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|
#!/usr/bin/env python
#
# Copyright 2004,2005,2007 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.
#
from gnuradio import gr, gru
from gnuradio import usrp
from usrpm import usrp_dbid
from gnuradio import eng_notation
from gnuradio.eng_option import eng_option
from gnuradio.wxgui import stdgui2, ra_fftsink, ra_stripchartsink, ra_waterfallsink, form, slider
from optparse import OptionParser
import wx
import sys
import Numeric
import time
import numpy.fft
import ephem
class app_flow_graph(stdgui2.std_top_block):
def __init__(self, frame, panel, vbox, argv):
stdgui2.std_top_block.__init__(self, frame, panel, vbox, argv)
self.frame = frame
self.panel = panel
parser = OptionParser(option_class=eng_option)
parser.add_option("-R", "--rx-subdev-spec", type="subdev", default=(0, 0),
help="select USRP Rx side A or B (default=A)")
parser.add_option("-d", "--decim", type="int", default=16,
help="set fgpa decimation rate to DECIM [default=%default]")
parser.add_option("-f", "--freq", type="eng_float", default=None,
help="set frequency to FREQ", metavar="FREQ")
parser.add_option("-a", "--avg", type="eng_float", default=1.0,
help="set spectral averaging alpha")
parser.add_option("-i", "--integ", type="eng_float", default=1.0,
help="set integration time")
parser.add_option("-g", "--gain", type="eng_float", default=None,
help="set gain in dB (default is midpoint)")
parser.add_option("-l", "--reflevel", type="eng_float", default=30.0,
help="Set Total power reference level")
parser.add_option("-y", "--division", type="eng_float", default=0.5,
help="Set Total power Y division size")
parser.add_option("-e", "--longitude", type="eng_float", default=-76.02,help="Set Observer Longitude")
parser.add_option("-c", "--latitude", type="eng_float", default=44.85,help="Set Observer Latitude")
parser.add_option("-o", "--observing", type="eng_float", default=0.0,
help="Set observing frequency")
parser.add_option("-x", "--ylabel", default="dB", help="Y axis label")
parser.add_option("-z", "--divbase", type="eng_float", default=0.025, help="Y Division increment base")
parser.add_option("-v", "--stripsize", type="eng_float", default=2400, help="Size of stripchart, in 2Hz samples")
parser.add_option("-F", "--fft_size", type="eng_float", default=1024, help="Size of FFT")
parser.add_option("-N", "--decln", type="eng_float", default=999.99, help="Observing declination")
parser.add_option("-X", "--prefix", default="./")
parser.add_option("-M", "--fft_rate", type="eng_float", default=8.0, help="FFT Rate")
parser.add_option("-A", "--calib_coeff", type="eng_float", default=1.0, help="Calibration coefficient")
parser.add_option("-B", "--calib_offset", type="eng_float", default=0.0, help="Calibration coefficient")
parser.add_option("-W", "--waterfall", action="store_true", default=False, help="Use Waterfall FFT display")
parser.add_option("-S", "--setimode", action="store_true", default=False, help="Enable SETI processing of spectral data")
parser.add_option("-K", "--setik", type="eng_float", default=1.5, help="K value for SETI analysis")
parser.add_option("-T", "--setibandwidth", type="eng_float", default=12500, help="Instantaneous SETI observing bandwidth--must be divisor of 250Khz")
parser.add_option("-Q", "--seti_range", type="eng_float", default=1.0e6, help="Total scan width, in Hz for SETI scans")
parser.add_option("-Z", "--dual_mode", action="store_true",
default=False, help="Dual-polarization mode")
parser.add_option("-I", "--interferometer", action="store_true", default=False, help="Interferometer mode")
parser.add_option("-D", "--switch_mode", action="store_true", default=False, help="Dicke Switching mode")
parser.add_option("-P", "--reference_divisor", type="eng_float", default=1.0, help="Reference Divisor")
parser.add_option("-U", "--ref_fifo", default="@@@@")
(options, args) = parser.parse_args()
self.setimode = options.setimode
self.dual_mode = options.dual_mode
self.interferometer = options.interferometer
self.normal_mode = False
self.switch_mode = options.switch_mode
self.switch_state = 0
self.reference_divisor = options.reference_divisor
self.ref_fifo = options.ref_fifo
if (self.ref_fifo != "@@@@"):
self.ref_fifo_file = open (self.ref_fifo, "w")
modecount = 0
for modes in (self.dual_mode, self.interferometer):
if (modes == True):
modecount = modecount + 1
if (modecount > 1):
print "must select only 1 of --dual_mode, or --interferometer"
sys.exit(1)
self.chartneeded = True
if (self.setimode == True):
self.chartneeded = False
if (self.setimode == True and self.interferometer == True):
print "can't pick both --setimode and --interferometer"
sys.exit(1)
if (self.setimode == True and self.switch_mode == True):
print "can't pick both --setimode and --switch_mode"
sys.exit(1)
if (self.interferometer == True and self.switch_mode == True):
print "can't pick both --interferometer and --switch_mode"
sys.exit(1)
if (modecount == 0):
self.normal_mode = True
self.show_debug_info = True
# Pick up waterfall option
self.waterfall = options.waterfall
# SETI mode stuff
self.setimode = options.setimode
self.seticounter = 0
self.setik = options.setik
self.seti_fft_bandwidth = int(options.setibandwidth)
