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wangjie
OpenXG-RAN
Commits
b9407c40
Commit
b9407c40
authored
Jan 27, 2017
by
Florian Kaltenberger
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openair1/PHY/TOOLS/lte_phy_scope_tm4.c
openair1/PHY/TOOLS/lte_phy_scope_tm4.c
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openair1/PHY/TOOLS/lte_phy_scope_tm4.c
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b9407c40
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface 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 of the License, or
(at your option) any later version.
OpenAirInterface 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 OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@lists.eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/* Form definition file generated by fdesign */
#include <stdlib.h>
#include "lte_phy_scope.h"
#define TPUT_WINDOW_LENGTH 100
int
otg_enabled
;
FL_COLOR
rx_antenna_colors
[
4
]
=
{
FL_RED
,
FL_BLUE
,
FL_GREEN
,
FL_YELLOW
};
float
tput_time_enb
[
NUMBER_OF_UE_MAX
][
TPUT_WINDOW_LENGTH
]
=
{{
0
}};
float
tput_enb
[
NUMBER_OF_UE_MAX
][
TPUT_WINDOW_LENGTH
]
=
{{
0
}};
float
tput_time_ue
[
NUMBER_OF_UE_MAX
][
TPUT_WINDOW_LENGTH
]
=
{{
0
}};
float
tput_ue
[
NUMBER_OF_UE_MAX
][
TPUT_WINDOW_LENGTH
]
=
{{
0
}};
float
tput_ue_max
[
NUMBER_OF_UE_MAX
]
=
{
0
};
static
void
ia_receiver_on_off
(
FL_OBJECT
*
button
,
long
arg
)
{
if
(
fl_get_button
(
button
))
{
fl_set_object_label
(
button
,
"IA Receiver ON"
);
// PHY_vars_UE_g[0][0]->use_ia_receiver = 1;
fl_set_object_color
(
button
,
FL_GREEN
,
FL_GREEN
);
}
else
{
fl_set_object_label
(
button
,
"IA Receiver OFF"
);
// PHY_vars_UE_g[0][0]->use_ia_receiver = 0;
fl_set_object_color
(
button
,
FL_RED
,
FL_RED
);
}
}
static
void
dl_traffic_on_off
(
FL_OBJECT
*
button
,
long
arg
)
{
if
(
fl_get_button
(
button
))
{
fl_set_object_label
(
button
,
"DL Traffic ON"
);
otg_enabled
=
1
;
fl_set_object_color
(
button
,
FL_GREEN
,
FL_GREEN
);
}
else
{
fl_set_object_label
(
button
,
"DL Traffic OFF"
);
otg_enabled
=
0
;
fl_set_object_color
(
button
,
FL_RED
,
FL_RED
);
}
}
FD_lte_phy_scope_enb
*
create_lte_phy_scope_enb
(
void
)
{
FL_OBJECT
*
obj
;
FD_lte_phy_scope_enb
*
fdui
=
fl_malloc
(
sizeof
*
fdui
);
// Define form
fdui
->
lte_phy_scope_enb
=
fl_bgn_form
(
FL_NO_BOX
,
800
,
800
);
// This the whole UI box
obj
=
fl_add_box
(
FL_BORDER_BOX
,
0
,
0
,
800
,
800
,
""
);
fl_set_object_color
(
obj
,
FL_BLACK
,
FL_BLACK
);
// Received signal
fdui
->
rxsig_t
=
fl_add_xyplot
(
FL_NORMAL_XYPLOT
,
20
,
20
,
370
,
100
,
"Received Signal (Time-Domain, dB)"
);
fl_set_object_boxtype
(
fdui
->
rxsig_t
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
rxsig_t
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
rxsig_t
,
FL_WHITE
);
// Label color
fl_set_xyplot_ybounds
(
fdui
->
rxsig_t
,
10
,
70
);
// Time-domain channel response
fdui
->
chest_t
=
fl_add_xyplot
(
FL_NORMAL_XYPLOT
,
410
,
20
,
370
,
100
,
"Channel Impulse Response (samples, abs)"
);
fl_set_object_boxtype
(
fdui
->
chest_t
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
chest_t
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
chest_t
,
FL_WHITE
);
// Label color
// Frequency-domain channel response
fdui
->
chest_f
=
fl_add_xyplot
(
FL_IMPULSE_XYPLOT
,
20
,
140
,
760
,
100
,
"Channel Frequency Response (RE, dB)"
);
fl_set_object_boxtype
(
fdui
->
chest_f
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
chest_f
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
chest_f
,
FL_WHITE
);
// Label color
fl_set_xyplot_ybounds
(
fdui
->
chest_f
,
30
,
70
);
// LLR of PUSCH
fdui
->
pusch_llr
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
20
,
260
,
500
,
200
,
"PUSCH Log-Likelihood Ratios (LLR, mag)"
);
fl_set_object_boxtype
(
fdui
->
pusch_llr
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pusch_llr
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pusch_llr
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pusch_llr
,
2
);
// I/Q PUSCH comp
fdui
->
pusch_comp
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
540
,
260
,
240
,
200
,
"PUSCH I/Q of MF Output"
);
fl_set_object_boxtype
(
fdui
->
pusch_comp
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pusch_comp
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pusch_comp
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pusch_comp
,
2
);
fl_set_xyplot_xgrid
(
fdui
->
pusch_llr
,
FL_GRID_MAJOR
);
// I/Q PUCCH comp (format 1)
fdui
->
pucch_comp1
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
540
,
480
,
240
,
100
,
"PUCCH1 Energy (SR)"
);
fl_set_object_boxtype
(
fdui
->
pucch_comp1
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pucch_comp1
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pucch_comp1
