Wiki source code of MQTT Forward Instruction

Version 46.2 by Xiaoling on 2022/07/14 16:19
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1 **~ Table of Contents:**
2
3 {{toc/}}
4
5
6 = 1.  Introduction =
7
8
9 Dragino LoRa/LoRaWAN gateway support MQTT forwarding. It can forward the sensor data from LoRa network to MQTT server , and vice verse.
10
11
12 == 1.1  Support Devices ==
13
14
15 This MQTT forward instruction is for below devices:
16
17 * Firmware Version > LG02_LG08-5.3.1580178039 [[Firmware Download>>url:http://www.dragino.com/downloads/index.php?dir=LoRa_Gateway/LPS8/Firmware/Release/]]
18 * LG01N, OLG01N ((% style="color:red" %)**Warning**(%%): LG01-P LG01-S use another instruction: [[MQTT for LG01-P/LG01S>>doc:Through MQTT to upload data.WebHome]])
19 * LG02, OLG02
20 * LG308, DLOS8
21 * LPS8
22 * LIG16
23 * MS14 series if installed with the same firmware. (in this case, the MQTT forward will work , but no LoRa support)
24
25
26
27
28 = 2.  Firmware Change Log for MQTT feature =
29
30
31 (((
32 This instruction is wrote start from LG02_LG08-5.3.1580178039. Below is related change log since this version of firmware.
33 )))
34
35 * LG02_LG08-5.3.1580178039
36 ** Initiate version
37
38
39
40
41 = 3.  MQTT forward operating principle =
42
43
44 == 3.1  Network Structure ==
45
46
47 Below shows the network structure for MQTT forwarding.
48
49 * **For Uplink:**  The sensor sends data to LoRa Gateway via LoRa wireless, The gateway will process these data and forward to remote MQTT Broker via Internet.
50 * **For Downlink:** The gateway subscribe a topic in the MQTT broker, when there is update on the topic, the gateway will know and broadcast the data to Local LoRa network,
51
52 [[image:image-20220527133547-1.png]]
53
54 General MQTT structure
55
56
57 == 3.2  How sensor data is forwarded ==
58
59
60 In this MQTT forward feature, the key point is how the gateway process the sensor data.
61
62
63 === 3.2.1  Upstream ===
64
65 Assume there are two sensor nodes, their ID are Node1 ID: 6734 , Node2 ID: 7456. In the remote MQTT broker there are two topics: Topic1: /channel/765800, Topic2: /channel/367860. We can set up in the gateway to map Node1 to Topic1 and Node2 to Topic2. So when there is a sensor data from Node1, the gateway will forward the data to Topic1, when there is sensor data from Node2, the gateway will forward to Topic2.
66
67 (((
68 The data flow works as below diagram.
69 )))
70
71 [[image:image-20220527134000-2.png]]
72
73 (((
74 Upstream path
75
76
77 )))
78
79 (((
80 (% style="color:red" %)**Note: The sensor data can base or LoRa or other method, as long as there are data on the file /var/iot/channels. /span>**
81 )))
82
83 (((
84
85 )))
86
87 === 3.2.2  Downstream ===
88
89
90 The gateway subscribes to a topic of the remote MQTT broker topic. When there is some one publish a value on this topic. The gateway will get it and broadcast to local LoRa Network.
91
92 (((
93 Below are the data flow for downstream.
94 )))
95
96 [[image:image-20220527134038-3.png]]
97
98 Downstream path
99
100
101 == 3.3  Macro Definition ==
102
103
104 The MQTT publish command use Macro settings to generate flexible upstream payload for MQTT publish.
105
106 (((
107 Currently the (% style="color:#4f81bd" %)**-t (topic)**(%%) and (% style="color:#4f81bd" %)**-m (message)**(%%) support Macros.
108
109
110 )))
111
112 === 3.3.1  -t topic macro ===
113
114
115 * CHANNEL: Remote Channel ID
116 * CLIENTID: Client ID , Same as -i
117 * WRITE_API: Remote Channel Write API
118 * USERNAME: User ID (-u)
119 * HOSTNAME: Device Hostname
120
121 === 3.3.2  -m message macro ===
122
123
124 * HOSTNAME: Device Hostname
125 * CHANNEL: Remote Channel ID
126 * DATA: Sensor Data without time stamp and rssi
127 * META: Completely sensor data with time stamp and rssi
128 * JSON: Convert META to json format.
