Last modified by Karry Zhuang on 2025/03/06 16:34
<
From version < 20.2 >
edited by Xiaoling
on 2022/05/23 09:08
To version < 31.3 >
edited by Xiaoling
on 2022/05/23 09:48
>
Change comment: There is no comment for this version

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... ... @@ -41,7 +41,7 @@
41 41  **Hardware System:**
42 42  
43 43  * STM32L072CZT6 MCU
44 -* SX1276/78 Wireless Chip
44 +* SX1276/78 Wireless Chip 
45 45  * Power Consumption (exclude RS485 device):
46 46  ** Idle: 32mA@12v
47 47  
... ... @@ -51,7 +51,7 @@
51 51  **Interface for Model:**
52 52  
53 53  * RS485
54 -* Power Input 7~~ 24V DC.
54 +* Power Input 7~~ 24V DC. 
55 55  
56 56  **LoRa Spec:**
57 57  
... ... @@ -116,7 +116,9 @@
116 116  * Power Source VIN to RS485-LN VIN+
117 117  * Power Source GND to RS485-LN VIN-
118 118  
119 +(((
119 119  Once there is power, the RS485-LN will be on.
121 +)))
120 120  
121 121  [[image:1653268091319-405.png]]
122 122  )))
... ... @@ -126,7 +126,7 @@
126 126  == 3.1 How it works? ==
127 127  
128 128  (((
129 -The RS485-BL is configured as LoRaWAN OTAA Class A mode by default. It has OTAA keys to join network. To connect a local LoRaWAN network, user just need to input the OTAA keys in the network server and power on the RS485-BL. It will auto join the network via OTAA.
131 +The RS485-LN is configured as LoRaWAN OTAA Class C mode by default. It has OTAA keys to join network. To connect a local LoRaWAN network, user just need to input the OTAA keys in the network server and power on the RS485-LN. It will auto join the network via OTAA.
130 130  )))
131 131  
132 132  == 3.2 Example to join LoRaWAN network ==
... ... @@ -133,27 +133,32 @@
133 133  
134 134  Here shows an example for how to join the TTN V3 Network. Below is the network structure, we use [[LG308>>url:http://www.dragino.com/products/lora-lorawan-gateway/item/140-lg308.html]] as LoRaWAN gateway here. 
135 135  
136 -[[image:1652953414711-647.png||height="337" width="723"]]
138 +[[image:1653268155545-638.png||height="334" width="724"]]
137 137  
138 138  (((
139 -The RS485-BL in this example connected to two RS485 devices for demonstration, user can connect to other RS485 devices via the same method.
140 -)))
141 +The RS485-LN in this example connected to two RS485 devices for demonstration, user can connect to other RS485 devices via the same method. The connection is as below:
141 141  
143 +485A+ and 485B- of the sensor are connected to RS485A and RA485B of RS485-LN respectively.
144 +
145 +[[image:1653268227651-549.png||height="592" width="720"]]
146 +
142 142  (((
143 -The LG308 is already set to connect to [[TTN V3 network >>url:https://www.thethingsnetwork.org/]]. So what we need to now is only configure the TTN V3:
148 +The LG308 is already set to connect to [[TTN V3 network >>path:eu1.cloud.thethings.network/]]. So what we need to now is only configure the TTN V3:
144 144  )))
145 145  
146 146  (((
147 -**Step 1**: Create a device in TTN V3 with the OTAA keys from RS485-BL.
152 +**Step 1**: Create a device in TTN V3 with the OTAA keys from RS485-LN.
148 148  )))
149 149  
150 150  (((
151 -Each RS485-BL is shipped with a sticker with unique device EUI:
156 +Each RS485-LN is shipped with a sticker with unique device EUI:
152 152  )))
158 +)))
153 153  
154 154  [[image:1652953462722-299.png]]
155 155  
156 156  (((
163 +(((
157 157  User can enter this key in their LoRaWAN Server portal. Below is TTN V3 screen shot:
158 158  )))
159 159  
... ... @@ -160,13 +160,11 @@
160 160  (((
161 161  Add APP EUI in the application.