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pucch_comp1
,
2
);
// fl_set_xyplot_xgrid( fdui->pusch_llr,FL_GRID_MAJOR);
// I/Q PUCCH comp (fromat 1a/b)
fdui
->
pucch_comp
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
540
,
600
,
240
,
100
,
"PUCCH I/Q of MF Output"
);
fl_set_object_boxtype
(
fdui
->
pucch_comp
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pucch_comp
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pucch_comp
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pucch_comp
,
2
);
// fl_set_xyplot_xgrid( fdui->pusch_llr,FL_GRID_MAJOR);
// Throughput on PUSCH
fdui
->
pusch_tput
=
fl_add_xyplot
(
FL_NORMAL_XYPLOT
,
20
,
480
,
500
,
100
,
"PUSCH Throughput [frame]/[kbit/s]"
);
fl_set_object_boxtype
(
fdui
->
pusch_tput
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pusch_tput
,
FL_BLACK
,
FL_WHITE
);
fl_set_object_lcolor
(
fdui
->
pusch_tput
,
FL_WHITE
);
// Label color
// Generic eNB Button
fdui
->
button_0
=
fl_add_button
(
FL_PUSH_BUTTON
,
20
,
600
,
240
,
40
,
""
);
fl_set_object_lalign
(
fdui
->
button_0
,
FL_ALIGN_CENTER
);
fl_set_button
(
fdui
->
button_0
,
0
);
otg_enabled
=
0
;
fl_set_object_label
(
fdui
->
button_0
,
"DL Traffic OFF"
);
fl_set_object_color
(
fdui
->
button_0
,
FL_RED
,
FL_RED
);
fl_set_object_callback
(
fdui
->
button_0
,
dl_traffic_on_off
,
0
);
fl_end_form
(
);
fdui
->
lte_phy_scope_enb
->
fdui
=
fdui
;
return
fdui
;
}
void
phy_scope_eNB
(
FD_lte_phy_scope_enb
*
form
,
PHY_VARS_eNB
*
phy_vars_enb
,
int
UE_id
)
{
int
eNB_id
=
0
;
int
i
,
i2
,
arx
,
atx
,
ind
,
k
;
LTE_DL_FRAME_PARMS
*
frame_parms
=
&
phy_vars_enb
->
frame_parms
;
int
nsymb_ce
=
12
*
frame_parms
->
N_RB_UL
*
frame_parms
->
symbols_per_tti
;
uint8_t
nb_antennas_rx
=
frame_parms
->
nb_antennas_rx
;
uint8_t
nb_antennas_tx
=
1
;
// frame_parms->nb_antennas_tx; // in LTE Rel. 8 and 9 only a single transmit antenna is assumed at the UE
int16_t
**
rxsig_t
;
int16_t
**
chest_t
;
int16_t
**
chest_f
;
int16_t
*
pusch_llr
;
int16_t
*
pusch_comp
;
int32_t
*
pucch1_comp
;
int32_t
*
pucch1_thres
;
int32_t
*
pucch1ab_comp
;
float
Re
,
Im
,
ymax
;
float
*
llr
,
*
bit
;
float
I
[
nsymb_ce
*
2
],
Q
[
nsymb_ce
*
2
];
float
I_pucch
[
10240
],
Q_pucch
[
10240
],
A_pucch
[
10240
],
B_pucch
[
10240
],
C_pucch
[
10240
];
float
rxsig_t_dB
[
nb_antennas_rx
][
FRAME_LENGTH_COMPLEX_SAMPLES
];
float
chest_t_abs
[
nb_antennas_rx
][
frame_parms
->
ofdm_symbol_size
];
float
*
chest_f_abs
;
float
time
[
FRAME_LENGTH_COMPLEX_SAMPLES
];
float
time2
[
2048
];
float
freq
[
nsymb_ce
*
nb_antennas_rx
*
nb_antennas_tx
];
int
frame
=
phy_vars_enb
->
proc
.
proc_rxtx
[
0
].
frame_tx
;
uint32_t
total_dlsch_bitrate
=
phy_vars_enb
->
total_dlsch_bitrate
;
int
coded_bits_per_codeword
=
0
;
uint8_t
harq_pid
;
// in TDD config 3 it is sf-2, i.e., can be 0,1,2
int
mcs
=
0
;
// choose max MCS to compute coded_bits_per_codeword
if
(
phy_vars_enb
->
ulsch
[
UE_id
]
!=
NULL
)
{
for
(
harq_pid
=
0
;
harq_pid
<
3
;
harq_pid
++
)
{
mcs
=
cmax
(
phy_vars_enb
->
ulsch
[
UE_id
]
->
harq_processes
[
harq_pid
]
->
mcs
,
mcs
);
}
}
coded_bits_per_codeword
=
frame_parms
->
N_RB_UL
*
12
*
get_Qm
(
mcs
)
*
frame_parms
->
symbols_per_tti
;
chest_f_abs
=
(
float
*
)
calloc
(
nsymb_ce
*
nb_antennas_rx
*
nb_antennas_tx
,
sizeof
(
float
));
llr
=
(
float
*
)
calloc
(
coded_bits_per_codeword
,
sizeof
(
float
));
// init to zero
bit
=
malloc
(
coded_bits_per_codeword
*
sizeof
(
float
));
rxsig_t
=
(
int16_t
**
)
phy_vars_enb
->
common_vars
.
rxdata
[
eNB_id
];
chest_t
=
(
int16_t
**
)
phy_vars_enb
->
pusch_vars
[
UE_id
]
->
drs_ch_estimates_time
[
eNB_id
];
chest_f
=
(
int16_t
**
)
phy_vars_enb
->
pusch_vars
[
UE_id
]
->
drs_ch_estimates
[
eNB_id
];
pusch_llr
=
(
int16_t
*
)
phy_vars_enb
->
pusch_vars
[
UE_id
]
->
llr
;
pusch_comp
=
(
int16_t
*
)
phy_vars_enb
->
pusch_vars
[
UE_id
]
->
rxdataF_comp
[
eNB_id
][
0
];
pucch1_comp
=
(
int32_t
*
)
phy_vars_enb
->
pucch1_stats
[
UE_id
];
pucch1_thres
=
(
int32_t
*
)
phy_vars_enb
->
pucch1_stats_thres
[
UE_id
];
pucch1ab_comp
=
(
int32_t
*
)
phy_vars_enb
->
pucch1ab_stats
[
UE_id
];
// Received signal in time domain of receive antenna 0
if
(
rxsig_t
!=
NULL
)
{
if
(
rxsig_t
[
0
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
FRAME_LENGTH_COMPLEX_SAMPLES
;
i
++
)
{
rxsig_t_dB
[
0
][
i
]
=
10
*
log10
(
1
.
0
+
(
float
)
((
rxsig_t
[
0
][
2
*
i
])
*
(
rxsig_t
[
0
][
2
*
i
])
+
(
rxsig_t
[
0
][
2
*
i
+
1
])
*
(
rxsig_t
[
0
][
2
*
i
+
1
])));
time
[
i
]
=
(
float
)
i
;
}
fl_set_xyplot_data
(
form
->
rxsig_t
,
time
,
rxsig_t_dB
[
0
],
FRAME_LENGTH_COMPLEX_SAMPLES
,
""
,
""
,
""
);
}
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
rxsig_t
[
arx
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
FRAME_LENGTH_COMPLEX_SAMPLES
;
i
++
)
{
rxsig_t_dB
[
arx
][
i
]
=
10
*
log10
(
1
.