129
130 === 3.3.3  Example for Macro ===
131
132
133 [[image:image-20220527134251-4.png]]
134
135 MQTT Publish configure
136
137
138 **Above screen shots shows below format:**
139
140 * -t: CLIENTID/CHANNEL/data
141 * -m: DATA
142
143 When there is a LoRa sensor arrive. it will be store at the /var/iot/channels as below:
144
145 [[image:image-20220527134332-5.png]]
146
147 Sensor Data
148
149
150 (((
151 According to above macro. Gateway will publish (% style="color:#4f81bd" %)**field1=22.0&field2=49.0**(%%) to topic: (% style="color:#4f81bd" %)**dragino-1b7060/78901/data**(%%), where 78901 is the remote channel for this node ID.
152 )))
153
154
155
156 == 3.4  Modify the MQTT to support more options ==
157
158
159 The MQTT Client Utility used in Dragino is **mosquitto_pub** and **mosquitto_sub**. User can add more options to the mqtt commands. User can check the valid options by command mosquitto_pub ~-~-help. as below:
160
161 (% class="box" %)
162 (((
163 root@dragino-1ec39c:~~# mosquitto_pub ~-~-help
164 mosquitto_pub is a simple mqtt client that will publish a message on a single topic and exit.
165 mosquitto_pub version 1.6.4 running on libmosquitto 1.6.4.
166 \\Usage: mosquitto_pub {[-h host] [-p port] [-u username] [-P password] -t topic | -L URL}
167 {-f file | -l | -n | -m message}
168 [-c] [-k keepalive] [-q qos] [-r] [~-~-repeat N] [~-~-repeat-delay time]
169 [-A bind_address]
170 [-i id] [-I id_prefix]
171 [-d] [~-~-quiet]
172 [-M max_inflight]
173 [-u username [-P password]]
174 [~-~-will-topic [~-~-will-payload payload] [~-~-will-qos qos] [~-~-will-retain]]
175 [{~-~-cafile file | ~-~-capath dir} [~-~-cert file] [~-~-key file]
176 [~-~-ciphers ciphers] [~-~-insecure]
177 [~-~-tls-alpn protocol]
178 [~-~-tls-engine engine] [~-~-keyform keyform] [~-~-tls-engine-kpass-sha1]]
179 [~-~-psk hex-key ~-~-psk-identity identity [~-~-ciphers ciphers]]
180 [~-~-proxy socks-url]
181 [~-~-property command identifier value]
182 [-D command identifier value]
183 mosquitto_pub ~-~-help
184 \\-A : bind the outgoing socket to this host/ip address. Use to control which interface
185 the client communicates over.
186 -d : enable debug messages.
187 -D : Define MQTT v5 properties. See the documentation for more details.
188 -f : send the contents of a file as the message.
189 -h : mqtt host to connect to. Defaults to localhost.
190 -i : id to use for this client. Defaults to mosquitto_pub_ appended with the process id.
191 -I : define the client id as id_prefix appended with the process id. Useful for when the
192 broker is using the clientid_prefixes option.
193 -k : keep alive in seconds for this client. Defaults to 60.
194 -L : specify user, password, hostname, port and topic as a URL in the form:
195 mqtt(s):~/~/[username[:password]@]host[:port]/topic
196 -l : read messages from stdin, sending a separate message for each line.
197 -m : message payload to send.
198 -M : the maximum inflight messages for QoS 1/2..
199 -n : send a null (zero length) message.
200 -p : network port to connect to. Defaults to 1883 for plain MQTT and 8883 for MQTT over TLS.
201 -P : provide a password
202 -q : quality of service level to use for all messages. Defaults to 0.
203 -r : message should be retained.
204 -s : read message from stdin, sending the entire input as a message.
205 -t : mqtt topic to publish to.
206 -u : provide a username
207 -V : specify the version of the MQTT protocol to use when connecting.
208 Can be mqttv5, mqttv311 or mqttv31. Defaults to mqttv311.
209 ~-~-help : display this message.
210 ~-~-repeat : if publish mode is -f, -m, or -s, then repeat the publish N times.
211 ~-~-repeat-delay : if using ~-~-repeat, wait time seconds between publishes. Defaults to 0.
212 ~-~-quiet : (% style="color:red" %)don't print error messages.
