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decode_meteorm2.py
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decode_meteorm2.py
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'''
Funcube
'''
from directdemod import source, sink, chunker, comm, constants, filters
import numpy as np
import logging
import scipy.signal as signal
#import matplotlib.pylab as plt
import math, time
## Inspired from: https://github.com/dbdexter-dev/meteor_demod
# Thank you!
################# OBJECTS
class agc():
def __init__(self):
self.mean = 3.0
self.dc = 0.0
def adjust(self, inp):
# moving avg to get dc
self.dc = ((self.dc * ((1024*1024)-1)*1.0) + inp) / (1024*1024*1.0)
inp -= self.dc
# moving avg of amplitude
self.mean = (self.mean * 1.0 * (65536.0 - 1) + ((np.real(inp)*np.real(inp) + np.imag(inp)*np.imag(inp))**0.5)) / 65536.0
# multiply the input value
if 180.0 / self.mean > 200:
return inp * 200
else:
return inp * 180.0 / self.mean
class costas():
def __init__(self):
self.freq = 0.001
self.phase = 0.00
self.output = np.exp(-1j*self.phase)
self.damping = 0.70710678118
self.bw = 0.008727
self.compAlphaBeta(self.damping, self.bw)
self.mean = 1.0
self.plllock = False
self.hypstore = []
for i in range(256):
self.hypstore.append(np.tanh(i-128))
def compAlphaBeta(self, damping, bw):
denom = (1.0 + 2.0*damping*bw + bw*bw)
self.alpha = (4*damping*bw)/denom
self.beta = (4*bw*bw)/denom
def loop(self, samp):
self.output = np.exp(-1j*self.phase)
correctedIn = samp * self.output
error = (np.imag(correctedIn) * self.hyp(np.real(correctedIn)) - np.real(correctedIn) * self.hyp(np.imag(correctedIn)))/255.0
self.mean = (self.mean * (39999.0) + np.abs(error))/40000.0
if error > 1:
error = 1.0
elif (error < -1):
error = -1.0
self.phase = math.fmod(self.phase + self.freq + self.alpha*error, 2*np.pi)
self.freq = self.freq + self.beta*error
if not self.plllock and self.mean < 0.2:
self.compAlphaBeta(self.damping, self.bw/2.0)
self.plllock = True
elif self.plllock and self.mean > 0.5:
self.compAlphaBeta(self.damping, self.bw)
self.plllock = False
return correctedIn
def hyp(self, x):
if x > 127: return 1
if x < -128: return -1
return self.hypstore[int(x+128)]
def lim(x):
if x < -128.0:
return -128
if x > 127.0:
return 127
if x > 0 and x < 1:
return 1
if x > -1 and x < 0:
return -1
return int(x)
def limBin(x):
if x <= 0:
return 0
else:
return 1
'''
Object to Meteor m2
'''
class decode_meteorm2:
'''
Object to decode Meteor m2
'''
def __init__(self, sigsrc, offset, bw):
'''Initialize the object
Args:
sigsrc (:obj:`commSignal`): IQ data source
offset (:obj:`float`): Frequency offset of source in Hz
bw (:obj:`int`, optional): Bandwidth
'''
self.__bw = bw
if self.__bw is None:
self.__bw = 70000
self.__sigsrc = sigsrc
self.__offset = offset
self.__useful = 0
@property
def useful(self):
'''See if signal was found
Returns:
:obj:`int`: 0 if not found, 1 if found
'''
return self.__useful
@property
def getSyncs(self):
'''Get syncs of Meteor M2