0
+
(
float
)
((
rxsig_t
[
arx
][
2
*
i
])
*
(
rxsig_t
[
arx
][
2
*
i
])
+
(
rxsig_t
[
arx
][
2
*
i
+
1
])
*
(
rxsig_t
[
arx
][
2
*
i
+
1
])));
}
fl_add_xyplot_overlay
(
form
->
rxsig_t
,
arx
,
time
,
rxsig_t_dB
[
arx
],
FRAME_LENGTH_COMPLEX_SAMPLES
,
rx_antenna_colors
[
arx
]);
}
}
}
// Channel Impulse Response
if
(
chest_t
!=
NULL
)
{
ymax
=
0
;
if
(
chest_t
[
0
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
(
frame_parms
->
ofdm_symbol_size
);
i
++
)
{
i2
=
(
i
+
(
frame_parms
->
ofdm_symbol_size
>>
1
))
%
frame_parms
->
ofdm_symbol_size
;
time2
[
i
]
=
(
float
)(
i
-
(
frame_parms
->
ofdm_symbol_size
>>
1
));
chest_t_abs
[
0
][
i
]
=
10
*
log10
((
float
)
(
1
+
chest_t
[
0
][
2
*
i2
]
*
chest_t
[
0
][
2
*
i2
]
+
chest_t
[
0
][
2
*
i2
+
1
]
*
chest_t
[
0
][
2
*
i2
+
1
]));
if
(
chest_t_abs
[
0
][
i
]
>
ymax
)
ymax
=
chest_t_abs
[
0
][
i
];
}
fl_set_xyplot_data
(
form
->
chest_t
,
time2
,
chest_t_abs
[
0
],(
frame_parms
->
ofdm_symbol_size
),
""
,
""
,
""
);
}
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
chest_t
[
arx
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
(
frame_parms
->
ofdm_symbol_size
>>
3
);
i
++
)
{
chest_t_abs
[
arx
][
i
]
=
10
*
log10
((
float
)
(
1
+
chest_t
[
arx
][
2
*
i
]
*
chest_t
[
arx
][
2
*
i
]
+
chest_t
[
arx
][
2
*
i
+
1
]
*
chest_t
[
arx
][
2
*
i
+
1
]));
if
(
chest_t_abs
[
arx
][
i
]
>
ymax
)
ymax
=
chest_t_abs
[
arx
][
i
];
}
fl_add_xyplot_overlay
(
form
->
chest_t
,
arx
,
time
,
chest_t_abs
[
arx
],(
frame_parms
->
ofdm_symbol_size
>>
3
),
rx_antenna_colors
[
arx
]);
fl_set_xyplot_overlay_type
(
form
->
chest_t
,
arx
,
FL_DASHED_XYPLOT
);
}
}
// Avoid flickering effect
// fl_get_xyplot_ybounds(form->chest_t,&ymin,&ymax);
fl_set_xyplot_ybounds
(
form
->
chest_t
,
0
,
ymax
);
}
// Channel Frequency Response
if
(
chest_f
!=
NULL
)
{
ind
=
0
;
for
(
atx
=
0
;
atx
<
nb_antennas_tx
;
atx
++
)
{
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
chest_f
[(
atx
<<
1
)
+
arx
]
!=
NULL
)
{
for
(
k
=
0
;
k
<
nsymb_ce
;
k
++
)
{
freq
[
ind
]
=
(
float
)
ind
;
Re
=
(
float
)(
chest_f
[(
atx
<<
1
)
+
arx
][(
2
*
k
)]);
Im
=
(
float
)(
chest_f
[(
atx
<<
1
)
+
arx
][(
2
*
k
)
+
1
]);
chest_f_abs
[
ind
]
=
(
short
)
10
*
log10
(
1
.
0
+
((
double
)
Re
*
Re
+
(
double
)
Im
*
Im
));
ind
++
;
}
}
}
}
// tx antenna 0
fl_set_xyplot_xbounds
(
form
->
chest_f
,
0
,
nb_antennas_rx
*
nb_antennas_tx
*
nsymb_ce
);
fl_set_xyplot_xtics
(
form
->
chest_f
,
nb_antennas_rx
*
nb_antennas_tx
*
frame_parms
->
symbols_per_tti
,
3
);
fl_set_xyplot_xgrid
(
form
->
chest_f
,
FL_GRID_MAJOR
);
fl_set_xyplot_data
(
form
->
chest_f
,
freq
,
chest_f_abs
,
nsymb_ce
,
""
,
""
,
""
);
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
fl_add_xyplot_overlay
(
form
->
chest_f
,
1
,
&
freq
[
arx
*
nsymb_ce
],
&
chest_f_abs
[
arx
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
// other tx antennas
if
(
nb_antennas_tx
>
1
)
{
if
(
nb_antennas_rx
>
1
)
{
for
(
atx
=
1
;
atx
<
nb_antennas_tx
;
atx
++
)
{
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
fl_add_xyplot_overlay
(
form
->
chest_f
,(
atx
<<
1
)
+
arx
,
&
freq
[((
atx
<<
1
)
+
arx
)
*
nsymb_ce
],
&
chest_f_abs
[((
atx
<<
1
)
+
arx
)
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
}
}
else
{
// 1 rx antenna
atx
=
1
;
arx
=
0
;
fl_add_xyplot_overlay
(
form
->
chest_f
,
atx
,
&
freq
[
atx
*
nsymb_ce
],
&
chest_f_abs
[
atx
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
}
}
// PUSCH LLRs
if
(
pusch_llr
!=
NULL
)
{
for
(
i
=
0
;
i
<
coded_bits_per_codeword
;
i
++
)
{
llr
[
i
]
=
(
float
)
pusch_llr
[
i
];
bit
[
i
]
=
(
float
)
i
;
}
fl_set_xyplot_data
(
form
->
pusch_llr
,
bit
,
llr
,
coded_bits_per_codeword
,
""
,
""
,
""
);
}
// PUSCH I/Q of MF Output
if
(
pusch_comp
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_UL
;
i
++
)
{
I
[
ind
]
=
pusch_comp
[(
2
*
frame_parms
->
N_RB_UL
*
12
*
k
)
+
2
*
i
];
Q
[
ind
]
=
pusch_comp
[(
2
*
frame_parms
->
N_RB_UL
*
12
*
k
)
+
2
*
i
+
1
];
ind
++
;
}
}
fl_set_xyplot_data
(
form
->
pusch_comp
,
I
,
Q
,
ind
,
""
,
""
,
""
);
}
// PUSCH I/Q of MF Output
if
(
pucch1ab_comp
!=
NULL
)
{
for
(
ind
=
0
;
ind
<
10240
;
ind
++
)
{
I_pucch
[
ind
]
=
(
float
)
pucch1ab_comp
[
2
*
(
ind
)];
Q_pucch
[
ind
]
=
(
float
)
pucch1ab_comp
[
2
*
(
ind
)
+
1
];
A_pucch
[
ind
]
=
10
*
log10
(
pucch1_comp
[
ind
]);
B_pucch
[
ind
]
=
ind
;
C_pucch
[
ind
]
=
(
float
)
pucch1_thres
[
ind
];
}
fl_set_xyplot_data
(
form
->
pucch_comp
,
I_pucch
,
Q_pucch
,
10240
,
""
,
""
,
""
);
fl_set_xyplot_data
(
form
->
pucch_comp1
,
B_pucch
,
A_pucch
,
1024
,
""
,
""
,
""
);
fl_add_xyplot_overlay
(
form
->
pucch_comp1
,
1
,
B_pucch
,
C_pucch
,
1024
,
FL_RED
);
fl_set_xyplot_ybounds
(
form
->
pucch_comp
,
-
5000
,
5000
);
fl_set_xyplot_xbounds
(
form
->
pucch_comp
,
-
5000
,
5000
);
fl_set_xyplot_ybounds
(
form
->
pucch_comp1
,
0
,
80
);
}
// PUSCH Throughput
memmove
(
tput_time_enb
[
UE_id
],
&
tput_time_enb
[
UE_id
][
1
],
(
TPUT_WINDOW_LENGTH
-
1
)
*
sizeof
(
float
)
);
memmove
(
tput_enb
[
UE_id
],
&
tput_enb
[
UE_id
][
1
],
(
TPUT_WINDOW_LENGTH
-
1
)
*
sizeof
(
float
)
);
tput_time_enb
[
UE_id
][
TPUT_WINDOW_LENGTH
-
1
]
=
(
float
)
frame
;
tput_enb
[
UE_id
][
TPUT_WINDOW_LENGTH
-
1
]
=
((
float
)
total_dlsch_bitrate
)
/
1000
.