213 ~-~-will-payload : payload for the client Will, which is sent by the broker in case of
214 unexpected disconnection. If not given and will-topic is set, a zero
215 length message will be sent.
216 ~-~-will-qos : QoS level for the client Will.
217 ~-~-will-retain : if given, make the client Will retained.
218 ~-~-will-topic : the topic on which to publish the client Will.
219 ~-~-cafile : path to a file containing trusted CA certificates to enable encrypted
220 communication.
221 ~-~-capath : path to a directory containing trusted CA certificates to enable encrypted
222 communication.
223 ~-~-cert : client certificate for authentication, if required by server.
224 ~-~-key : client private key for authentication, if required by server.
225 ~-~-keyform : keyfile type, can be either "pem" or "engine".
226 ~-~-ciphers : openssl compatible list of TLS ciphers to support.
227 ~-~-tls-version : TLS protocol version, can be one of tlsv1.3 tlsv1.2 or tlsv1.1.
228 Defaults to tlsv1.2 if available.
229 ~-~-insecure : do not check that the server certificate hostname matches the remote
230 hostname. Using this option means that you cannot be sure that the
231 remote host is the server you wish to connect to and so is insecure.
232 Do not use this option in a production environment.
233 ~-~-tls-engine : If set, enables the use of a TLS engine device.
234 ~-~-tls-engine-kpass-sha1 : SHA1 of the key password to be used with the selected SSL engine.
235 ~-~-psk : pre-shared-key in hexadecimal (no leading 0x) to enable TLS-PSK mode.
236 ~-~-psk-identity : client identity string for TLS-PSK mode.
237 ~-~-proxy : SOCKS5 proxy URL of the form:
238 socks5h:~/~/[username[:password]@]hostname[:port]
239 Only "none" and "username" authentication is supported.
240 \\See https:~/~/mosquitto.org/ for more information.
241 )))
242
243
244 (((
245 and modify the /usr/bin/mqtt_process.sh script, the location to change the command option is below lines:
246 )))
247
248 (% class="box" %)
249 (((
250 //# Call MQTT Publish command
251 \\# 1. Case with User, Password and Client ID present  (e.g. Azure)
252 if [ ! -z "$pass" ] && [ ! -z "$user" ] && [ ! -z "$clientID" ]; then
253 case="1" 
254 mosquitto_pub $D -h $server -p $port -q $pub_qos -i $clientID -t $pub_topic -u $user -P "$pass" $C $cafile $PUB_FLAG "$mqtt_data"
255 \\# 2. Case with Certificate, Key and ClientID present (e.g. AWS)
256 elif [ ! -z "$certfile" ] && [ ! -z "$key" ] && [ ! -z "$clientID" ]; then
257 case="2" 
258 mosquitto_pub $D -h $server -p $port -q $pub_qos -i $clientID -t $pub_topic ~-~-cert $cert ~-~-key $key $C $cafile $PUB_FLAG "$mqtt_data"
259 \\# 3. Case with no User, Certificate or ClientID present
260 elif [ -z "$user" ] && [ -z "$certfile" ] && [ -z "$clientID" ]; then
261 case="3" 
262 mosquitto_pub $D -h $server -p $port -q $pub_qos -t $pub_topic $PUB_FLAG "$mqtt_data"
263 \\# 4. Case with no User, Certificate, but with ClientID present
264 elif [ -z "$user" ] && [ -z "$certfile" ] && [ ! -z "$clientID" ]; then
265 case="4" 
266 mosquitto_pub $D -h $server -p $port -q $pub_qos -i $clientID -t $pub_topic $PUB_FLAG "$mqtt_data"
267 \\# 5. Case with User and ClientID present, but no Password and no Certificate present
268 elif [ -z "$pass" ] && [ -z "$certfile" ] && [ ! -z "$user" ] && [ ! -z "$clientID" ]; then
269 case="5" 
270 mosquitto_pub $D -h $server -p $port -q $pub_qos -i $clientID -t $pub_topic -u $user $PUB_FLAG "$mqtt_data"
271 \\# 6. Case with User and Password present, but no ClientID and no Certificate present
272 elif [ ! -z "$user" ] && [ ! -z "$pass" ] && [ -z "$clientID" ] && [ -z "$certfile" ]; then
273 case="6" 
274 mosquitto_pub $D -h $server -p $port -q $pub_qos  -t $pub_topic -u $user -P "$pass" $PUB_FLAG "$mqtt_data"
275 \\# 0. Else - invalid parameters, just log
276 else
277 case="(% style="color:red" %)Invalid parameters" (%%)
278 logger (% style="color:red" %)"[IoT.MQTT]:Invalid Parameters - mosquitto_pub not called."(%%)
279 fi//
280 )))
281
282
283
284 = 4.  Example to communicate to a simple MQTT server =
285
286
287 == 4.1  Overview ==
288
289
290 This section is an example to show how to set up LG01-N to communicate with a MQTT server. The MQTT server is a simple utility set up in a local PC. Note: User can set up same server via [[this instruction>>url:http://www.steves-internet-guide.com/install-mosquitto-broker/]].