# Calculate binwidth
binwidth = self.seti_fft_bandwidth / options.fft_size
# Use binwidth, and knowledge of likely chirp rates to set reasonable
# values for SETI analysis code. We assume that SETI signals will
# chirp at somewhere between 0.10Hz/sec and 0.25Hz/sec.
#
# upper_limit is the "worst case"--that is, the case for which we have
# to wait the longest to actually see any drift, due to the quantizing
# on FFT bins.
upper_limit = binwidth / 0.10
self.setitimer = int(upper_limit * 2.00)
self.scanning = True
# Calculate the CHIRP values based on Hz/sec
self.CHIRP_LOWER = 0.10 * self.setitimer
self.CHIRP_UPPER = 0.25 * self.setitimer
# Reset hit counters to 0
self.hitcounter = 0
self.s1hitcounter = 0
self.s2hitcounter = 0
self.avgdelta = 0
# We scan through 2Mhz of bandwidth around the chosen center freq
self.seti_freq_range = options.seti_range
# Calculate lower edge
self.setifreq_lower = options.freq - (self.seti_freq_range/2)
self.setifreq_current = options.freq
# Calculate upper edge
self.setifreq_upper = options.freq + (self.seti_freq_range/2)
# Maximum "hits" in a line
self.nhits = 20
# Number of lines for analysis
self.nhitlines = 4
# We change center frequencies based on nhitlines and setitimer
self.setifreq_timer = self.setitimer * (self.nhitlines * 5)
# Create actual timer
self.seti_then = time.time()
# The hits recording array
self.hits_array = Numeric.zeros((self.nhits,self.nhitlines), Numeric.Float64)
self.hit_intensities = Numeric.zeros((self.nhits,self.nhitlines), Numeric.Float64)
# Calibration coefficient and offset
self.calib_coeff = options.calib_coeff
self.calib_offset = options.calib_offset
if self.calib_offset < -750:
self.calib_offset = -750
if self.calib_offset > 750:
self.calib_offset = 750
if self.calib_coeff < 1:
self.calib_coeff = 1
if self.calib_coeff > 100:
self.calib_coeff = 100
self.integ = options.integ
self.avg_alpha = options.avg
self.gain = options.gain
self.decln = options.decln
# Set initial values for datalogging timed-output
self.continuum_then = time.time()
self.spectral_then = time.time()
# build the graph
self.subdev = [(0, 0), (0,0)]
#
# If SETI mode, we always run at maximum USRP decimation
#
if (self.setimode):
options.decim = 256
if (self.dual_mode == False and self.interferometer == False):
self.u = usrp.source_c(decim_rate=options.decim)
self.u.set_mux(usrp.determine_rx_mux_value(self.u, options.rx_subdev_spec))
# determine the daughterboard subdevice we're using
self.subdev[0] = usrp.selected_subdev(self.u, options.rx_subdev_spec)
self.subdev[1] = self.subdev[0]
self.cardtype = self.subdev[0].dbid()
else:
self.u=usrp.source_c(decim_rate=options.decim, nchan=2)
self.subdev[0] = usrp.selected_subdev(self.u, (0, 0))
self.subdev[1] = usrp.selected_subdev(self.u, (1, 0))
self.cardtype = self.subdev[0].dbid()
self.u.set_mux(0x32103210)
c1 = self.subdev[0].name()
c2 = self.subdev[1].name()
if (c1 != c2):
print "Must have identical cardtypes for --dual_mode or --interferometer"
sys.exit(1)
#
# Set 8-bit mode
#
width = 8
shift = 8
format = self.u.make_format(width, shift)
r = self.u.set_format(format)
# Set initial declination
self.decln = options.decln
input_rate = self.u.adc_freq() / self.u.decim_rate()
#
# Set prefix for data files
#
self.prefix = options.prefix
#
# The lower this number, the fewer sample frames are dropped
# in computing the FFT. A sampled approach is taken to
# computing the FFT of the incoming data, which reduces
# sensitivity. Increasing sensitivity inreases CPU loading.
#
self.fft_rate = options.fft_rate
self.fft_size = int(options.fft_size)
# This buffer is used to remember the most-recent FFT display
# values. Used later by self.write_spectral_data() to write
# spectral data to datalogging files, and by the SETI analysis
# function.
#
self.fft_outbuf = Numeric.zeros(self.fft_size, Numeric.Float64)