0
;
fl_set_xyplot_data
(
form
->
pusch_tput
,
tput_time_enb
[
UE_id
],
tput_enb
[
UE_id
],
TPUT_WINDOW_LENGTH
,
""
,
""
,
""
);
// fl_get_xyplot_ybounds(form->pusch_tput,&ymin,&ymax);
// fl_set_xyplot_ybounds(form->pusch_tput,0,ymax);
fl_check_forms
();
free
(
llr
);
free
(
bit
);
free
(
chest_f_abs
);
}
FD_lte_phy_scope_ue
*
create_lte_phy_scope_ue
(
void
)
{
FL_OBJECT
*
obj
;
FD_lte_phy_scope_ue
*
fdui
=
fl_malloc
(
sizeof
*
fdui
);
// Define form
fdui
->
lte_phy_scope_ue
=
fl_bgn_form
(
FL_NO_BOX
,
800
,
1000
);
// This the whole UI box
obj
=
fl_add_box
(
FL_BORDER_BOX
,
0
,
0
,
800
,
1000
,
""
);
fl_set_object_color
(
obj
,
FL_BLACK
,
FL_BLACK
);
// Received signal
fdui
->
rxsig_t
=
fl_add_xyplot
(
FL_NORMAL_XYPLOT
,
20
,
20
,
370
,
100
,
"Received Signal (Time-Domain, dB)"
);
fl_set_object_boxtype
(
fdui
->
rxsig_t
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
rxsig_t
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
rxsig_t
,
FL_WHITE
);
// Label color
fl_set_xyplot_ybounds
(
fdui
->
rxsig_t
,
30
,
70
);
// Time-domain channel response
fdui
->
chest_t
=
fl_add_xyplot
(
FL_NORMAL_XYPLOT
,
410
,
20
,
370
,
100
,
"Channel Impulse Response (samples, abs)"
);
fl_set_object_boxtype
(
fdui
->
chest_t
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
chest_t
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
chest_t
,
FL_WHITE
);
// Label color
// Frequency-domain channel response
fdui
->
chest_f
=
fl_add_xyplot
(
FL_IMPULSE_XYPLOT
,
20
,
140
,
760
,
100
,
"Channel Frequency Response (RE, dB)"
);
fl_set_object_boxtype
(
fdui
->
chest_f
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
chest_f
,
FL_BLACK
,
FL_RED
);
fl_set_object_lcolor
(
fdui
->
chest_f
,
FL_WHITE
);
// Label color
fl_set_xyplot_ybounds
(
fdui
->
chest_f
,
30
,
70
);
/*
// LLR of PBCH
fdui->pbch_llr = fl_add_xyplot( FL_POINTS_XYPLOT, 20, 260, 500, 100, "PBCH Log-Likelihood Ratios (LLR, mag)" );
fl_set_object_boxtype( fdui->pbch_llr, FL_EMBOSSED_BOX );
fl_set_object_color( fdui->pbch_llr, FL_BLACK, FL_GREEN );
fl_set_object_lcolor( fdui->pbch_llr, FL_WHITE ); // Label color
fl_set_xyplot_symbolsize( fdui->pbch_llr,2);
fl_set_xyplot_xgrid( fdui->pbch_llr,FL_GRID_MAJOR);
fl_set_xyplot_xbounds( fdui->pbch_llr,0,1920);
// I/Q PBCH comp
fdui->pbch_comp = fl_add_xyplot( FL_POINTS_XYPLOT, 540, 260, 240, 100, "PBCH I/Q of MF Output" );
fl_set_object_boxtype( fdui->pbch_comp, FL_EMBOSSED_BOX );
fl_set_object_color( fdui->pbch_comp, FL_BLACK, FL_GREEN );
fl_set_object_lcolor( fdui->pbch_comp, FL_WHITE ); // Label color
fl_set_xyplot_symbolsize( fdui->pbch_comp,2);
fl_set_xyplot_xbounds( fdui->pbch_comp,-100,100);
fl_set_xyplot_ybounds( fdui->pbch_comp,-100,100);
// LLR of PDCCH
fdui->pdcch_llr = fl_add_xyplot( FL_POINTS_XYPLOT, 20, 380, 500, 100, "PDCCH Log-Likelihood Ratios (LLR, mag)" );
fl_set_object_boxtype( fdui->pdcch_llr, FL_EMBOSSED_BOX );
fl_set_object_color( fdui->pdcch_llr, FL_BLACK, FL_CYAN );
fl_set_object_lcolor( fdui->pdcch_llr, FL_WHITE ); // Label color
fl_set_xyplot_symbolsize( fdui->pdcch_llr,2);
// I/Q PDCCH comp
fdui->pdcch_comp = fl_add_xyplot( FL_POINTS_XYPLOT, 540, 380, 240, 100, "PDCCH I/Q of MF Output" );
fl_set_object_boxtype( fdui->pdcch_comp, FL_EMBOSSED_BOX );
fl_set_object_color( fdui->pdcch_comp, FL_BLACK, FL_CYAN );
fl_set_object_lcolor( fdui->pdcch_comp, FL_WHITE ); // Label color
fl_set_xyplot_symbolsize( fdui->pdcch_comp,2);
fl_set_xyplot_xgrid( fdui->pdcch_llr,FL_GRID_MAJOR);
*/
int
offset
=
240
;
// LLR of PDSCH
fdui
->
pdsch_llr
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
20
,
500
-
offset
,
500
,