291
292
293 == 4.2  Simulate via MQTT.fx utility ==
294
295
296 The [[MQTT.fx>>url:http://mqttfx.jensd.de/index.php/download]] is a MQTT client tool. We can use this to simulate a MQTT connection to our MQTT broker first to make sure the MQTT broker works. This will also help us understand how it works.
297
298 (((
299 In this test, the MQTT broker and MQTT.fx are installed in the same PC, so the MQTT server address in MQTT.fx should be localhost. Below shows how to connect to the server.
300 )))
301
302 [[image:image-20220527134929-6.png]]
303
304 Connect to MQTT Broker
305
306
307 After connected, use publish to public some thing to MQTT server. This to simulate upsteam
308
309 [[image:image-20220527135037-7.png]]
310
311 Upstream: Publish message to MQTT Broker
312
313
314 To simulate a downstream, use MQTT.fx to subscribe a topic, and publish something to this topic. as Below:
315
316 [[image:image-20220527135215-8.png]]
317
318 Downstream: Subscribe a topic to get downstream
319
320
321
322 == 4.3  Simulate via Dragino Command Line ==
323
324 For first try of MQTT connection, simulate via command line is recommend, there are many servers / connection type for MQTT. They are using different connection parameters. Simulating the connection via command line will help us rapidly connect to server and debug.
325
326 In the Dragino Gateway, we use [[mosquitto client>>url:https://mosquitto.org/]] for MQTT connection.
327
328
329 (% style="color:blue" %)**For Upstream**
330
331 command is [[mosquitto_pub>>url:https://mosquitto.org/man/mosquitto_pub-1.html]]
332
333 Example: mosquitto_pub -h 192.168.199.148 -p 1883 -t /channel/6543 -m temp=36
334
335 Note: 192.168.199.148 is MQTT broker address, the gateway and the MQTT broker PC are in the same network.
336
337 [[image:image-20220527135310-9.png]]
338
339 mosquitto_pub
340
341
342
343 (% style="color:blue" %)**For Downstream**
344
345 Use [[mosquitto_sub>>url:https://mosquitto.org/man/mosquitto_sub-1.html]] to subscribe the change on the topic.
346
347 [[image:image-20220527135440-10.png]]
348
349 mosquitto_sub
350
351
352 == 4.4  Configure Dragino UI for MQTT connection ==
353
354 This chapter are step by step to show to configure the Dragino Menu for MQTT auto connection.
355
356 (((
357 Go to (% style="color:#4f81bd" %)**Dragino Menu ~-~-> MQTT Client**
358 )))
359
360 [[image:image-20220714155901-1.png]]
361
362 go to mqtt configure menu
363
364
365 (((
366 Select (% style="color:#4f81bd" %)**Forward to MQTT server**. (% style="color:red" %)**Notice**(%%): This option is removed from the latest firmware, in the latest firmware, if user submit "SAVE & APPLY" in MQTT page, the gateway will use MQTT service.
