1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
|
; This is an advanced configuration example for ODR-DabMux,
; that documents more options that the simple example.mux
; More information about the usage of the tools is available
; in the guide, which can be found on the
; www.opendigitalradio.org website.
;
; The format is called INFO format, and defined by boost property_tree:
; http://www.boost.org/doc/libs/1_41_0/doc/html/boost_propertytree/parsers.html#boost_propertytree.parsers.info_parser
; It consists of six mandatory sections, whose relative order in this
; file are of no importance.
; The general section defines global multiplex parameters.
general {
; the DAB Transmission mode (values 1-4 accepted)
dabmode 1
; the number of ETI frames to generate (set to 0 to get an unlimited number)
nbframes 10
; boolean fileds can accept either false or true as values:
; Enable logging to syslog
syslog false
; Write the SCCA field useful for the Factum ETI analyser
writescca false
; Enable timestamp definition necessary for SFN
; This also enables time encoding using the MNSC and in EDI.
tist false
; On startup, the timestamp is initialised to system time. If you want
; to add an offset, uncomment the following line and give a number
; in seconds.
; tist_offset 0
; The management server is a simple TCP server that can present
; statistics data (buffers, overruns, underruns, etc)
; which can then be graphed a tool like Munin
; The doc/stats_dabmux_multi.py tool is a suitable
; plugin for that.
; If the port is zero, or the line commented, the server
; is not started.
managementport 12720
}
remotecontrol {
; enable the telnet remote control server on the given port
; This server allows you to read and define parameters that
; some features export. It is only accessible from localhost.
; Set the port to 0 to disable the server
telnetport 12721
; the remote control server makes use of the unique identifiers
; for the subchannels, services and components. Make sure you
; chose them so that you can identify them.
}
; Some ensemble parameters
ensemble {
; Example for Switzerland, with country id=4 and ECC=E1
id 0x4fff ; you can also use decimal if you want
ecc 0xe1 ; Extended Country Code
local-time-offset auto ; autmatically calculate from system local time
; or
;local-time-offset 1 ; in hours, supports half-hour offsets
international-table 1 ; See TS 101 756 clause 5.7
; 1 corresponds to the PTy used in RDS
; 2 corresponds to program types used in north america
;reconfig-counter 1 ; Uncomment this option to enable FIG0/7, which specifies that
; the ensemble is compliant to EN 300 401 version 2
; This setting sets the Count field of FIG0/7, which is a
; modulo-1024 binary counter that increments by one for every multiplex reconfiguration.
; all labels are maximum 16 characters in length
label "OpenDigitalRadio"
; The short label is built from the label by erasing letters, and cannot
; be longer than 8 characters. If omitted, it will be truncated from the
; label
shortlabel "ODR"
; Announcement settings for FIG0/19.
announcements {
test_announcement {
cluster 1
flags {
Traffic true
}
subchannel sub-fu
}
}
}
; Definition of DAB services
services {
; Each service has it's own unique identifier, that is
; used throughout the configuration file and for the RC.
srv-fu {
id 0x4daa
label "Funk"
shortlabel "Fu"
; Programme Type, according to the chosen international-table above.
pty 0
; chose between static and dynamic PTy
; static means the PTy represents to overall genre of the programme.
; dynamic means the PTy follows the various items within a programme.
; Use the RC interface to modify at runtime.
; See EN 300 401 Clause 8.1.5
pty-sd static
language 0
; also supports id
; List of announcement switching flags signalled in FIG 0/18
; This lists all possible announcements. If one is left out, it is disabled.
announcements {
Alarm false
Traffic true
Travel false
Warning false
News false
Weather false
Event false
Special false
ProgrammeInfo false
Sports false
Finance false
; a comma separated list of clusters in which the service belongs to
clusters "1,2"
}
}
srv-ri {
; If your ensemble contains a service from another country,
; specify its ECC here. Example is for Italy, country id=5, ECC=E0
id 0x5dab
ecc 0xe0
label "rick"
}
srv-lu {
id 0x4dac
label "Lu"
; pty, language, shortlabel and id can be omitted, and will take default values
}
}
; The subchannels are defined in the corresponding section.
; supported types are : audio, data, enhancedpacket,
; dabplus, packet
;
; Type 'packet' expects to receive data in the format described
; in EN 300 401 Clause 5.3.2.
;
; 'enhancedpacket' mode will calculate FEC for MSC packet mode
; as described in EN 300 401 Clause 5.3.5.
;
; 'data' will read from the source and write it unmodified into
; the MSC.
subchannels {
sub-fu {
type audio
bitrate 128
id 10
; type audio subchannels automatically use
; UEP, unless the bitrate is 8, 16, 24, 40 or 144kbit/s
; (EN 300 401 Clause 6.2.1)
; this can be overridden with the option protection-profile
protection-profile EEP_A
; supported options: UEP (use only for type audio!)