200
,
"PDSCH Log-Likelihood Ratios (LLR, mag)"
);
fl_set_object_boxtype
(
fdui
->
pdsch_llr
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pdsch_llr
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pdsch_llr
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pdsch_llr
,
2
);
fl_set_xyplot_xgrid
(
fdui
->
pdsch_llr
,
FL_GRID_MAJOR
);
// I/Q PDSCH comp
fdui
->
pdsch_comp
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
540
,
500
-
offset
,
240
,
200
,
"PDSCH I/Q of MF Output"
);
fl_set_object_boxtype
(
fdui
->
pdsch_comp
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pdsch_comp
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pdsch_comp
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pdsch_comp
,
2
);
// LLR of PDSCH
fdui
->
pdsch_llr1
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
20
,
720
-
offset
,
500
,
200
,
"PDSCH Log-Likelihood Ratios (LLR, mag)"
);
fl_set_object_boxtype
(
fdui
->
pdsch_llr1
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pdsch_llr1
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pdsch_llr1
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pdsch_llr1
,
2
);
fl_set_xyplot_xgrid
(
fdui
->
pdsch_llr1
,
FL_GRID_MAJOR
);
// I/Q PDSCH comp
fdui
->
pdsch_comp1
=
fl_add_xyplot
(
FL_POINTS_XYPLOT
,
540
,
720
-
offset
,
240
,
200
,
"PDSCH I/Q of MF Output"
);
fl_set_object_boxtype
(
fdui
->
pdsch_comp1
,
FL_EMBOSSED_BOX
);
fl_set_object_color
(
fdui
->
pdsch_comp1
,
FL_BLACK
,
FL_YELLOW
);
fl_set_object_lcolor
(
fdui
->
pdsch_comp1
,
FL_WHITE
);
// Label color
fl_set_xyplot_symbolsize
(
fdui
->
pdsch_comp1
,
2
);
/*
// Throughput on PDSCH
fdui->pdsch_tput = fl_add_xyplot( FL_NORMAL_XYPLOT, 20, 720, 500, 100, "PDSCH Throughput [frame]/[kbit/s]" );
fl_set_object_boxtype( fdui->pdsch_tput, FL_EMBOSSED_BOX );
fl_set_object_color( fdui->pdsch_tput, FL_BLACK, FL_WHITE );
fl_set_object_lcolor( fdui->pdsch_tput, FL_WHITE ); // Label color
// Generic UE Button
fdui->button_0 = fl_add_button( FL_PUSH_BUTTON, 540, 720, 240, 40, "" );
fl_set_object_lalign(fdui->button_0, FL_ALIGN_CENTER );
//openair_daq_vars.use_ia_receiver = 0;
fl_set_button(fdui->button_0,0);
fl_set_object_label(fdui->button_0, "IA Receiver OFF");
fl_set_object_color(fdui->button_0, FL_RED, FL_RED);
fl_set_object_callback(fdui->button_0, ia_receiver_on_off, 0 );
fl_hide_object(fdui->button_0);
*/
fl_end_form
(
);
fdui
->
lte_phy_scope_ue
->
fdui
=
fdui
;
return
fdui
;
}
void
phy_scope_UE
(
FD_lte_phy_scope_ue
*
form
,
PHY_VARS_UE
*
phy_vars_ue
,
int
eNB_id
,
int
UE_id
,
uint8_t
subframe
){
int
i
,
arx
,
atx
,
ind
,
k
;
LTE_DL_FRAME_PARMS
*
frame_parms
=
&
phy_vars_ue
->
frame_parms
;
int
nsymb_ce
=
frame_parms
->
ofdm_symbol_size
*
frame_parms
->
symbols_per_tti
;
uint8_t
nb_antennas_rx
=
frame_parms
->
nb_antennas_rx
;
uint8_t
nb_antennas_tx
=
frame_parms
->
nb_antennas_tx_eNB
;
int16_t
**
rxsig_t
;
int16_t
**
chest_t
;
int16_t
**
chest_f
;
int16_t
*
pdsch_llr
,
*
pdsch_llr1
;
int16_t
*
pdsch_comp
,
*
pdsch_comp1
;
int16_t
*
pdsch_mag0
,
*
pdsch_mag1
,
*
pdsch_magb0
,
*
pdsch_magb1
;
int8_t
*
pdcch_llr
;
int16_t
*
pdcch_comp
;
int8_t
*
pbch_llr
;
int16_t
*
pbch_comp
;
float
Re
,
Im
,
ymax
=
1
;
int
num_pdcch_symbols
=
3
;
float
*
llr0
,
*
bit0
,
*
llr1
,
*
bit1
,
*
chest_f_abs
,
llr_pbch
[
1920
],
bit_pbch
[
1920
],
*
llr_pdcch
,
*
bit_pdcch
;
float
*
I
,
*
Q
;
float
rxsig_t_dB
[
nb_antennas_rx
][
FRAME_LENGTH_COMPLEX_SAMPLES
];
float
**
chest_t_abs
;
float
time
[
FRAME_LENGTH_COMPLEX_SAMPLES
];
float
freq
[
nsymb_ce
*
nb_antennas_rx
*
nb_antennas_tx
];
int
frame
=
phy_vars_ue
->
proc
.
proc_rxtx
[
0
].