162 162  )))
170 +)))
163 163  
164 -
165 -
166 -
167 167  [[image:image-20220519174512-1.png]]
168 168  
169 -[[image:image-20220519174512-2.png||height="328" width="731"]]
174 +[[image:image-20220519174512-2.png||height="323" width="720"]]
170 170  
171 171  [[image:image-20220519174512-3.png||height="556" width="724"]]
172 172  
... ... @@ -182,7 +182,7 @@
182 182  
183 183  
184 184  (((
185 -**Step 2**: Power on RS485-BL and it will auto join to the TTN V3 network. After join success, it will start to upload message to TTN V3 and user can see in the panel.
190 +**Step 2**: Power on RS485-LN and it will auto join to the TTN V3 network. After join success, it will start to upload message to TTN V3 and user can see in the panel.
186 186  )))
187 187  
188 188  [[image:1652953568895-172.png||height="232" width="724"]]
... ... @@ -190,23 +190,19 @@
190 190  == 3.3 Configure Commands to read data ==
191 191  
192 192  (((
193 -There are plenty of RS485 and TTL level devices in the market and each device has different command to read the valid data. To support these devices in flexible, RS485-BL supports flexible command set. User can use [[AT Commands or LoRaWAN Downlink>>path:#AT_COMMAND]] Command to configure how RS485-BL should read the sensor and how to handle the return from RS485 or TTL sensors.
198 +(((
199 +There are plenty of RS485 devices in the market and each device has different command to read the valid data. To support these devices in flexible, RS485-LN supports flexible command set. User can use [[AT Commands>>path:#AT_COMMAND]] or LoRaWAN Downlink Command to configure what commands RS485-LN should send for each sampling and how to handle the return from RS485 devices.
194 194  )))
195 195  
202 +(((
203 +(% style="color:red" %)Note: below description and commands are for firmware version >v1.1, if you have firmware version v1.0. Please check the [[user manual v1.0>>url:http://www.dragino.com/downloads/index.php?dir=RS485-LN/&file=RS485-LN_UserManual_v1.0.1.pdf]] or upgrade the firmware to v1.1
204 +)))
205 +)))
206 +
196 196  === 3.3.1 onfigure UART settings for RS485 or TTL communication ===
197 197  
198 -RS485-BL can connect to either RS485 sensors or TTL sensor. User need to specify what type of sensor need to connect.
209 +To use RS485-LN to read data from RS485 sensors, connect the RS485-LN A/B traces to the sensors. And user need to make sure RS485-LN use the match UART setting to access the sensors. The related commands for UART settings are:
199 199  
200 -**~1. RS485-MODBUS mode:**
201 -
202 -AT+MOD=1 ~/~/ Support RS485-MODBUS type sensors. User can connect multiply RS485 , Modbus sensors to the A / B pins.
203 -
204 -**2. TTL mode:**
205 -
206 -AT+MOD=2 ~/~/ Support TTL Level sensors, User can connect one TTL Sensor to the TXD/RXD/GND pins.
207 -
208 -RS485-BL default UART settings is **9600, no parity, stop bit 1**. If the sensor has a different settings, user can change the RS485-BL setting to match.
209 -
210 210  (% border="1" style="background-color:#ffffcc; color:green; width:795px" %)
211 211  |(((
212 212  **AT Commands**
... ... @@ -231,13 +231,7 @@
231 231  |(((
232 232  AT+PARITY
233 233  )))|(% style="width:285px" %)(((
234 -(((
235 235  Set UART parity (for RS485 connection)
236 -)))
237 -
238 -(((
239 -Default Value is: no parity.
240 -)))
241 241  )))|(% style="width:347px" %)(((
242 242  (((
243 243  AT+PARITY=0
... ... @@ -255,7 +255,7 @@
255 255  )))
256 256  
257 257  (((
258 -Default Value is: 1bit.