; EEP_A (for all bitrates)
; EEP_B (bitrates multiple of 32kbit/s)
; Set the protection level, possible values depend
; on the protection profile:
; UEP profile: 1 to 5; EEP profiles: 1 to 4
protection 4
; example file input
inputproto file
inputuri "funk.mp2"
nonblock false
}
sub-lu {
type dabplus
bitrate 96
id 3
protection 3
; EXPERIMENTAL!
; Receive STI-D(LI) carried in STI(PI, X) inside RTP using UDP.
; This is intended to be compatible with AVT audio encoders.
; EXPERIMENTAL!
inputproto sti
inputuri "rtp://127.0.0.1:32010"
}
sub-ri {
type dabplus
bitrate 96
id 1
protection 1
; example file input
;inputuri "rick.dabp"
; example zmq input:
; Accepts connections to port 9000 from any interface.
inputproto zmq
inputuri "tcp://*:9000"
; ZMQ specific options, mandatory:
; Maximum size of input buffer, in AAC frames (24ms)
; when this buffer size is reached, some frames will be
; discarded to get the size again below this value.
; As the present implementation discards entire AAC superframes,
; (5 frames = 120ms) the effect will clearly be audible.
zmq-buffer 40
; At startup or after an underrun, the buffer is filled to this
; amount of AAC frames before streaming starts.
zmq-prebuffering 20
; In an ideal scenario, where the input rate exactly corresponds
; to the rate at which the frames are consumed by dabmux, you
; see the buffer level staying around the zmq-prebuffering value.
; Network latency jitter can make it temporarily go lower or higher.
; Encoder clock drift will make the buffer either slowly fill or
; empty, which will create intermittent glitches.
; the ZMQ inputs support encryption using the CURVE method.
; The multiplexer must have a public and a private key, which
; can be shared among several zmq inputs.
;
; each encoder also has a public and private key, and the
; encoder *public* key has to be known to the multiplexer.
; Using this system, the multiplexer can be sure that
; only the encoder possessing the right secret key can
; connect here. This inhibits third parties to hijack the
; input.
; by default, it is disabled, set encryption to 1 to enable
encryption true
; the multiplexer key pair. Keep these secret.
secret-key "keys/mux.sec"
public-key "keys/mux.pub"
; The public key from the encoder. Only the encoder you want
; to accept must know the corresponding secret key.
encoder-key "keys/encoder1.pub"
; key pairs can be generated using the zmqinput-keygen tool.
}
; 'prbs' will generate a pseudorandom bit sequence according to
; ETS 300 799 Clause G.2.1. This is useful for testing purposes and
; measurement of bit error rate.
sub-prbs {
type data
bitrate 16
id 5
protection 3
; Use the default PRBS polynomial.
inputproto prbs
inputuri "prbs://"
; To use another polynomial, set it in the url as hexadecimal
; The default polynomial is G(x) = x^20 + x^17 + 1, represented as
; (1 << 20) + (1 << 17) + (1 << 0) = 0x120001
;inputuri "prbs://:0x120001
}
}
; For now, each component links one service to one subchannel
components {
; the component unique identifiers are used for the RC.
comp-fu {
; specifies audio -or- packet type, defaults to zero when not given
; audio: foreground=0, background=1, multi-channel=2
; data: unspecified=0, TMC=1, EWS=2, ITTS=3, paging=4, TDC=5, IP=59, MOT=60, proprietary=61
type 0
; According to specification, you should not define component labels if
; the service is only used in one component. The service label is sufficient
; in that case.
;label "funk"
;shortlabel "fu"
service srv-fu
subchannel sub-fu
; for audio components, the field
figtype 0x2
; defines the User Application Type according to TS 101 756 Table 16:
; 0x2 : MOT Slideshow
; 0x3 : MOT Broadcast Web Site
; 0x4 : TPEG
; 0x5 : DGPS
; 0x6 : TMC
; 0x7 : EPG
; 0x8 : DAB Java
; 0x44a : Journaline
; If not defined, the FIG 0/13 is not transmitted for this component
; for packet components, the fields
; "user application type in FIG 0/13 for packet mode"
;figtype
; and the packet address (mandatory)
;address
; are supported, with the same syntax as in the manpage.
; FIG 0/13 is only transmitted when figtype is defined.
; The -d option on the command line is:
;datagroup (true|false)
; and defaults to false. You should normally set
;datagroup true
; if your packet mode subchannel is tranferring an MOT application such
; as EPG or Slideshow.
}
; If a service is used in more than one component, the primary component has to
; be placed above the secondary component(s) to ensure that the SCIdS field of FIG0/8
; is zero for the primary service component. (New in EN 300 401 V2.1.1)
comp-lu {
service srv-lu
subchannel sub-lu
figtype 0x2
}
comp-ri {
service srv-ri
subchannel sub-ri
figtype 0x2
}
}
outputs {
; The unique-id can be used by the remote control or the statistics server
; to identify the output
; Important! For real-time operation, you need to have exactly one
; output that applies back-pressure to ODR-DabMux, otherwise it will run
; at the highest possible rate on your system!
