def __init__(self):
gr.hier_block2.__init__(self,
"proto_transceiver",
gr.io_signature(1, 1, gr.sizeof_gr_complex),
gr.io_signature(1, 1, gr.sizeof_gr_complex))
#file sinks for debugging
self.agc_out = gr.file_sink(itemsize = gr.sizeof_gr_complex,
filename = "agc.dat")
#########################
#uplink blocks
q_encoder = gr.msg_queue(100)
self.tx_encoder = rfidbts.pie_encoder(samples_per_delimiter = 8,
samples_per_tari = 16,
samples_per_pw = 8,
samples_per_trcal = 53,
samples_per_data1 = 32)
self.tx_encoder.set_encoder_queue(q_encoder)
rfidbts.cvar.rfid_mac.set_encoder_queue(q_encoder)
####################################
#downlink blocks
q_blocker = gr.msg_queue(100)
frame_size_rn16 = int((32 + 32 + 12) * 8 + int(75*0.4*1.024))
self.TX_blocker = rfidbts.receive_gate(threshold = 0.15, #bit above the noise floor
off_max = 15) #should not be in the off state for more than 13 us
self.TX_blocker.set_gate_queue(q_blocker)
rfidbts.cvar.rfid_mac.set_gate_queue(q_blocker)
self.blocker = gr.dc_blocker_cc(D = 5,
long_form = True)
self.agc = gr.agc_cc(rate = 5e-1,
reference = 0.707,
gain = 100.0,
max_gain = 1000.0)
self.search = preamble_search(frame_size_rn16)
self.half_symbols = symbol_mapper()
# self.decoder = binary_diff_decoder()
self.decoder = rfidbts.orthogonal_decode()
self.framer = rfidbts.packetizer()
#frame the rn16 and send to message queue
#####################################
#connect uplink
self.connect(self.tx_encoder, self)
#####################################
#connect downlink
self.connect(self,
self.TX_blocker,
self.blocker,
self.agc,
self.search,
self.half_symbols,
self.decoder,
self.framer)
self.connect(self.agc, self.agc_out)
def test_002(self):
''' Test impulse response - short form, cc '''
src_data = [1,] + 100*[0,]
expected_result = ((-0.029296875+0j), (-0.0302734375+0j),
(0.96875+0j), (-0.0302734375+0j),
(-0.029296875+0j))
src = gr.vector_source_c(src_data)
op = gr.dc_blocker_cc(32, False)
dst = gr.vector_sink_c()
self.tb.connect (src, op, dst)
self.tb.run()
# only test samples around D-1
result_data = dst.data()[29:34]
self.assertFloatTuplesAlmostEqual (expected_result, result_data)
def test_001(self):
''' Test impulse response - long form, cc '''
src_data = [1,] + 100*[0,]
expected_result = ((-0.02072429656982422+0j), (-0.02081298828125+0j),
(0.979156494140625+0j), (-0.02081298828125+0j),
(-0.02072429656982422+0j))
src = gr.vector_source_c(src_data)
op = gr.dc_blocker_cc(32, True)
dst = gr.vector_sink_c()
self.tb.connect (src, op, dst)
self.tb.run()
# only test samples around 2D-2
result_data = dst.data()[60:65]
self.assertFloatTuplesAlmostEqual (expected_result, result_data)
def __init__(self):
gr.hier_block2.__init__(self, "proto_transceiver",
gr.io_signature(1, 1, gr.sizeof_gr_complex),
gr.io_signature(1, 1, gr.sizeof_gr_complex))
#file sinks for debugging
self.agc_out = gr.file_sink(itemsize=gr.sizeof_gr_complex,
filename="agc.dat")
#########################
#uplink blocks
q_encoder = gr.msg_queue(100)
self.tx_encoder = rfidbts.pie_encoder(samples_per_delimiter=8,
samples_per_tari=16,
samples_per_pw=8,
samples_per_trcal=53,
samples_per_data1=32)
self.tx_encoder.set_encoder_queue(q_encoder)
rfidbts.cvar.rfid_mac.set_encoder_queue(q_encoder)
####################################
#downlink blocks
q_blocker = gr.msg_queue(100)
frame_size_rn16 = int((32 + 32 + 12) * 8 + int(75 * 0.4 * 1.024))
self.TX_blocker = rfidbts.receive_gate(
threshold=0.15, #bit above the noise floor
off_max=15) #should not be in the off state for more than 13 us
self.TX_blocker.set_gate_queue(q_blocker)
rfidbts.cvar.rfid_mac.set_gate_queue(q_blocker)
self.blocker = gr.dc_blocker_cc(D=5, long_form=True)
self.agc = gr.agc_cc(rate=5e-1,
reference=0.707,
gain=100.0,
max_gain=1000.0)
self.search = preamble_search(frame_size_rn16)
self.half_symbols = symbol_mapper()
# self.decoder = binary_diff_decoder()
self.decoder = rfidbts.orthogonal_decode()
self.framer = rfidbts.packetizer()
#frame the rn16 and send to message queue
#####################################
#connect uplink
self.connect(self.tx_encoder, self)
#####################################
#connect downlink
self.connect(self, self.TX_blocker, self.blocker, self.agc,
self.search, self.half_symbols, self.decoder, self.framer)
self.connect(self.agc, self.agc_out)
def test_002(self):
''' Test impulse response - short form, cc '''
src_data = [
1,
] + 100 * [
0,
]
expected_result = ((-0.029296875 + 0j), (-0.0302734375 + 0j),
(0.96875 + 0j), (-0.0302734375 + 0j),
(-0.029296875 + 0j))
src = gr.vector_source_c(src_data)
op = gr.dc_blocker_cc(32, False)
dst = gr.vector_sink_c()
self.tb.connect(src, op, dst)
self.tb.run()
# only test samples around D-1
result_data = dst.data()[29:34]
self.assertComplexTuplesAlmostEqual(expected_result, result_data)
def test_001(self):
''' Test impulse response - long form, cc '''
src_data = [
1,
] + 100 * [
0,
]
expected_result = ((-0.02072429656982422 + 0j),
(-0.02081298828125 + 0j), (0.979156494140625 + 0j),
(-0.02081298828125 + 0j),
(-0.02072429656982422 + 0j))
src = gr.vector_source_c(src_data)
op = gr.dc_blocker_cc(32, True)
dst = gr.vector_sink_c()
self.tb.connect(src, op, dst)
self.tb.run()
# only test samples around 2D-2
result_data = dst.data()[60:65]
self.assertComplexTuplesAlmostEqual(expected_result, result_data)