253 +
259 259  )))
260 260  )))|(% style="width:347px" %)(((
261 261  (((
... ... @@ -274,12 +274,10 @@
274 274  === 3.3.2 Configure sensors ===
275 275  
276 276  (((
277 -Some sensors might need to configure before normal operation. User can configure such sensor via PC or through RS485-BL AT Commands (% style="color:#4f81bd" %)**AT+CFGDEV**.
278 -)))
279 -
280 280  (((
281 -When user issue an (% style="color:#4f81bd" %)**AT+CFGDEV**(%%) command, Each (% style="color:#4f81bd" %)**AT+CFGDEV**(%%) equals to send a command to the RS485 or TTL sensors. This command will only run when user input it and won’t run during each sampling.
273 +Some sensors might need to configure before normal operation. User can configure such sensor via PC and RS485 adapter or through RS485-LN AT Commands (% style="color:#4f81bd" %)**AT+CFGDEV**(%%). Each (% style="color:#4f81bd" %)**AT+CFGDEV **(%%)equals to send a RS485 command to sensors. This command will only run when user input it and won’t run during each sampling.
282 282  )))
275 +)))
283 283  
284 284  (% border="1" style="background-color:#ffffcc; color:green; width:806px" %)
285 285  |**AT Commands**|(% style="width:418px" %)**Description**|(% style="width:256px" %)**Example**
... ... @@ -291,8 +291,6 @@
291 291  mm: 0: no CRC, 1: add CRC-16/MODBUS in the end of this command
292 292  )))|(% style="width:256px" %)AT+CFGDEV=xx xx xx xx xx xx xx xx xx xx xx xx,m
293 293  
294 -Detail of AT+CFGDEV command see [[AT+CFGDEV detail>>path:#AT_CFGDEV]].
295 -
296 296  === 3.3.3 Configure read commands for each sampling ===
297 297  
298 298  (((
... ... @@ -374,11 +374,17 @@
374 374  **m: 0: no CRC, 1: add CRC-16/MODBUS in the end of this command**
375 375  )))
376 376  
368 +(((
377 377  For example, if we have a RS485 sensor. The command to get sensor value is: 01 03 0B B8 00 02 46 0A. Where 01 03 0B B8 00 02 is the Modbus command to read the register 0B B8 where stored the sensor value. The 46 0A is the CRC-16/MODBUS which calculate manually.
370 +)))
378 378  
372 +(((
379 379  In the RS485-BL, we should use this command AT+COMMAND1=01 03 0B B8 00 02,1 for the same.
374 +)))
380 380  
376 +(((
381 381  **AT+SEARCHx**: This command defines how to handle the return from AT+COMMANDx.
378 +)))
382 382  
383 383  (% border="1" class="table-bordered" %)
384 384  |(((
... ... @@ -390,26 +390,24 @@
390 390  
391 391  )))
392 392  
393 -Examples:
390 +**Examples:**
394 394  
395 -1. For a return string from AT+COMMAND1: 16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
392 +~1. For a return string from AT+COMMAND1: 16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
396 396  
397 397  If we set AT+SEARCH1=1,1E 56 34.      (max 5 bytes for prefix)
398 398  
399 -The valid data will be all bytes after 1E 56 34 , so it is 2e 30 58 5f 36 41 30 31 00 49
396 +The valid data will be all bytes after 1E 56 34 , so it is (% style="background-color:yellow" %)** 2e 30 58 5f 36 41 30 31 00 49**
400 400  
401 -[[image:1652954654347-831.png]]
398 +[[image:1653269403619-508.png]]
402 402  
400 +2. For a return string from AT+COMMAND1:  16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
403 403  
404 -1. For a return string from AT+COMMAND1:  16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
405 -
406 406  If we set AT+SEARCH1=2, 1E 56 34+31 00 49
407 407  
408 -Device will search the bytes between 1E 56 34 and 31 00 49. So it is 2e 30 58 5f 36 41 30
404 +Device will search the bytes between 1E 56 34 and 31 00 49. So it is (% style="background-color:yellow" %)** 2e 30 58 5f 36 41 30**
409 409  
410 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image014.png]]
406 +[[image:1653269438444-278.png]]
411 411  
412 -
413 413  **AT+DATACUTx : **This command defines how to handle the return from AT+COMMANDx, max return length is 45 bytes.
