From ee09a80f9962e9c69101b714442104ae0e329459 Mon Sep 17 00:00:00 2001
From: Tom Rondeau <trondeau@vt.edu>
Date: Thu, 6 Oct 2011 20:02:56 -0400
Subject: digital: removed old digital and digital-bert scripts that will no
 longer work. All of these have been replaced in gr-digital/examples.

---
 .../python/digital-bert/receive_path.py            | 118 ---------------------
 1 file changed, 118 deletions(-)
 delete mode 100644 gnuradio-examples/python/digital-bert/receive_path.py

(limited to 'gnuradio-examples/python/digital-bert/receive_path.py')

diff --git a/gnuradio-examples/python/digital-bert/receive_path.py b/gnuradio-examples/python/digital-bert/receive_path.py
deleted file mode 100644
index e273923a4f..0000000000
--- a/gnuradio-examples/python/digital-bert/receive_path.py
+++ /dev/null
@@ -1,118 +0,0 @@
-#
-# 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.
-#
-
-from gnuradio import gr, eng_notation
-import math
-
-n2s = eng_notation.num_to_str
-
-class receive_path(gr.hier_block2):
-    def __init__(self,
-                 if_rate,        # Incoming sample rate
-                 symbol_rate,    # Original symbol rate
-                 excess_bw,      # RRC excess bandwidth, typically 0.35-0.5
-                 costas_alpha,   # Costas loop 1st order gain, typically 0.01-0.2
-                 costas_beta,    # Costas loop 2nd order gain, typically alpha^2/4.0
-                 costas_max,     # Costas loop max frequency offset in radians/sample
-                 mm_gain_mu,     # M&M loop 1st order gain, typically 0.001-0.2
-                 mm_gain_omega,  # M&M loop 2nd order gain, typically alpha^2/4.0
-                 mm_omega_limit, # M&M loop max timing error
-                 ):
-        
-        gr.hier_block2.__init__(self, "receive_path",
-                                gr.io_signature(1, 1, gr.sizeof_gr_complex), # Input signature
-                                gr.io_signature(0, 0, 0))                    # Output signature
-
-        self._if_rate = if_rate
-        self._sps = int(self._if_rate/symbol_rate)
-        print "IF sample rate:", n2s(self._if_rate)
-        print "Symbol rate:", n2s(symbol_rate)
-        print "Samples/symbol:", self._sps
-        print "RRC bandwidth:", excess_bw
-        
-        # Create AGC to scale input to unity
-        self._agc = gr.agc_cc(1e-5, 1.0, 1.0, 1.0)
-
-	# Create RRC with specified excess bandwidth
-	taps = gr.firdes.root_raised_cosine(1.0,          # Gain
-					    self._sps,    # Sampling rate
-					    1.0,          # Symbol rate
-					    excess_bw,    # Roll-off factor
-					    11*self._sps) # Number of taps
-
-	self._rrc = gr.fir_filter_ccf(1, taps)
-        
-        # Create a Costas loop frequency/phase recovery block
-
-        print "Costas alpha:", costas_alpha
-        print "Costas beta:", costas_beta
-        print "Costas max:", costas_max
-        
-        self._costas = gr.costas_loop_cc(costas_alpha,  # PLL first order gain
-                                         costas_beta,   # PLL second order gain
-                                         costas_max,    # Max frequency offset rad/sample
-                                         -costas_max,   # Min frequency offset rad/sample
-                                         2)             # BPSK
-
-        # Create a M&M bit synchronization retiming block
-        mm_mu = 0.5
-        mm_omega = self._sps
-
-        print "MM gain mu:", mm_gain_mu
-        print "MM gain omega:", mm_gain_omega
-        print "MM omega limit:", mm_omega_limit
-        
-        self._mm = gr.clock_recovery_mm_cc(mm_omega,       # Initial samples/symbol
-                                           mm_gain_omega,  # Second order gain
-                                           mm_mu,          # Initial symbol phase
-                                           mm_gain_mu,     # First order gain
-                                           mm_omega_limit) # Maximum timing offset
-
-        # Add an SNR probe on the demodulated constellation
-        self._snr_probe = gr.probe_mpsk_snr_c(10.0/symbol_rate)
-        self.connect(self._mm, self._snr_probe)
-        
-        # Slice the resulting constellation into bits.
-        # Get inphase channel and make decision about 0
-        self._c2r = gr.complex_to_real()
-        self._slicer = gr.binary_slicer_fb() 
-        
-        # Descramble BERT sequence.  A channel error will create 3 incorrect bits
-        self._descrambler = gr.descrambler_bb(0x8A, 0x7F, 7) # CCSDS 7-bit descrambler
-
-        # Measure BER by the density of 0s in the stream
-        self._ber = gr.probe_density_b(1.0/symbol_rate)
-
-        self.connect(self, self._agc, self._rrc, self._costas, self._mm, 
-                     self._c2r, self._slicer, self._descrambler, self._ber)
-
-    def frequency_offset(self):
-        return self._costas.freq()*self._if_rate/(2*math.pi)
-
-    def timing_offset(self):
-        return self._mm.omega()/self._sps-1.0
-
-    def snr(self):
-        return self._snr_probe.snr()
-
-    def ber(self):
-        return (1.0-self._ber.density())/3.0
-
-- 
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