#
# If SETI mode, only look at seti_fft_bandwidth
# at a time.
#
if (self.setimode):
self.fft_input_rate = self.seti_fft_bandwidth
#
# Build a decimating bandpass filter
#
self.fft_input_taps = gr.firdes.complex_band_pass (1.0,
input_rate,
-(int(self.fft_input_rate/2)), int(self.fft_input_rate/2), 200,
gr.firdes.WIN_HAMMING, 0)
#
# Compute required decimation factor
#
decimation = int(input_rate/self.fft_input_rate)
self.fft_bandpass = gr.fir_filter_ccc (decimation,
self.fft_input_taps)
else:
self.fft_input_rate = input_rate
# Set up FFT display
if self.waterfall == False:
self.scope = ra_fftsink.ra_fft_sink_c (panel,
fft_size=int(self.fft_size), sample_rate=self.fft_input_rate,
fft_rate=int(self.fft_rate), title="Spectral",
ofunc=self.fft_outfunc, xydfunc=self.xydfunc)
else:
self.scope = ra_waterfallsink.waterfall_sink_c (panel,
fft_size=int(self.fft_size), sample_rate=self.fft_input_rate,
fft_rate=int(self.fft_rate), title="Spectral", ofunc=self.fft_outfunc, size=(1100, 600), xydfunc=self.xydfunc, ref_level=0, span=10)
# Set up ephemeris data
self.locality = ephem.Observer()
self.locality.long = str(options.longitude)
self.locality.lat = str(options.latitude)
# We make notes about Sunset/Sunrise in Continuum log files
self.sun = ephem.Sun()
self.sunstate = "??"
# Set up stripchart display
tit = "Continuum"
if (self.dual_mode != False):
tit = "H+V Continuum"
if (self.interferometer != False):
tit = "East x West Correlation"
self.stripsize = int(options.stripsize)
if self.chartneeded == True:
self.chart = ra_stripchartsink.stripchart_sink_f (panel,
stripsize=self.stripsize,
title=tit,
xlabel="LMST Offset (Seconds)",
scaling=1.0, ylabel=options.ylabel,
divbase=options.divbase)
# Set center frequency
self.centerfreq = options.freq
# Set observing frequency (might be different from actual programmed
# RF frequency)
if options.observing == 0.0:
self.observing = options.freq
else:
self.observing = options.observing
# Remember our input bandwidth
self.bw = input_rate
#
#
# The strip chart is fed at a constant 1Hz rate
#
#
# Call constructors for receive chains
#
if (self.dual_mode == True):
self.setup_dual (self.setimode)
if (self.interferometer == True):
self.setup_interferometer(self.setimode)
if (self.normal_mode == True):
self.setup_normal(self.setimode)
if (self.setimode == True):
self.setup_seti()
self._build_gui(vbox)
# Make GUI agree with command-line
self.integ = options.integ
if self.setimode == False:
self.myform['integration'].set_value(int(options.integ))
self.myform['offset'].set_value(self.calib_offset)
self.myform['dcgain'].set_value(self.calib_coeff)
self.myform['average'].set_value(int(options.avg))
if self.setimode == False:
# Make integrator agree with command line
self.set_integration(int(options.integ))
self.avg_alpha = options.avg
# Make spectral averager agree with command line
if options.avg != 1.0:
self.scope.set_avg_alpha(float(1.0/options.avg))
self.scope.set_average(True)
if self.setimode == False:
# Set division size
self.chart.set_y_per_div(options.division)
# Set reference(MAX) level
self.chart.set_ref_level(options.reflevel)
# set initial values
if options.gain is None:
# if no gain was specified, use the mid-point in dB
g = self.subdev[0].gain_range()
options.gain = float(g[0]+g[1])/2
if options.freq is None:
# if no freq was specified, use the mid-point
r = self.subdev[0].freq_range()
options.freq = float(r[0]+r[1])/2
# Set the initial gain control
self.set_gain(options.gain)
if not(self.set_freq(options.freq)):
self._set_status_msg("Failed to set initial frequency")
# Set declination
self.set_decln (self.decln)
# RF hardware information
self.myform['decim'].set_value(self.u.decim_rate())
self.myform['USB BW'].set_value(self.u.adc_freq() / self.u.decim_rate())
if (self.dual_mode == True):
self.myform['dbname'].set_value(self.subdev[0].name()+'/'+self.subdev[1].name())
else:
self.myform['dbname'].set_value(self.subdev[0].name())
# Set analog baseband filtering, if DBS_RX
if self.cardtype in (usrp_dbid.DBS_RX, usrp_dbid.DBS_RX_REV_2_1):
lbw = (self.u.adc_freq() / self.u.decim_rate()) / 2
if lbw < 1.0e6:
lbw = 1.0e6
self.subdev[0].set_bw(lbw)
self.subdev[1].set_bw(lbw)
# Start the timer for the LMST display and datalogging
self.lmst_timer.Start(1000)
if (self.switch_mode == True):
self.other_timer.Start(330)
def _set_status_msg(self, msg):
self.frame.GetStatusBar().SetStatusText(msg, 0)
def _build_gui(self, vbox):
def _form_set_freq(kv):
# Adjust current SETI frequency, and limits
self.setifreq_lower = kv['freq'] - (self.seti_freq_range/2)