414 414  
415 415  |(((
... ... @@ -424,94 +424,95 @@
424 424  
425 425  * Grab bytes:
426 426  
427 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image015.png]]
422 +[[image:1653269551753-223.png||height="311" width="717"]]
428 428  
429 429  * Grab a section.
430 430  
431 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image016.png]]
426 +[[image:1653269568276-930.png||height="325" width="718"]]
432 432  
433 433  * Grab different sections.
434 434  
435 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image017.png]]
430 +[[image:1653269593172-426.png||height="303" width="725"]]
436 436  
432 +(% style="color:red" %)**Note:**
437 437  
438 -Note:
439 -
440 440  AT+SEARCHx and AT+DATACUTx can be used together, if both commands are set, RS485-BL will first process AT+SEARCHx on the return string and get a temporary string, and then process AT+DATACUTx on this temporary string to get the final payload. In this case, AT+DATACUTx need to set to format AT+DATACUTx=0,xx,xx where the return bytes set to 0.
441 441  
442 442  Example:
443 443  
444 -AT+COMMAND1=11 01 1E D0,0
438 +(% style="color:red" %)AT+COMMAND1=11 01 1E D0,0
445 445  
446 -AT+SEARCH1=1,1E 56 34
440 +(% style="color:red" %)AT+SEARCH1=1,1E 56 34
447 447  
448 -AT+DATACUT1=0,2,1~~5
442 +(% style="color:red" %)AT+DATACUT1=0,2,1~~5
449 449  
450 -Return string from AT+COMMAND1: 16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
444 +(% style="color:red" %)Return string from AT+COMMAND1: 16 0c 1e 56 34 2e 30 58 5f 36 41 30 31 00 49
451 451  
452 -String after SEARCH command: 2e 30 58 5f 36 41 30 31 00 49
446 +(% style="color:red" %)String after SEARCH command: 2e 30 58 5f 36 41 30 31 00 49
453 453  
454 -Valid payload after DataCUT command: 2e 30 58 5f 36
448 +(% style="color:red" %)Valid payload after DataCUT command: 2e 30 58 5f 36
455 455  
456 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image018.png]]
450 +[[image:1653269618463-608.png]]
457 457  
452 +=== 3.3.4 Compose the uplink payload ===
458 458  
459 -
460 -
461 -1.
462 -11.
463 -111. Compose the uplink payload
464 -
454 +(((
465 465  Through AT+COMMANDx and AT+DATACUTx we got valid value from each RS485 commands, Assume these valid value are RETURN1, RETURN2, .., to RETURNx. The next step is how to compose the LoRa Uplink Payload by these RETURNs. The command is **AT+DATAUP.**
456 +)))
466 466  
458 +(((
459 +(% style="color:#4f81bd" %)**Examples: AT+DATAUP=0**
460 +)))
467 467  
468 -**Examples: AT+DATAUP=0**
462 +(((
463 +Compose the uplink payload with value returns in sequence and send with (% style="color:red" %)**A SIGNLE UPLINK**.
464 +)))
469 469  
470 -Compose the uplink payload with value returns in sequence and send with **A SIGNLE UPLINK**.
471 -
466 +(((
472 472  Final Payload is
468 +)))
473 473  
474 -Battery Info+PAYVER + VALID Value from RETURN1 + Valid Value from RETURN2 + … + RETURNx
470 +(((
471 +(% style="color:#4f81bd" %)**Battery Info+PAYVER + VALID Value from RETURN1 + Valid Value from RETURN2 + … + RETURNx**
472 +)))
475 475  
474 +(((
476 476  Where PAYVER is defined by AT+PAYVER, below is an example screen shot.