frame_rx
;
uint32_t
total_dlsch_bitrate
=
phy_vars_ue
->
bitrate
[
eNB_id
];
int
coded_bits_per_codeword0
=
0
,
coded_bits_per_codeword1
=
1
;
int
mod0
,
mod1
;
int
mcs0
=
0
;
int
mcs1
=
0
;
unsigned
char
harq_pid
=
0
;
if
(
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
!=
NULL
)
{
harq_pid
=
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
->
current_harq_pid
;
if
(
harq_pid
>=
8
)
return
;
mcs0
=
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
->
harq_processes
[
harq_pid
]
->
mcs
;
// Button 0
/*
if(!phy_vars_ue->dlsch_ue[eNB_id][0]->harq_processes[harq_pid]->dl_power_off) {
// we are in TM5
fl_show_object(form->button_0);
}
*/
}
if
(
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
!=
NULL
)
{
harq_pid
=
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
->
current_harq_pid
;
if
(
harq_pid
>=
8
)
return
;
mcs1
=
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
->
harq_processes
[
harq_pid
]
->
mcs
;
}
if
(
phy_vars_ue
->
pdcch_vars
[
eNB_id
]
!=
NULL
)
{
num_pdcch_symbols
=
phy_vars_ue
->
pdcch_vars
[
eNB_id
]
->
num_pdcch_symbols
;
}
// coded_bits_per_codeword = frame_parms->N_RB_DL*12*get_Qm(mcs)*(frame_parms->symbols_per_tti);
if
(
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
!=
NULL
)
{
mod0
=
get_Qm
(
mcs0
);
coded_bits_per_codeword0
=
get_G
(
frame_parms
,
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
->
harq_processes
[
harq_pid
]
->
nb_rb
,
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
->
harq_processes
[
harq_pid
]
->
rb_alloc_even
,
get_Qm
(
mcs0
),
phy_vars_ue
->
dlsch
[
eNB_id
][
0
]
->
harq_processes
[
harq_pid
]
->
Nl
,
num_pdcch_symbols
,
frame
,
subframe
);
}
else
{
coded_bits_per_codeword0
=
0
;
//frame_parms->N_RB_DL*12*get_Qm(mcs)*(frame_parms->symbols_per_tti);
mod0
=
0
;
}
if
(
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
!=
NULL
)
{
mod1
=
get_Qm
(
mcs1
);
coded_bits_per_codeword1
=
get_G
(
frame_parms
,
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
->
harq_processes
[
harq_pid
]
->
nb_rb
,
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
->
harq_processes
[
harq_pid
]
->
rb_alloc_even
,
get_Qm
(
mcs1
),
phy_vars_ue
->
dlsch
[
eNB_id
][
1
]
->
harq_processes
[
harq_pid
]
->
Nl
,
num_pdcch_symbols
,
frame
,
subframe
);
}
else
{
coded_bits_per_codeword1
=
0
;
//frame_parms->N_RB_DL*12*get_Qm(mcs)*(frame_parms->symbols_per_tti);
mod1
=
0
;
}
I
=
(
float
*
)
calloc
(
nsymb_ce
*
2
,
sizeof
(
float
));
Q
=
(
float
*
)
calloc
(
nsymb_ce
*
2
,
sizeof
(
float
));
chest_t_abs
=
(
float
**
)
malloc
(
nb_antennas_rx
*
sizeof
(
float
*
));
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
chest_t_abs
[
arx
]
=
(
float
*
)
calloc
(
frame_parms
->
ofdm_symbol_size
,
sizeof
(
float
));
}
chest_f_abs
=
(
float
*
)
calloc
(
nsymb_ce
*
nb_antennas_rx
*
nb_antennas_tx
,
sizeof
(
float
));
llr0
=
(
float
*
)
calloc
(
coded_bits_per_codeword0
,
sizeof
(
float
));
// init to zero
bit0
=
malloc
(
coded_bits_per_codeword0
*
sizeof
(
float
));
llr1
=
(
float
*
)
calloc
(
coded_bits_per_codeword1
,
sizeof
(
float
));
// init to zero
bit1
=
malloc
(
coded_bits_per_codeword1
*
sizeof
(
float
));
llr_pdcch
=
(
float
*
)
calloc
(
12
*
frame_parms
->
N_RB_DL
*
num_pdcch_symbols
*
2
,
sizeof
(
float
));
// init to zero
bit_pdcch
=
(
float
*
)
calloc
(
12
*
frame_parms
->
N_RB_DL
*
num_pdcch_symbols
*
2
,
sizeof
(
float
));
rxsig_t
=
(
int16_t
**
)
phy_vars_ue
->
common_vars
.
rxdata
;
chest_t
=
(
int16_t
**
)
phy_vars_ue
->
common_vars
.
dl_ch_estimates_time
[
eNB_id
];
chest_f
=
(
int16_t
**
)
phy_vars_ue
->
common_vars
.
dl_ch_estimates
[
eNB_id
];
pbch_llr
=
(
int8_t
*
)
phy_vars_ue
->
pbch_vars
[
eNB_id
]
->
llr
;
pbch_comp
=
(
int16_t
*
)
phy_vars_ue
->
pbch_vars
[
eNB_id
]
->
rxdataF_comp
[
0
];
pdcch_llr
=
(
int8_t
*
)
phy_vars_ue
->
pdcch_vars
[
eNB_id
]
->
llr
;
pdcch_comp
=
(
int16_t
*
)
phy_vars_ue
->
pdcch_vars
[
eNB_id
]
->
rxdataF_comp
[
0
];
pdsch_llr
=
(
int16_t
*
)
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
llr
[
0
];
// stream 0
pdsch_llr1
=
(
int16_t
*
)
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
llr
[
1
];
// stream 1
pdsch_comp
=
(
int16_t
*
)
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
rxdataF_comp0
[
0
];
//pdsch_comp = (int16_t*) phy_vars_ue->lte_ue_pdsch_vars[eNB_id]->rxdataF_ext[0];
//pdsch_comp1 = (int16_t*) phy_vars_ue->lte_ue_pdsch_vars[eNB_id]->rxdataF_ext[1];
pdsch_comp1
=
(
int16_t
*
)
(
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
rxdataF_comp1
[
0
][
0
])[
0
];
//pdsch_comp1 = (int16_t*) (phy_vars_ue->lte_ue_pdsch_vars[eNB_id]->dl_ch_rho_ext[0][0])[0];
pdsch_mag0
=
(
int16_t
*
)
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
dl_ch_mag0
[
0
];
pdsch_mag1
=
(
int16_t
*
)
(
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
dl_ch_mag1
[
0
][
0
])[
0
];
pdsch_magb0
=
(
int16_t
*
)
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
dl_ch_magb0
[
0
];
pdsch_magb1
=
(
int16_t
*
)
(
phy_vars_ue
->
pdsch_vars
[
eNB_id
]
->
dl_ch_magb1
[
0
][
0
])[
0
];
fl_freeze_form
(
form
->
lte_phy_scope_ue
);
// Received signal in time domain of receive antenna 0
if
(
rxsig_t
!=
NULL
)
{
if
(
rxsig_t
[
0
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
FRAME_LENGTH_COMPLEX_SAMPLES
;
i
++
)
{
rxsig_t_dB
[
0
][
i
]
=
10
*
log10
(
1
.