self.setifreq_current = kv['freq']
self.setifreq_upper = kv['freq'] + (self.seti_freq_range/2)
# Reset SETI analysis timer
self.seti_then = time.time()
# Zero-out hits array when changing frequency
self.hits_array[:,:] = 0.0
self.hit_intensities[:,:] = -60.0
return self.set_freq(kv['freq'])
def _form_set_decln(kv):
return self.set_decln(kv['decln'])
# Position the FFT display
vbox.Add(self.scope.win, 15, wx.EXPAND)
if self.setimode == False:
# Position the Total-power stripchart
vbox.Add(self.chart.win, 15, wx.EXPAND)
# add control area at the bottom
self.myform = myform = form.form()
hbox = wx.BoxSizer(wx.HORIZONTAL)
hbox.Add((7,0), 0, wx.EXPAND)
vbox1 = wx.BoxSizer(wx.VERTICAL)
myform['freq'] = form.float_field(
parent=self.panel, sizer=vbox1, label="Center freq", weight=1,
callback=myform.check_input_and_call(_form_set_freq, self._set_status_msg))
vbox1.Add((4,0), 0, 0)
myform['lmst_high'] = form.static_text_field(
parent=self.panel, sizer=vbox1, label="Current LMST", weight=1)
vbox1.Add((4,0), 0, 0)
if self.setimode == False:
myform['spec_data'] = form.static_text_field(
parent=self.panel, sizer=vbox1, label="Spectral Cursor", weight=1)
vbox1.Add((4,0), 0, 0)
vbox2 = wx.BoxSizer(wx.VERTICAL)
if self.setimode == False:
vbox3 = wx.BoxSizer(wx.VERTICAL)
g = self.subdev[0].gain_range()
myform['gain'] = form.slider_field(parent=self.panel, sizer=vbox2, label="RF Gain",
weight=1,
min=int(g[0]), max=int(g[1]),
callback=self.set_gain)
vbox2.Add((4,0), 0, 0)
if self.setimode == True:
max_savg = 100
else:
max_savg = 3000
myform['average'] = form.slider_field(parent=self.panel, sizer=vbox2,
label="Spectral Averaging (FFT frames)", weight=1, min=1, max=max_savg, callback=self.set_averaging)
# Set up scan control button when in SETI mode
if (self.setimode == True):
# SETI scanning control
buttonbox = wx.BoxSizer(wx.HORIZONTAL)
self.scan_control = form.button_with_callback(self.panel,
label="Scan: On ",
callback=self.toggle_scanning)
buttonbox.Add(self.scan_control, 0, wx.CENTER)
vbox2.Add(buttonbox, 0, wx.CENTER)
vbox2.Add((4,0), 0, 0)
if self.setimode == False:
myform['integration'] = form.slider_field(parent=self.panel, sizer=vbox2,
label="Continuum Integration Time (sec)", weight=1, min=1, max=180, callback=self.set_integration)
vbox2.Add((4,0), 0, 0)
myform['decln'] = form.float_field(
parent=self.panel, sizer=vbox2, label="Current Declination", weight=1,
callback=myform.check_input_and_call(_form_set_decln))
vbox2.Add((4,0), 0, 0)
if self.setimode == False:
myform['offset'] = form.slider_field(parent=self.panel, sizer=vbox3,
label="Post-Detector Offset", weight=1, min=-750, max=750,
callback=self.set_pd_offset)
vbox3.Add((2,0), 0, 0)
myform['dcgain'] = form.slider_field(parent=self.panel, sizer=vbox3,
label="Post-Detector Gain", weight=1, min=1, max=100,
callback=self.set_pd_gain)
vbox3.Add((2,0), 0, 0)
hbox.Add(vbox1, 0, 0)
hbox.Add(vbox2, wx.ALIGN_RIGHT, 0)
if self.setimode == False:
hbox.Add(vbox3, wx.ALIGN_RIGHT, 0)
vbox.Add(hbox, 0, wx.EXPAND)
self._build_subpanel(vbox)
self.lmst_timer = wx.PyTimer(self.lmst_timeout)
self.other_timer = wx.PyTimer(self.other_timeout)
def _build_subpanel(self, vbox_arg):
# build a secondary information panel (sometimes hidden)
# FIXME figure out how to have this be a subpanel that is always
# created, but has its visibility controlled by foo.Show(True/False)
if not(self.show_debug_info):
return
panel = self.panel
vbox = vbox_arg
myform = self.myform
#panel = wx.Panel(self.panel, -1)
#vbox = wx.BoxSizer(wx.VERTICAL)
hbox = wx.BoxSizer(wx.HORIZONTAL)
hbox.Add((5,0), 0)
myform['decim'] = form.static_float_field(
parent=panel, sizer=hbox, label="Decim")
hbox.Add((5,0), 1)
myform['USB BW'] = form.static_float_field(
parent=panel, sizer=hbox, label="USB BW")
hbox.Add((5,0), 1)
myform['dbname'] = form.static_text_field(
parent=panel, sizer=hbox)
hbox.Add((5,0), 1)
myform['baseband'] = form.static_float_field(
parent=panel, sizer=hbox, label="Analog BB")
hbox.Add((5,0), 1)
myform['ddc'] = form.static_float_field(
parent=panel, sizer=hbox, label="DDC")
hbox.Add((5,0), 0)
vbox.Add(hbox, 0, wx.EXPAND)
def set_freq(self, target_freq):
"""
Set the center frequency we're interested in.
@param target_freq: frequency in Hz
@rypte: bool
Tuning is a two step process. First we ask the front-end to
tune as close to the desired frequency as it can. Then we use
the result of that operation and our target_frequency to
determine the value for the digital down converter.