476 +)))
477 477  
478 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image019.png]]
478 +[[image:1653269759169-150.png||height="513" width="716"]]
479 479  
480 +(% style="color:#4f81bd" %)**Examples: AT+DATAUP=1**
480 480  
482 +Compose the uplink payload with value returns in sequence and send with (% style="color:red" %)**Multiply UPLINKs**.
481 481  
482 -**Examples: AT+DATAUP=1**
483 -
484 -Compose the uplink payload with value returns in sequence and send with **Multiply UPLINKs**.
485 -
486 486  Final Payload is
487 487  
488 -Battery Info+PAYVER + PAYLOAD COUNT + PAYLOAD# + DATA
486 +(% style="color:#4f81bd" %)**Battery Info+PAYVER + PAYLOAD COUNT + PAYLOAD# + DATA**
489 489  
490 490  1. Battery Info (2 bytes): Battery voltage
491 491  1. PAYVER (1 byte): Defined by AT+PAYVER
492 492  1. PAYLOAD COUNT (1 byte): Total how many uplinks of this sampling.
493 493  1. PAYLOAD# (1 byte): Number of this uplink. (from 0,1,2,3…,to PAYLOAD COUNT)
494 -1. DATA: Valid value: max 6 bytes(US915 version here, [[Notice*!>>path:#max_byte]]) for each uplink so each uplink <= 11 bytes. For the last uplink, DATA will might less than 6 bytes
492 +1. DATA: Valid value: max 6 bytes(US915 version here, Notice*!) for each uplink so each uplink <= 11 bytes. For the last uplink, DATA will might less than 6 bytes
495 495  
496 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image020.png]]
494 +[[image:1653269916228-732.png||height="433" width="711"]]
497 497  
498 498  
499 499  So totally there will be 3 uplinks for this sampling, each uplink includes 6 bytes DATA
500 500  
501 -DATA1=RETURN1 Valid Value = 20 20 0a 33 90 41
499 +DATA1=RETURN1 Valid Value = (% style="background-color:green; color:white" %)20 20 0a 33 90 41
502 502  
503 -DATA2=1^^st^^ ~~ 6^^th^^ byte of Valid value of RETURN10= 02 aa 05 81 0a 20
501 +DATA2=1^^st^^ ~~ 6^^th^^ byte of Valid value of RETURN10=(% style="background-color:green; color:white" %) 02 aa 05 81 0a 20
504 504  
505 -DATA3=7^^th^^ ~~ 11^^th^^ bytes of Valid value of RETURN10 = 20 20 20 2d 30
503 +DATA3=7^^th^^ ~~ 11^^th^^ bytes of Valid value of RETURN10 = (% style="background-color:green; color:white" %)20 20 20 2d 30
506 506  
507 -
508 -
509 509  Below are the uplink payloads:
510 510  
511 -[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image021.png]]
507 +[[image:1653270130359-810.png]]
512 512  
513 513  
514 -Notice: the Max bytes is according to the max support bytes in different Frequency Bands for lowest SF. As below:
510 +(% style="color:red" %)**Notice: the Max bytes is according to the max support bytes in different Frequency Bands for lowest SF. As below:**
515 515  
516 516   ~* For AU915/AS923 bands, if UplinkDwell time=0, max 51 bytes for each uplink ( so 51 -5 = 46 max valid date)
517 517  
... ... @@ -521,12 +521,8 @@
521 521  
522 522   ~* For all other bands: max 51 bytes for each uplink  ( so 51 -5 = 46 max valid date).
523 523  
520 +=== 3.3.5 Uplink on demand ===
524 524  
525 -
526 -1.
527 -11.
528 -111. Uplink on demand
529 -
530 530  Except uplink periodically, RS485-BL is able to uplink on demand. The server sends downlink command to RS485-BL and RS485 will uplink data base on the command.
531 531  
532 532  Downlink control command:
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