0
+
(
float
)
((
rxsig_t
[
0
][
2
*
i
])
*
(
rxsig_t
[
0
][
2
*
i
])
+
(
rxsig_t
[
0
][
2
*
i
+
1
])
*
(
rxsig_t
[
0
][
2
*
i
+
1
])));
time
[
i
]
=
(
float
)
i
;
}
fl_set_xyplot_data
(
form
->
rxsig_t
,
time
,
rxsig_t_dB
[
0
],
FRAME_LENGTH_COMPLEX_SAMPLES
,
""
,
""
,
""
);
}
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
rxsig_t
[
arx
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
FRAME_LENGTH_COMPLEX_SAMPLES
;
i
++
)
{
rxsig_t_dB
[
arx
][
i
]
=
10
*
log10
(
1
.
0
+
(
float
)
((
rxsig_t
[
arx
][
2
*
i
])
*
(
rxsig_t
[
arx
][
2
*
i
])
+
(
rxsig_t
[
arx
][
2
*
i
+
1
])
*
(
rxsig_t
[
arx
][
2
*
i
+
1
])));
}
fl_add_xyplot_overlay
(
form
->
rxsig_t
,
arx
,
time
,
rxsig_t_dB
[
arx
],
FRAME_LENGTH_COMPLEX_SAMPLES
,
rx_antenna_colors
[
arx
]);
}
}
}
// Channel Impulse Response (still repeated format)
if
(
chest_t
!=
NULL
)
{
ymax
=
0
;
if
(
chest_t
[
0
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
(
frame_parms
->
ofdm_symbol_size
>>
3
);
i
++
)
{
chest_t_abs
[
0
][
i
]
=
(
float
)
(
chest_t
[
0
][
4
*
i
]
*
chest_t
[
0
][
4
*
i
]
+
chest_t
[
0
][
4
*
i
+
1
]
*
chest_t
[
0
][
4
*
i
+
1
]);
if
(
chest_t_abs
[
0
][
i
]
>
ymax
)
ymax
=
chest_t_abs
[
0
][
i
];
}
fl_set_xyplot_data
(
form
->
chest_t
,
time
,
chest_t_abs
[
0
],(
frame_parms
->
ofdm_symbol_size
>>
3
),
""
,
""
,
""
);
}
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
chest_t
[
arx
]
!=
NULL
)
{
for
(
i
=
0
;
i
<
(
frame_parms
->
ofdm_symbol_size
>>
3
);
i
++
)
{
chest_t_abs
[
arx
][
i
]
=
(
float
)
(
chest_t
[
arx
][
4
*
i
]
*
chest_t
[
arx
][
4
*
i
]
+
chest_t
[
arx
][
4
*
i
+
1
]
*
chest_t
[
arx
][
4
*
i
+
1
]);
if
(
chest_t_abs
[
arx
][
i
]
>
ymax
)
ymax
=
chest_t_abs
[
arx
][
i
];
}
fl_add_xyplot_overlay
(
form
->
chest_t
,
arx
,
time
,
chest_t_abs
[
arx
],(
frame_parms
->
ofdm_symbol_size
>>
3
),
rx_antenna_colors
[
arx
]);
fl_set_xyplot_overlay_type
(
form
->
chest_t
,
arx
,
FL_DASHED_XYPLOT
);
}
}
// Avoid flickering effect
// fl_get_xyplot_ybounds(form->chest_t,&ymin,&ymax);
fl_set_xyplot_ybounds
(
form
->
chest_t
,
0
,
ymax
);
}
// Channel Frequency Response (includes 5 complex sample for filter)
if
(
chest_f
!=
NULL
)
{
ind
=
0
;
for
(
atx
=
0
;
atx
<
nb_antennas_tx
;
atx
++
)
{
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
if
(
chest_f
[(
atx
<<
1
)
+
arx
]
!=
NULL
)
{
for
(
k
=
0
;
k
<
nsymb_ce
;
k
++
)
{
freq
[
ind
]
=
(
float
)
ind
;
Re
=
(
float
)(
chest_f
[(
atx
<<
1
)
+
arx
][(
2
*
k
)]);
Im
=
(
float
)(
chest_f
[(
atx
<<
1
)
+
arx
][(
2
*
k
)
+
1
]);
chest_f_abs
[
ind
]
=
(
short
)
10
*
log10
(
1
.
0
+
((
double
)
Re
*
Re
+
(
double
)
Im
*
Im
));
ind
++
;
}
}
}
}
// tx antenna 0
fl_set_xyplot_xbounds
(
form
->
chest_f
,
0
,
nb_antennas_rx
*
nb_antennas_tx
*
nsymb_ce
);
//fl_set_xyplot_xtics(form->chest_f,nb_antennas_rx*nb_antennas_tx*frame_parms->symbols_per_tti,2);
// fl_set_xyplot_xtics(form->chest_f,nb_antennas_rx*nb_antennas_tx*2,2);
fl_set_xyplot_xgrid
(
form
->
chest_f
,
FL_GRID_MAJOR
);
fl_set_xyplot_data
(
form
->
chest_f
,
freq
,
chest_f_abs
,
nsymb_ce
,
""
,
""
,
""
);
for
(
arx
=
1
;
arx
<
nb_antennas_rx
;
arx
++
)
{
fl_add_xyplot_overlay
(
form
->
chest_f
,
1
,
&
freq
[
arx
*
nsymb_ce
],
&
chest_f_abs
[
arx
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
// other tx antennas
if
(
nb_antennas_tx
>
1
)
{
if
(
nb_antennas_rx
>
1
)
{
for
(
atx
=
1
;
atx
<
nb_antennas_tx
;
atx
++
)
{
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
fl_add_xyplot_overlay
(
form
->
chest_f
,(
atx
<<
1
)
+
arx
,
&
freq
[((
atx
<<
1
)
+
arx
)
*
nsymb_ce
],
&
chest_f_abs
[((
atx
<<
1
)
+
arx
)
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
}
}
else
{
// 1 rx antenna
atx
=
1
;
arx
=
0
;
fl_add_xyplot_overlay
(
form
->
chest_f
,
atx
,
&
freq
[
atx
*
nsymb_ce
],
&
chest_f_abs
[
atx
*
nsymb_ce
],
nsymb_ce
,
rx_antenna_colors
[
arx
]);
}
}
}
/*
// PBCH LLRs
if (pbch_llr != NULL) {
for (i=0; i<1920;i++) {
llr_pbch[i] = (float) pbch_llr[i];
bit_pbch[i] = (float) i;
}
fl_set_xyplot_data(form->pbch_llr,bit_pbch,llr_pbch,1920,"","","");
}
// PBCH I/Q of MF Output
if (pbch_comp!=NULL) {
for (i=0; i<72*2; i++) {
I[i] = pbch_comp[2*i];
Q[i] = pbch_comp[2*i+1];
}
fl_set_xyplot_data(form->pbch_comp,I,Q,72*2,"","","");
}
// PDCCH LLRs
if (pdcch_llr != NULL) {
for (i=0; i<12*frame_parms->N_RB_DL*2*num_pdcch_symbols;i++) {
llr_pdcch[i] = (float) pdcch_llr[i];
bit_pdcch[i] = (float) i;
}
fl_set_xyplot_xbounds(form->pdcch_llr,0,12*frame_parms->N_RB_DL*2*3);
fl_set_xyplot_data(form->pdcch_llr,bit_pdcch,llr_pdcch,12*frame_parms->N_RB_DL*2*num_pdcch_symbols,"","","");
}
// PDCCH I/Q of MF Output
if (pdcch_comp!=NULL) {
for (i=0; i<12*frame_parms->N_RB_DL*num_pdcch_symbols; i++) {