"""
#
# Everything except BASIC_RX should support usrp.tune()
#
if not (self.cardtype == usrp_dbid.BASIC_RX):
r = usrp.tune(self.u, self.subdev[0]._which, self.subdev[0], target_freq)
r = usrp.tune(self.u, self.subdev[1]._which, self.subdev[1], target_freq)
else:
r = self.u.set_rx_freq(0, target_freq)
f = self.u.rx_freq(0)
if abs(f-target_freq) > 2.0e3:
r = 0
if r:
self.myform['freq'].set_value(target_freq) # update displayed value
#
# Make sure calibrator knows our target freq
#
# Remember centerfreq---used for doppler calcs
delta = self.centerfreq - target_freq
self.centerfreq = target_freq
self.observing -= delta
self.scope.set_baseband_freq (self.observing)
self.myform['baseband'].set_value(r.baseband_freq)
self.myform['ddc'].set_value(r.dxc_freq)
return True
return False
def set_decln(self, dec):
self.decln = dec
self.myform['decln'].set_value(dec) # update displayed value
def set_gain(self, gain):
self.myform['gain'].set_value(gain) # update displayed value
self.subdev[0].set_gain(gain)
self.subdev[1].set_gain(gain)
self.gain = gain
def set_averaging(self, avval):
self.myform['average'].set_value(avval)
self.scope.set_avg_alpha(1.0/(avval))
self.scope.set_average(True)
self.avg_alpha = avval
def set_integration(self, integval):
if self.setimode == False:
self.integrator.set_taps(1.0/((integval)*(self.bw/2)))
self.myform['integration'].set_value(integval)
self.integ = integval
#
# Timeout function
# Used to update LMST display, as well as current
# continuum value
#
# We also write external data-logging files here
#
def lmst_timeout(self):
self.locality.date = ephem.now()
if self.setimode == False:
x = self.probe.level()
sidtime = self.locality.sidereal_time()
# LMST
s = str(ephem.hours(sidtime)) + " " + self.sunstate
# Continuum detector value
if self.setimode == False:
sx = "%7.4f" % x
s = s + "\nDet: " + str(sx)
else:
sx = "%2d" % self.hitcounter
s1 = "%2d" % self.s1hitcounter
s2 = "%2d" % self.s2hitcounter
sa = "%4.2f" % self.avgdelta
sy = "%3.1f-%3.1f" % (self.CHIRP_LOWER, self.CHIRP_UPPER)
s = s + "\nHits: " + str(sx) + "\nS1:" + str(s1) + " S2:" + str(s2)
s = s + "\nAv D: " + str(sa) + "\nCh lim: " + str(sy)
self.myform['lmst_high'].set_value(s)
#
# Write data out to recording files
#
if self.setimode == False:
self.write_continuum_data(x,sidtime)
self.write_spectral_data(self.fft_outbuf,sidtime)
else:
self.seti_analysis(self.fft_outbuf,sidtime)
now = time.time()
if ((self.scanning == True) and ((now - self.seti_then) > self.setifreq_timer)):
self.seti_then = now
self.setifreq_current = self.setifreq_current + self.fft_input_rate
if (self.setifreq_current > self.setifreq_upper):
self.setifreq_current = self.setifreq_lower
self.set_freq(self.setifreq_current)
# Make sure we zero-out the hits array when changing
# frequency.
self.hits_array[:,:] = 0.0
self.hit_intensities[:,:] = 0.0
def other_timeout(self):
if (self.switch_state == 0):
self.switch_state = 1
elif (self.switch_state == 1):
self.switch_state = 0
if (self.switch_state == 0):
self.mute.set_n(1)
self.cmute.set_n(int(1.0e9))
elif (self.switch_state == 1):
self.mute.set_n(int(1.0e9))
self.cmute.set_n(1)
if (self.ref_fifo != "@@@@"):
self.ref_fifo_file.write(str(self.switch_state)+"\n")
self.ref_fifo_file.flush()
self.avg_reference_value = self.cprobe.level()
#
# Set reference value
#
self.reference_level.set_k(-1.0 * (self.avg_reference_value/self.reference_divisor))
def fft_outfunc(self,data,l):
self.fft_outbuf=data
def write_continuum_data(self,data,sidtime):
# Create localtime structure for producing filename
foo = time.localtime()
pfx = self.prefix
filenamestr = "%s/%04d%02d%02d%02d" % (pfx, foo.tm_year,
foo.tm_mon, foo.tm_mday, foo.tm_hour)
# Open the data file, appending
continuum_file = open (filenamestr+".tpdat","a")
flt = "%6.3f" % data
inter = self.decln
integ = self.integ
fc = self.observing
fc = fc / 1000000
bw = self.bw
bw = bw / 1000000
ga = self.gain
now = time.time()
#
# If time to write full header info (saves storage this way)
#
if (now - self.continuum_then > 20):
self.sun.compute(self.locality)
enow = ephem.now()
sun_insky = "Down"
self.sunstate = "Dn"
if ((self.sun.rise_time < enow) and (enow < self.sun.set_time)):
sun_insky = "Up"
self.sunstate = "Up"
self.continuum_then = now
continuum_file.write(str(ephem.hours(sidtime))+" "+flt+" Dn="+str(inter)+",")
continuum_file.write("Ti="+str(integ)+",Fc="+str(fc)+",Bw="+str(bw))
continuum_file.write(",Ga="+str(ga)+",Sun="+str(sun_insky)+"\n")
else:
continuum_file.write(str(ephem.hours(sidtime))+" "+flt+"\n")
continuum_file.close()
return(data)
def write_spectral_data(self,data,sidtime):
now = time.time()