367 )))
368
369 [[image:image-20220527135742-11.png]]
370
371 forward to MQTT
372
373
374
375 === 4.4.1  Configure the MQTT Client for Upstream ===
376
377
378 **Below screenshot is same as the publish command:**
379
380 (% class="box" %)
381 (((
382 **mosquitto_pub -h 192.168.199.148 -p 1883 -i dragino-1b7060 -t CLIENTID/CHANNEL/data -m DATA
383 ~/~/where the CLIENTID, CHANNEL & DATA are macro. represent for
384 ~/~/CLIENTID: dragino-1b7060
385 ~/~/CHANNEL: Remote ID in Channel settings; here is 78901 or 567456
386 ~/~/DATA: The data stores in /var/iot/channels/**
387 )))
388
389
390 [[image:image-20220527135828-12.png]]
391
392 MQTT Publish configure
393
394
395
396 [[image:image-20220527135929-13.png]]
397
398 MQTT Channel settings
399
400
401 (((
402 For example, if we put a data(temp=46) on the file /var/iot/channels/4567, because 4567 match the remote channel 78901. the gateway will run this command:
403 )))
404
405 (% class="box" %)
406 (((
407 mosquitto_pub -h 192.168.199.148 -p 1883 -i dragino-1b7060 -t dragino-1b7060/78901/data -m temp=46
408 )))
409
410 (((
411 to MQTT broker.
412 )))
413
414
415 (((
416 Below is a simulation to put this data to active the MQTT publish.
417 )))
418
419 [[image:image-20220527140023-14.png]]
420
421 MQTT Publish
422
423
424
425 === 4.4.2  Configure the MQTT Client for Downstream ===
426
427
428 Below screen shot equal to this subscribe command:
429
430 (% class="box" %)
431 (((
432 mosquitto_sub -h 192.168.199.148 -p 1883 -i dragino-1b7060 -t command.
433 )))
434
435 [[image:image-20220527140100-15.png]]
436
437 MQTT Subscribe
438
439
440 (((
441 When MQTT broker receive a update on this topic, the gateway will get the update and use LoRa radio to broadcast this message. The LoRa parameters used for update is:
442 )))
443
444 [[image:image-20220527140148-16.png]]
445
446 LoRa Broadcast parameters.
447
448
449 And below is the subscribe simulation:
450
451 [[image:image-20220527140238-17.png]]
452
453 downstream simulation
454
455
456 == 4.5  Add LoRa support to communicate with remote sensor ==
457
458
459 In above section, we have configured the UI to support MQTT upstream and downstream. We can simulate via Linux command. In this section, we will guide how to communicate with remote LoRa End Node for upstream and downstream.
460
461
462 === 4.5.1  Use LoRa Raw protocol for communication ~-~- For LG01/LG02 ===
463
464
465 (((
466 We can use [[LoRa Shield>>url:http://www.dragino.com/products/lora/item/102-lora-shield.html]] to send LoRa Raw data to Gateway and receive data from gateway.
467 )))
468
469 (((
470 The example Sketch for LoRa Shield +Arduino is here: [[LoRa_Shield_Sketch_For_MQTT>>url:http://www.dragino.com/downloads/index.php?dir=LoraShield/]]
471 )))
472
473 (((
474 And this link is the required library: [[arduino-LoRa-master>>url:http://www.dragino.com/downloads/index.php?dir=LoraShield/]]. Unzip this library and put in Arduino library location.
475
476
477 )))
478
479 (((
480 What does the Arduino Sketch do? The Arduino Sketch will:
481 )))
482
483 * Upstream: Keep sending a LoRa Message every minutes with this payload : <4567>tem=xx&hum=yy (Where xx and yy are temperature and humidity value generated randomly).
484 * Downstream: Listening broadcast message from gateway, and print it in console.
485 * The LoRa parameter settings in Arduino should match the LoRa settings in gateway, as below:
486
487 [[image:image-20220527140354-18.png]]
488
489 LoRa Parameter should match
490
491
492
493 Below is the test result after the Arduino Sketch is running.
494
495 [[image:image-20220527140459-19.png]]
496
497 Upstream Data Flow
498
499
500
501 [[image:image-20220527140542-20.png]]
502
503 Downstream Data Flow
504
505
506
507 === 4.5.2  Use LoRaWAN Protocol for communication ~-~- For LG308/LPS8/DLOS8 ===
508
509
510 (((
511 Since firmware (% style="color:#4f81bd" %)**LG02_LG08~-~-build-v5.3.1585192026-20200326-1109,**(%%) Dragino LoRaWAN gateways support the communication to LoRaWAN (% style="color:#4f81bd" %)**ABP end node**(%%) locally without the need of LoRaWAN server. This feature allow us to integrate MQTT in the gateway to support LoRaWAN to MQTT forwarding or visa verse.