Returns:
:obj:`list`: list of detected syncs
'''
# create chunker object
chunkerObj = chunker.chunker(self.__sigsrc)
# butter filter
bf = filters.butter(self.__sigsrc.sampFreq, self.__bw)
# init vars for gardner
symbolPeriod = self.__sigsrc.sampFreq/72000
timing = 0.00
gardnerC, gardnerB, gardnerA = 0.00, 0.00, 0.00
agcObj = agc()
pllObj = costas()
ctr = 0
sync = [int(i) for i in "0, 13, 13, 12, 13, 13, 13, 0, 0, 0, 13, 13, 0, 13, 13, 0, 13, 0, 0, 0, 13, 13, 13, 0, 0, 13, 0, 13, 0, 13, 0, 13, 13, 0, 0, 0, 13, 13, 0, 0, 0, 0, 13, 0, 13, 13, 0, 0, 0, 0, 0, 13, 1, 13, 0, 13, 13, 13, 13, 12, 0, 13, 0, 13, 0, 0, 13, 0, 13, 0, 13, 13, 0, 13, 13, 13, 0, 0, 0, 0, 13, 0, 13, 0, 13, 13, 13, 13, 13, 0, 13, 13, 13, 0, 0, 0, 0, 13, 13, 13, 0, 13, 0, 0, 0, 13, 0, 13, 13, 0, 13, 0, 13, 13, 0, 0, 0, 13, 13, 13".split(",")]
sync = np.array(sync)
sync[sync < 7] = 0
sync[sync >= 7] = 1
sync72khz = np.repeat(sync, 1)
sync72khz1 = []
for i in range(len(sync72khz)):
if i%2 == 0:
sync72khz1.append(sync72khz[i])
else:
sync72khz1.append(1-sync72khz[i])
sync72khz1 = np.array(sync72khz1)
sync72khz2 = []
for i in range(len(sync72khz)):
if i%2 == 1:
sync72khz2.append(sync72khz[i])
else:
sync72khz2.append(1-sync72khz[i])
sync72khz2 = np.array(sync72khz2)
sync[sync == 1] = 127
sync[sync == 0] = -128
sync2mhz = np.repeat(sync, int(2048000/72000))
sync = np.array(sync72khz1[:])
sync[sync == 1] = 127
sync[sync == 0] = -128
sync2mhz1 = np.repeat(sync, int(2048000/72000))
sync = np.array(sync72khz2[:])
sync[sync == 1] = 127
sync[sync == 0] = -128
sync2mhz2 = np.repeat(sync, int(2048000/72000))
maxResBuff = []
minResBuff1 = []
minResBuff2 = []
maxBuffRetain = -1
maxBuffStart = 0
minSyncs = []
maxSyncs = []
numCtrs = int(chunkerObj.getChunks[-1][-1]*72000/2048000)
start_time = time.time()
lastMin = None
ctrMain = 0
sync2mhzChosen = sync2mhz
for i in chunkerObj.getChunks[:]:
#interpolate
sig = comm.commSignal(self.__sigsrc.sampFreq, self.__sigsrc.read(*i))
sig.offsetFreq(self.__offset)
sig.filter(bf)
# main loop
for i in sig.signal:
### MAXSYNC detection by correlation
# start storing 2mhz values near sync possible regions
if not lastMin is None and (ctr > lastMin + (0.1*72000) - (2*len(sync72khz)) or not maxBuffRetain == -1) and not ctr > lastMin + (1*72000):
if len(maxResBuff) == 0:
maxBuffStart = ctrMain
corrVal = i*pllObj.output
maxResBuff.append(lim(np.real(corrVal)/2))
maxResBuff.append(lim(np.imag(corrVal)/2))
# see if correlation is to be performed
if maxBuffRetain == -1:
if len(maxResBuff) > (2 * len(sync2mhz)):
maxBuffStart += 1
maxResBuff.pop(0)
maxResBuff.pop(0)
elif maxBuffRetain == 0:
maxBuffRetain -= 1
corr = np.abs(np.correlate(maxResBuff,sync2mhzChosen, mode='same'))
logging.info("MAXSYNC %d", maxBuffStart+(np.argmax(corr)/2.0))
#print("MAXSYNC", maxBuffStart, np.argmax(corr), maxBuffStart+np.argmax(corr))
maxSyncs.append(maxBuffStart+(np.argmax(corr)/2.0))
maxResBuff = []
#plt.plot(corr)
#plt.show()
else:
