
#grid parameters
sample_rate = self.ext_controller[self.sample_rate_key]
frame_rate = self.ext_controller[self.frame_rate_key]
baseband_freq = self[BASEBAND_FREQ_KEY]
num_lines = self[NUM_LINES_KEY]
y_divs = self[Y_DIVS_KEY]
x_divs = self[X_DIVS_KEY]
#determine best fitting x_per_div
if self.real: x_width = sample_rate/2.0
else: x_width = sample_rate/1.0
x_per_div = common.get_clean_num(x_width/x_divs)
coeff, exp, prefix = common.get_si_components(abs(baseband_freq) + abs(sample_rate/2.0))
#update the x grid
if self.real:
self.plotter.set_x_grid(
baseband_freq,
baseband_freq + sample_rate/2.0,
x_per_div,
10**(-exp),
)
else:
self.plotter.set_x_grid(
baseband_freq - sample_rate/2.0,
baseband_freq + sample_rate/2.0,
x_per_div,
10**(-exp),
)
#update x units
self.plotter.set_x_label('Frequency', prefix+'Hz')
#update y grid
duration = float(num_lines)/frame_rate
y_per_div = common.get_clean_num(duration/y_divs)
self.plotter.set_y_grid(0, duration, y_per_div)
#update y units
self.plotter.set_y_label('Time', 's')
#update plotter
self.plotter.update()