512 )))
513
514 (((
515 When use test this feature, please use the version higher then : (% style="color:#4f81bd" %)**LG02_LG08~-~-build-v5.4.1593400722-20200629-1120**(%%), in this version, the upload format is changed and readable, which is easier for integration.
516
517
518 (% style="color:#4f81bd" %)**Video Instruction**(%%): (% style="color:blue" %)[[https:~~/~~/youtu.be/qJTY441-t90>>url:https://youtu.be/qJTY441-t90]]
519 )))
520
521 (((
522 (% style="color:blued" %)**Step 1**(%%): Refer [[Communicate with ABP End Node>>Communicate with ABP End Node without LoRaWAN Network Server --- LG308]] to know how to set up LG308 to work with LoRaWAN End node.
523 )))
524
525 (((
526 (% style="color:blue" %)**Step 2**(%%): Make sure your Radio settings match the End Node settings.
527 )))
528
529 [[image:image-20220527141235-21.png]]
530
531 Use Same Frequency Band as End Node
532
533
534 (((
535 (((
536 (% style="color:blue" %)**Step 3**(%%): Set up publish format and MQTT channel. The LG308 will store the Data from End node in (% style="color:#4f81bd" %)**HEX format**(%%) in the file.
537 )))
538 )))
539
540 [[image:image-20220613191345-4.png]]
541
542
543
544 (% style="color:blue" %)**Step 4**(%%): Map the Device Address to Remote ID in MQTT server.
545
546 [[image:image-20220613190635-2.png]]
547
548
549
550 (% style="color:blue" %)**Step 5: Upstream**(%%): Save the change, we can see the log info via "sytem log", End Node and MQTT Server
551
552 [[image:image-20220527141843-24.png]]
553
554
555
556
557 [[image:image-20220527141933-25.png]]
558
559 Choose ASCII Format
560
561
562
563 [[image:image-20220527142028-26.png]]
564
565 LHT65 Decoder
566
567
568
569 (% style="color:blue" %)**Step 6: Set up subscribe**(%%)**:** Subscribe a topci for downstream.
570
571 [[image:image-20220613191426-5.png]]
572
573
574
575 (% style="color:blue" %)**Step 7: Downstream**(%%): Save the change, we can see the log info via "sytem log", End Node and MQTT Server.
576
577 [[image:image-20220527142239-28.png]]
578
579
580
581 === 4.5.3 MQTT Downstream format ===
582
583
584 mosquitto_pub -h $server_address -p $server_port -t $Client_ID -m "**dev_addr,imme/time,txt/hex,payload**"
585
586 (% class="box infomessage" %)
587 (((
588 **mosquitto_pub -h 10.130.2.192 -p 1883 -t dragino-1d25dc/ -m "260211D,time,txt,hello"**
589 )))
590
591 mosquitto_pub -h $server_address -p $server_port -t $Client_ID -m "**dev_addr,imme/time,txt/hex,payload,txpw,txbw,SF,frequency,rxwindow**"
592
593 (% class="box infomessage" %)
594 (((
595 **mosquitto_pub -h 10.130.2.192 -p 1883 -t dragino-1d25dc/ -m "260211D,time,txt,hello,20,1,SF12,923300000,2 > /var/iot/push/test"**
596 )))
597
598 Or use [[MQTT.fx>>https://mqttfx.jensd.de/index.php/download]]
599
600 [[image:image-20220613192816-6.png||height="440" width="1056"]]
601
602
603 (% style="color:red" %)**Notice: The text use for Downstream must meet the requirement from [[LG308 Downstream Payload>>Communicate with ABP End Node without LoRaWAN Network Server --- LG308||anchor="H2.2Downstream"]]**
604
605
606 Check out this link for more mosquito-related directives [[https:~~/~~/mosquitto.org/man/mosquitto_pub-1.html>>https://mosquitto.org/man/mosquitto_pub-1.html]]
607
608
609
610 = 5.  How to Debug =
611
612
613 User can login the gateway's console and run (% style="color:#4f81bd" %)**logread -f**(%%). It will shows the output when there is packet arrive.User can see if it is correct.
614
615
616 = 6.  How to ask for Support =
617
618
619 If a user still not have trouble making it works. please send a mail to support@dragino.com with the below info:
620
621 * Detail of your LoRaWAN end node.
622 * Gateway Model and firmware version
623 * A set of screenshots you configure in the gateway according to our instruction
624 * A full log of "logread -f"
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