delta = 10
# If time to write out spectral data
# We don't write this out every time, in order to
# save disk space. Since the spectral data are
# typically heavily averaged, writing this data
# "once in a while" is OK.
#
if (now - self.spectral_then >= delta):
self.spectral_then = now
# Get localtime structure to make filename from
foo = time.localtime()
pfx = self.prefix
filenamestr = "%s/%04d%02d%02d%02d" % (pfx, foo.tm_year,
foo.tm_mon, foo.tm_mday, foo.tm_hour)
# Open the file
spectral_file = open (filenamestr+".sdat","a")
# Setup data fields to be written
r = data
inter = self.decln
fc = self.observing
fc = fc / 1000000
bw = self.bw
bw = bw / 1000000
av = self.avg_alpha
# Write those fields
spectral_file.write("data:"+str(ephem.hours(sidtime))+" Dn="+str(inter)+",Fc="+str(fc)+",Bw="+str(bw)+",Av="+str(av))
spectral_file.write (" [ ")
for r in data:
spectral_file.write(" "+str(r))
spectral_file.write(" ]\n")
spectral_file.close()
return(data)
return(data)
def seti_analysis(self,fftbuf,sidtime):
l = len(fftbuf)
x = 0
hits = []
hit_intensities = []
if self.seticounter < self.setitimer:
self.seticounter = self.seticounter + 1
return
else:
self.seticounter = 0
# Run through FFT output buffer, computing standard deviation (Sigma)
avg = 0
# First compute average
for i in range(0,l):
avg = avg + fftbuf[i]
avg = avg / l
sigma = 0.0
# Then compute standard deviation (Sigma)
for i in range(0,l):
d = fftbuf[i] - avg
sigma = sigma + (d*d)
sigma = Numeric.sqrt(sigma/l)
#
# Snarfle through the FFT output buffer again, looking for
# outlying data points
start_f = self.observing - (self.fft_input_rate/2)
current_f = start_f
l = len(fftbuf)
f_incr = self.fft_input_rate / l
hit = -1
# -nyquist to DC
for i in range(l/2,l):
#
# If current FFT buffer has an item that exceeds the specified
# sigma
#
if ((fftbuf[i] - avg) > (self.setik * sigma)):
hits.append(current_f)
hit_intensities.append(fftbuf[i])
current_f = current_f + f_incr
# DC to nyquist
for i in range(0,l/2):
#
# If current FFT buffer has an item that exceeds the specified
# sigma
#
if ((fftbuf[i] - avg) > (self.setik * sigma)):
hits.append(current_f)
hit_intensities.append(fftbuf[i])
current_f = current_f + f_incr
# No hits
if (len(hits) <= 0):
return
#
# OK, so we have some hits in the FFT buffer
# They'll have a rather substantial gauntlet to run before
# being declared a real "hit"
#
# Update stats
self.s1hitcounter = self.s1hitcounter + len(hits)
# Weed out buffers with an excessive number of
# signals above Sigma
if (len(hits) > self.nhits):
return
# Weed out FFT buffers with apparent multiple narrowband signals
# separated significantly in frequency. This means that a
# single signal spanning multiple bins is OK, but a buffer that
# has multiple, apparently-separate, signals isn't OK.
#
last = hits[0]
ns2 = 1
for i in range(1,len(hits)):
if ((hits[i] - last) > (f_incr*3.0)):
return
last = hits[i]
ns2 = ns2 + 1
self.s2hitcounter = self.s2hitcounter + ns2
#
# Run through all available hit buffers, computing difference between
# frequencies found there, if they're all within the chirp limits
# declare a good hit
#
good_hit = False
f_ds = Numeric.zeros(self.nhitlines, Numeric.Float64)
avg_delta = 0
k = 0
for i in range(0,min(len(hits),len(self.hits_array[:,0]))):
f_ds[0] = abs(self.hits_array[i,0] - hits[i])
for j in range(1,len(f_ds)):
f_ds[j] = abs(self.hits_array[i,j] - self.hits_array[i,0])
avg_delta = avg_delta + f_ds[j]
k = k + 1
if (self.seti_isahit (f_ds)):
good_hit = True
self.hitcounter = self.hitcounter + 1
break
if (avg_delta/k < (self.seti_fft_bandwidth/2)):
self.avgdelta = avg_delta / k
# Save 'n shuffle hits
# Old hit buffers percolate through the hit buffers
# (there are self.nhitlines of these buffers)
# and then drop off the end
# A consequence is that while the nhitlines buffers are filling,
# you can get some absurd values for self.avgdelta, because some
# of the buffers are full of zeros
for i in range(self.nhitlines,1):
self.hits_array[:,i] = self.hits_array[:,i-1]
self.hit_intensities[:,i] = self.hit_intensities[:,i-1]
for i in range(0,len(hits)):
self.hits_array[i,0] = hits[i]
self.hit_intensities[i,0] = hit_intensities[i]
# Finally, write the hits/intensities buffer
if (good_hit):
self.write_hits(sidtime)
return
def seti_isahit(self,fdiffs):
truecount = 0
for i in range(0,len(fdiffs)):
if (fdiffs[i] >= self.CHIRP_LOWER and fdiffs[i] <= self.CHIRP_UPPER):
truecount = truecount + 1
if truecount == len(fdiffs):
return (True)
else:
return (False)
def write_hits(self,sidtime):
# Create localtime structure for producing filename
foo = time.localtime()
pfx = self.prefix
filenamestr = "%s/%04d%02d%02d%02d" % (pfx, foo.tm_year,
foo.tm_mon, foo.tm_mday, foo.tm_hour)
# Open the data file, appending
hits_file = open (filenamestr+".seti","a")
# Write sidtime first
hits_file.write(str(ephem.hours(sidtime))+" "+str(self.decln)+" ")