I[i] = pdcch_comp[2*i];
Q[i] = pdcch_comp[2*i+1];
}
fl_set_xyplot_data(form->pdcch_comp,I,Q,12*frame_parms->N_RB_DL*num_pdcch_symbols,"","","");
}
*/
// PDSCH LLRs CW0
if
(
pdsch_llr
!=
NULL
)
{
for
(
i
=
0
;
i
<
coded_bits_per_codeword0
;
i
++
)
{
llr0
[
i
]
=
(
float
)
pdsch_llr
[
i
];
bit0
[
i
]
=
(
float
)
i
;
}
fl_set_xyplot_xbounds
(
form
->
pdsch_llr
,
0
,
coded_bits_per_codeword0
);
fl_set_xyplot_data
(
form
->
pdsch_llr
,
bit0
,
llr0
,
coded_bits_per_codeword0
,
""
,
""
,
""
);
}
// PDSCH I/Q of MF Output
if
(
pdsch_comp
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_comp
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
];
Q
[
ind
]
=
pdsch_comp
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
];
ind
++
;
}
}
fl_set_xyplot_data
(
form
->
pdsch_comp
,
I
,
Q
,
ind
,
""
,
""
,
""
);
}
if
(
pdsch_mag0
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_mag0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
pdsch_mag0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp
,
1
,
I
,
Q
,
ind
,
FL_GREEN
);
}
if
(
pdsch_magb0
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_magb0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
pdsch_magb0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp
,
2
,
I
,
Q
,
ind
,
FL_RED
);
}
if
((
pdsch_mag0
!=
NULL
)
&&
(
pdsch_magb0
!=
NULL
))
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
(
pdsch_mag0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
+
pdsch_magb0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
])
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
(
pdsch_mag0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
+
pdsch_magb0
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
])
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp
,
3
,
I
,
Q
,
ind
,
FL_BLUE
);
}
// PDSCH LLRs CW1
if
(
pdsch_llr1
!=
NULL
)
{
for
(
i
=
0
;
i
<
coded_bits_per_codeword1
;
i
++
)
{
llr1
[
i
]
=
(
float
)
pdsch_llr1
[
i
];
bit1
[
i
]
=
(
float
)
i
;
}
fl_set_xyplot_xbounds
(
form
->
pdsch_llr1
,
0
,
coded_bits_per_codeword1
);
fl_set_xyplot_data
(
form
->
pdsch_llr1
,
bit1
,
llr1
,
coded_bits_per_codeword1
,
""
,
""
,
""
);
}
// PDSCH I/Q of MF Output
if
(
pdsch_comp1
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_comp1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
];
Q
[
ind
]
=
pdsch_comp1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
];
ind
++
;
}
}
fl_set_xyplot_data
(
form
->
pdsch_comp1
,
I
,
Q
,
ind
,
""
,
""
,
""
);
}
if
(
pdsch_mag1
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_mag1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
pdsch_mag1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp1
,
1
,
I
,
Q
,
ind
,
FL_GREEN
);
}
if
(
pdsch_magb1
!=
NULL
)
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
pdsch_magb1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
pdsch_magb1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp1
,
2
,
I
,
Q
,
ind
,
FL_RED
);
}
if
((
pdsch_mag1
!=
NULL
)
&&
(
pdsch_magb1
!=
NULL
))
{
ind
=
0
;
for
(
k
=
0
;
k
<
frame_parms
->
symbols_per_tti
;
k
++
)
{
for
(
i
=
0
;
i
<
12
*
frame_parms
->
N_RB_DL
/
2
;
i
++
)
{
I
[
ind
]
=
(
pdsch_mag1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
]
+
pdsch_magb1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
])
*
cos
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
Q
[
ind
]
=
(
pdsch_mag1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
]
+
pdsch_magb1
[(
2
*
frame_parms
->
N_RB_DL
*
12
*
k
)
+
4
*
i
+
1
])
*
sin
(
i
*
2
*
M_PI
/
(
12
*
frame_parms
->
N_RB_DL
/
2
));
ind
++
;
}
}
fl_add_xyplot_overlay
(
form
->
pdsch_comp1
,
3
,
I
,
Q
,
ind
,
FL_BLUE
);
}
/*
// PDSCH Throughput
memcpy((void*)tput_time_ue[UE_id],(void*)&tput_time_ue[UE_id][1],(TPUT_WINDOW_LENGTH-1)*sizeof(float));
memcpy((void*)tput_ue[UE_id],(void*)&tput_ue[UE_id][1],(TPUT_WINDOW_LENGTH-1)*sizeof(float));
tput_time_ue[UE_id][TPUT_WINDOW_LENGTH-1] = (float) frame;
tput_ue[UE_id][TPUT_WINDOW_LENGTH-1] = ((float) total_dlsch_bitrate)/1000.0;
if (tput_ue[UE_id][TPUT_WINDOW_LENGTH-1] > tput_ue_max[UE_id]) {
tput_ue_max[UE_id] = tput_ue[UE_id][TPUT_WINDOW_LENGTH-1];
}
fl_set_xyplot_data(form->pdsch_tput,tput_time_ue[UE_id],tput_ue[UE_id],TPUT_WINDOW_LENGTH,"","","");
fl_set_xyplot_ybounds(form->pdsch_tput,0,tput_ue_max[UE_id]);
*/
fl_unfreeze_form
(
form
->
lte_phy_scope_ue
);
fl_check_forms
();
free
(
I
);
free
(
Q
);
free
(
chest_f_abs
);
free
(
llr0
);
free
(
bit0
);
free
(
llr1
);
free
(
bit1
);
free
(
bit_pdcch
);
free
(
llr_pdcch
);
for
(
arx
=
0
;
arx
<
nb_antennas_rx
;
arx
++
)
{
free
(
chest_t_abs
[
arx
]);
}
}
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