;
; For an output to a pipe, the data consumer at the other end of the pipe
; will dictate the multiplexing rate to ODR-DabMux.
;
; If you use the zmq or EDI outputs, you must also enable a simul:// output!
;supported output types for file and fifo outputs are
; raw, framed and streamed
;
; Please see doc/dab_output_formats.txt
;stdout "fifo:///dev/stdout?type=raw"
; Throttle output to real-time (one ETI frame every 24ms)
throttle "simul://"
edi {
; If TIST is enabled, requires leap-second information (see example.mux)
destinations {
; The names you give to the destinations have no meaning,
; but have to be unique. You can give them meaningful names to help
; you identify the outputs.
example_unicast {
; example for unicast EDI over UDP
; for unicast EDI, do not set source
protocol udp
destination "192.168.23.23"
sourceport 13000
}
example_multicast {
; example for multicast EDI, the source IP is required
; so that the data is sent on the correct ethernet interface
protocol udp
destination "232.20.10.1"
source "192.168.0.50"
; The multicast TTL has to be adapted according to your network
ttl 1
sourceport 13000
}
example_tcp {
; example for EDI TCP server. TCP is reliable, so it is counterproductive to
; use FEC. Using PFT also brings no benefit.
protocol tcp
listenport 13000
; For every connected endpoint, a queue is created. If the queue overflows, we
; assume the endpoint has a problem, and we close the connection. This sets
; the max queue size in number of frames. With PFT disabled, one frame is generated
; every 24ms. With PFT enabled, it depends on fragmentation and FEC settings.
;
; default value: 500 frames, without PFT: 12s worth of EDI data
;max_frames_queued 500
}
}
; The settings below apply to all destinations
; The destination port cannot be set independently for
; different outputs because it is encoded in the transport
; header of the PFT layer.
; Necessary when using UDP, optional when only using TCP.
port 12000
; Enable the PFT subsystem. If false, AFPackets are sent.
; PFT is not necessary when using TCP.
enable_pft false
; How many lost fragments can be recovered by Reed-Solomon.
; Requires enable_pft true.
;
; If set to 0, the PFT subsystem will only do Fragmentation and
; Transport, but no Reed Solomon.
; See ETSI TS 102 821, Clause 7 "PFT Layer", Figure 10. ODR-DabMux
; supports "Fragmentation and Transportation" and "Reed-Solomon and
; Transportation".
fec 2
; Interleave fragments from several ETI frames so as to reduce the
; probability of errors when several UDP packets are lost in bursts.
; This comes at the cost of larger overall latency between multiplexing
; and modulation. This latency is given in milliseconds, and rounded
; to nearest multiple of 24ms. Set to 0 to disable the interleaver.
interleave 0
; Length of a RS chunk, can be overridden
;default=207
;chunk_len 207
; Save the packets sent over Ethernet to the file ./edi.debug
dump false
; show more debugging info
verbose false
; (optional) set the kind of alignment to use in TAG Packets
; 0: no padding
; 8: pad to eight bytes (default)
; above 8: insert *dmy TAG Item to pad to given size in bytes
;tagpacket_alignment 8
}
; Other outputs:
; ZeroMQ output example, new configuration format. Several
; zeromq blocks can be added here.
; This output does not back-pressure the multiplexer.
;zeromq {
; Listen on all interfaces, on port 9100
;endpoint "tcp://*:9100"
; Transmit backward compatible metadata containing
; EDI time and UTC offset when TIST is enabled.
;
; If TIST is enabled, requires leap-second information (see example.mux)
;
; WARNING! requires ODR-DabMux to be compiled with
; cURL support, and this will enable leap second download
; as for the EDI output!
;allowmetadata true
;}
; Legacy format for ZeroMQ output example. See example.mux
; for newer format.
;zmq "zmq+tcp://*:9100"
; Output ETI-over-TCP. This is like piping a RAW ETI NI data stream
; into a TCP socket, except that the output can handle simultaneous
; connections. Not suitable for SFN use because timestamps are incomplete.
; 0.0.0.0 means "listen on all interfaces"
; This output does not back-pressure the multiplexer.
;tcp "tcp://0.0.0.0:9200"
; UDP send to host:port, simple example for unicast
;net_udp "udp://host:port"
; example with source and TTL specification for multicast
;net_udp "udp://237.10.0.230:7000?src=10.0.1.125&ttl=1"
; RAW for farsync ETI card
;farsync "raw://sync0"
; the output also supports two parameters:
; clocking=master and clocking=slave
;
; and extsyncclock which enables external clock sync. Its value is the
; external clock frequency in Hz.
; Example:
;farsync "raw://sync0?clocking=master&extsyncclock=10000000"
}
|