#
# Then write the hits/hit intensities buffers with enough
# "syntax" to allow parsing by external (not yet written!)
# "stuff".
#
for i in range(0,self.nhitlines):
hits_file.write(" ")
for j in range(0,self.nhits):
hits_file.write(str(self.hits_array[j,i])+":")
hits_file.write(str(self.hit_intensities[j,i])+",")
hits_file.write("\n")
hits_file.close()
return
def xydfunc(self,xyv):
if self.setimode == True:
return
magn = int(Numeric.log10(self.observing))
if (magn == 6 or magn == 7 or magn == 8):
magn = 6
dfreq = xyv[0] * pow(10.0,magn)
ratio = self.observing / dfreq
vs = 1.0 - ratio
vs *= 299792.0
if magn >= 9:
xhz = "Ghz"
elif magn >= 6:
xhz = "Mhz"
elif magn <= 5:
xhz = "Khz"
s = "%.6f%s\n%.3fdB" % (xyv[0], xhz, xyv[1])
s2 = "\n%.3fkm/s" % vs
self.myform['spec_data'].set_value(s+s2)
def xydfunc_waterfall(self,pos):
lower = self.observing - (self.seti_fft_bandwidth / 2)
upper = self.observing + (self.seti_fft_bandwidth / 2)
binwidth = self.seti_fft_bandwidth / 1024
s = "%.6fMHz" % ((lower + (pos.x*binwidth)) / 1.0e6)
self.myform['spec_data'].set_value(s)
def toggle_cal(self):
if (self.calstate == True):
self.calstate = False
self.u.write_io(0,0,(1<<15))
self.calibrator.SetLabel("Calibration Source: Off")
else:
self.calstate = True
self.u.write_io(0,(1<<15),(1<<15))
self.calibrator.SetLabel("Calibration Source: On")
def toggle_annotation(self):
if (self.annotate_state == True):
self.annotate_state = False
self.annotation.SetLabel("Annotation: Off")
else:
self.annotate_state = True
self.annotation.SetLabel("Annotation: On")
#
# Turn scanning on/off
# Called-back by "Recording" button
#
def toggle_scanning(self):
# Current scanning? Flip state
if (self.scanning == True):
self.scanning = False
self.scan_control.SetLabel("Scan: Off")
# Not scanning
else:
self.scanning = True
self.scan_control.SetLabel("Scan: On ")
def set_pd_offset(self,offs):
self.myform['offset'].set_value(offs)
self.calib_offset=offs
x = self.calib_coeff / 100.0
self.cal_offs.set_k(offs*(x*8000))
def set_pd_gain(self,gain):
self.myform['dcgain'].set_value(gain)
self.cal_mult.set_k(gain*0.01)
self.calib_coeff = gain
x = gain/100.0
self.cal_offs.set_k(self.calib_offset*(x*8000))
def compute_notch_taps(self,notchlist):
NOTCH_TAPS = 256
tmptaps = Numeric.zeros(NOTCH_TAPS,Numeric.Complex64)
binwidth = self.bw / NOTCH_TAPS
for i in range(0,NOTCH_TAPS):
tmptaps[i] = complex(1.0,0.0)
for i in notchlist:
diff = i - self.observing
if i == 0:
break
if (diff > 0):
idx = diff / binwidth
idx = int(idx)
if (idx < 0 or idx > (NOTCH_TAPS/2)):
break
tmptaps[idx] = complex(0.0, 0.0)
if (diff < 0):
idx = -diff / binwidth
idx = (NOTCH_TAPS/2) - idx
idx = int(idx+(NOTCH_TAPS/2))
if (idx < 0 or idx > (NOTCH_TAPS)):
break
tmptaps[idx] = complex(0.0, 0.0)
self.notch_taps = numpy.fft.ifft(tmptaps)
#
# Setup common pieces of radiometer mode
#
def setup_radiometer_common(self):
# The IIR integration filter for post-detection
self.integrator = gr.single_pole_iir_filter_ff(1.0)
self.integrator.set_taps (1.0/self.bw)
# Signal probe
self.probe = gr.probe_signal_f()
#
# Continuum calibration stuff
#
x = self.calib_coeff/100.0
self.cal_mult = gr.multiply_const_ff(self.calib_coeff/100.0)
self.cal_offs = gr.add_const_ff(self.calib_offset*(x*8000))
#
# Mega decimator after IIR filter
#
if (self.switch_mode == False):
self.keepn = gr.keep_one_in_n(gr.sizeof_float, self.bw)
else:
self.keepn = gr.keep_one_in_n(gr.sizeof_float, int(self.bw/2))
#
# For the Dicke-switching scheme
#
self.switch = gr.multiply_const_ff(1.0)
#
if (self.switch_mode == True):
self.vector = gr.vector_sink_f()
self.swkeep = gr.keep_one_in_n(gr.sizeof_float, int(self.bw/3))
self.mute = gr.keep_one_in_n(gr.sizeof_float, 1)
self.cmute = gr.keep_one_in_n(gr.sizeof_float, int(1.0e9))
self.cintegrator = gr.single_pole_iir_filter_ff(1.0/(self.bw/2))