maxBuffRetain -= 1
# Gardners algorithm
if timing >= symbolPeriod/2 and timing < ((symbolPeriod/2)+1):
gardnerB = agcObj.adjust(i)
elif timing >= symbolPeriod:
gardnerA = agcObj.adjust(i)
timing -= symbolPeriod
resync_error = (np.imag(gardnerA) - np.imag(gardnerC)) * np.imag(gardnerB)
timing += (resync_error*symbolPeriod/(2000000.0))
gardnerC = gardnerA
gardnerA = pllObj.loop(gardnerA)
ctr += 1
# print periodic status
try:
if ctr%1000 == 0:
logging.info("[%.2f percent complete] [%.2f seconds elapsed] [%.2f seconds remain]", (ctr*100/numCtrs), (time.time() - start_time), (((time.time() - start_time)/(ctr/numCtrs))-(time.time() - start_time)))
#print(ctr, '[%.2f' %(ctr*100/numCtrs),"%]",'[%.2f' %(time.time() - start_time),"seconds elapsed]",'[%.2f' %(((time.time() - start_time)/(ctr/numCtrs))-(time.time() - start_time)), "seconds remaining]", pllObj.mean)
except:
pass
if lastMin is None or ctr > lastMin + 0.1*(72000):
# 72khz buffer
minResBuff1.append(limBin(np.real(gardnerA)))
minResBuff1.append(limBin(np.imag(gardnerA)))
minResBuff1 = minResBuff1[-1*len(sync72khz):]
minResBuff2.append(limBin(np.imag(gardnerA)))
minResBuff2.append(limBin(np.real(gardnerA)))
minResBuff2 = minResBuff2[-1*len(sync72khz):]
buff1corr, buff2corr, buff3corr, buff4corr, buff5corr, buff6corr = 0, 0, 0, 0, 0, 0
if len(minResBuff1) == len(sync72khz):
buff1corr = np.abs(np.sum(np.abs(np.array(minResBuff1) - sync72khz)) - (len(sync72khz)/2))
#if len(minResBuff2) == len(sync72khz):
# buff2corr = np.abs(np.sum(np.abs(np.array(minResBuff2) - sync72khz)) - (len(sync72khz)/2))
#if len(minResBuff1) == len(sync72khz1):
# buff3corr = np.abs(np.sum(np.abs(np.array(minResBuff1) - sync72khz1)) - (len(sync72khz1)/2))
if len(minResBuff2) == len(sync72khz1):
buff4corr = np.abs(np.sum(np.abs(np.array(minResBuff2) - sync72khz1)) - (len(sync72khz1)/2))
#if len(minResBuff1) == len(sync72khz2):
# buff5corr = np.abs(np.sum(np.abs(np.array(minResBuff1) - sync72khz2)) - (len(sync72khz2)/2))
#if len(minResBuff2) == len(sync72khz2):
# buff6corr = np.abs(np.sum(np.abs(np.array(minResBuff2) - sync72khz2)) - (len(sync72khz2)/2))
if buff1corr > 30 or buff2corr > 30:
sync2mhzChosen = sync2mhz
if buff3corr > 30 or buff4corr > 30:
sync2mhzChosen = sync2mhz1
if buff4corr > 30 or buff6corr > 30:
sync2mhzChosen = sync2mhz2
# see if sync is present
if buff1corr > 30 or buff2corr > 30 or buff3corr > 30 or buff4corr > 30 or buff5corr > 30 or buff6corr > 30:
logging.info("MINSYNC: %d",ctr)
#logging.info("MINSYNC: %d %f %f %f %f %f %f",ctr, buff1corr, buff2corr, buff3corr, buff4corr, buff5corr, buff6corr)
#print("MINSYNC:",ctr, np.abs(np.sum(np.abs(np.array(minResBuff) - sync72khz)) - (len(sync72khz)/2)))
minSyncs.append(ctr)
lastMin = ctr
maxBuffRetain = 2 * len(sync2mhz)
timing += 1
ctrMain += 1
if len(maxSyncs) > 0:
# check usefulness
if np.min(np.abs(np.diff(maxSyncs) - (0.11*2048000))) < (0.05*2048000):
self.__useful = 1
return list(maxSyncs)[1:]
else:
return []