self.cprobe = gr.probe_signal_f()
else:
self.mute = gr.multiply_const_ff(1.0)
self.avg_reference_value = 0.0
self.reference_level = gr.add_const_ff(0.0)
#
# Setup ordinary single-channel radiometer mode
#
def setup_normal(self, setimode):
self.head = self.u
self.shead = self.u
if setimode == False:
self.detector = gr.complex_to_mag_squared()
self.setup_radiometer_common()
self.connect(self.shead, self.scope)
self.connect(self.head, self.detector, self.mute, self.reference_level,
self.integrator, self.keepn, self.cal_mult, self.cal_offs, self.chart)
self.connect(self.cal_offs, self.probe)
#
# Add a side-chain detector chain, with a different integrator, for sampling
# The reference channel data
# This is used to derive the offset value for self.reference_level, used above
#
if (self.switch_mode == True):
self.connect(self.detector, self.cmute, self.cintegrator, self.swkeep, self.cprobe)
return
#
# Setup dual-channel (two antenna, usual orthogonal polarity probes in the same waveguide)
#
def setup_dual(self, setimode):
self.di = gr.deinterleave(gr.sizeof_gr_complex)
self.addchans = gr.add_cc ()
self.detector = gr.add_ff ()
self.h_power = gr.complex_to_mag_squared()
self.v_power = gr.complex_to_mag_squared()
self.connect (self.u, self.di)
#
# For spectral, adding the two channels works, assuming no gross
# phase or amplitude error
self.connect ((self.di, 0), (self.addchans, 0))
self.connect ((self.di, 1), (self.addchans, 1))
#
# Connect heads of spectral and total-power chains
#
self.head = self.di
self.shead = self.addchans
if (setimode == False):
self.setup_radiometer_common()
#
# For dual-polarization mode, we compute the sum of the
# powers on each channel, after they've been detected
#
self.detector = gr.add_ff()
#
# In dual-polarization mode, we compute things a little differently
# In effect, we have two radiometer chains, terminating in an adder
#
self.connect((self.di, 0), self.h_power)
self.connect((self.di, 1), self.v_power)
self.connect(self.h_power, (self.detector, 0))
self.connect(self.v_power, (self.detector, 1))
self.connect(self.detector, self.mute, self.reference_level,
self.integrator, self.keepn, self.cal_mult, self.cal_offs, self.chart)
self.connect(self.cal_offs, self.probe)
self.connect(self.shead, self.scope)
#
# Add a side-chain detector chain, with a different integrator, for sampling
# The reference channel data
# This is used to derive the offset value for self.reference_level, used above
#
if (self.switch_mode == True):
self.connect(self.detector, self.cmute, self.cintegrator, self.swkeep, self.cprobe)
return
#
# Setup correlating interferometer mode
#
def setup_interferometer(self, setimode):
self.setup_radiometer_common()
self.di = gr.deinterleave(gr.sizeof_gr_complex)
self.connect (self.u, self.di)
self.corr = gr.multiply_cc()
self.c2f = gr.complex_to_float()
self.shead = (self.di, 0)
# Channel 0 to multiply port 0
# Channel 1 to multiply port 1
self.connect((self.di, 0), (self.corr, 0))
self.connect((self.di, 1), (self.corr, 1))
#
# Multiplier (correlator) to complex-to-float, followed by integrator, etc
#
self.connect(self.corr, self.c2f, self.switch, self.integrator, self.keepn, self.cal_mult, self.cal_offs, self.chart)
#
# FFT scope gets only 1 channel
# FIX THIS, by cross-correlating the *outputs* of two different FFTs, then display
# Funky!
#
self.connect(self.shead, self.scope)
#
# Output of correlator/integrator chain to probe
#
self.connect(self.cal_offs, self.probe)
return
#
# Setup SETI mode
#
def setup_seti(self):
self.connect (self.shead, self.fft_bandpass, self.scope)
return
def main ():
app = stdgui2.stdapp(app_flow_graph, "RADIO ASTRONOMY SPECTRAL/CONTINUUM RECEIVER: $Revision$", nstatus=1)
app.MainLoop()
if __name__ == '__main__':
main ()
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