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...	...	@@ -18,19 +18,21 @@
18	18
19	19	(((
20	20	(((
21		-The Dragino RS485-LN is a RS485 to LoRaWAN Converter. It converts the RS485 signal into LoRaWAN wireless signal which simplify the IoT installation and reduce the installation/maintaining cost.
	21	+The Dragino RS485-LN is a **RS485 to LoRaWAN Converter**. It converts the RS485 signal into LoRaWAN wireless signal which simplify the IoT installation and reduce the installation/maintaining cost.
22	22	)))
23	23
24	24	(((
25		-RS485-LN allows user to monitor / control RS485 devices and reach extremely long ranges. It provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption. It targets professional wireless sensor network applications such as irrigation systems, smart metering, smart cities, smartphone detection, building automation, and so on.
	25	+RS485-LN allows user to **monitor / control RS485 devices** and reach extremely long ranges. It provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption. It targets professional wireless sensor network applications such as irrigation systems, smart metering, smart cities, smartphone detection, building automation, and so on.
26	26	)))
27	27
28	28	(((
29		-For data uplink, RS485-LN sends user-defined commands to RS485 devices and gets the return from the RS485 devices. RS485-LN will process these returns according to user-define rules to get the final payload and upload to LoRaWAN server.
	29	+**For data uplink**, RS485-LN sends user-defined commands to RS485 devices and gets the return from the RS485 devices. RS485-LN will process these returns according to user-define rules to get the final payload and upload to LoRaWAN server.
30	30	)))
31	31
32	32	(((
33		-For data downlink, RS485-LN runs in LoRaWAN Class C. When there downlink commands from LoRaWAN server, RS485-LN will forward the commands from LoRaWAN server to RS485 devices.
	33	+**For data downlink**, RS485-LN runs in LoRaWAN Class C. When there downlink commands from LoRaWAN server, RS485-LN will forward the commands from LoRaWAN server to RS485 devices.
	34	+
	35	+**Demo Dashboard for RS485-LN** connect to two energy meters: [[https:~~/~~/app.datacake.de/dashboard/d/58844a26-378d-4c5a-aaf5-b5b5b153447a>>url:https://app.datacake.de/dashboard/d/58844a26-378d-4c5a-aaf5-b5b5b153447a]]
34	34	)))
35	35	)))
36	36
...	...	@@ -41,17 +41,17 @@
41	41	**Hardware System:**
42	42
43	43	* STM32L072CZT6 MCU
44		-* SX1276/78 Wireless Chip
	46	+* SX1276/78 Wireless Chip
45	45	* Power Consumption (exclude RS485 device):
46	46	** Idle: 32mA@12v
47	47
48		-*
	50	+*
49	49	** 20dB Transmit: 65mA@12v
50	50
51	51	**Interface for Model:**
52	52
53	53	* RS485
54		-* Power Input 7~~ 24V DC.
	56	+* 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
	121	+(((
119	119	Once there is power, the RS485-LN will be on.
	123	+)))
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.
	133	+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"]]
	140	+[[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		-)))
	143	+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
	145	+485A+ and 485B- of the sensor are connected to RS485A and RA485B of RS485-LN respectively.
	146	+
	147	+[[image:1653268227651-549.png||height="592" width="720"]]
	148	+
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:
	150	+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.
	154	+**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:
	158	+Each RS485-LN is shipped with a sticker with unique device EUI:
152	152	)))
	160	+)))
153	153
154	154	[[image:1652953462722-299.png]]
155	155
156	156	(((
	165	+(((
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	)))
	172	+)))
163	163
164		-
165		-
166		-
167	167	[[image:image-20220519174512-1.png]]
168	168
169		-[[image:image-20220519174512-2.png||height="328" width="731"]]
	176	+[[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.
	192	+**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.
	200	+(((
	201	+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
	204	+(((
	205	+(% 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
	206	+)))
	207	+)))
	208	+
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.
	211	+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.
	255	+
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.
	275	+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	)))
	277	+)))
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
	370	+(((
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.
	372	+)))
378	378
	374	+(((
379	379	In the RS485-BL, we should use this command AT+COMMAND1=01 03 0B B8 00 02,1 for the same.
	376	+)))
380	380
	378	+(((
381	381	**AT+SEARCHx**: This command defines how to handle the return from AT+COMMANDx.
	380	+)))
382	382
383	383	(% border="1" class="table-bordered" %)
384	384	|(((
...	...	@@ -390,26 +390,24 @@
390	390
391	391	)))
392	392
393		-Examples:
	392	+**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
	394	+~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
	398	+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]]
	400	+[[image:1653269403619-508.png]]
402	402
	402	+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
	406	+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]]
	408	+[[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]]
	424	+[[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]]
	428	+[[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]]
	432	+[[image:1653269593172-426.png||height="303" width="725"]]
436	436
	434	+(% 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
	440	+(% style="color:red" %)AT+COMMAND1=11 01 1E D0,0
445	445
446		-AT+SEARCH1=1,1E 56 34
	442	+(% style="color:red" %)AT+SEARCH1=1,1E 56 34
447	447
448		-AT+DATACUT1=0,2,1~~5
	444	+(% 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
	446	+(% 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
	448	+(% 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
	450	+(% 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]]
	452	+[[image:1653269618463-608.png]]
457	457
	454	+=== 3.3.4 Compose the uplink payload ===
458	458
459		-
460		-
461		-1.
462		-11.
463		-111. Compose the uplink payload
464		-
	456	+(((
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.**
	458	+)))
466	466
	460	+(((
	461	+(% style="color:#4f81bd" %)**Examples: AT+DATAUP=0**
	462	+)))
467	467
468		-**Examples: AT+DATAUP=0**
	464	+(((
	465	+Compose the uplink payload with value returns in sequence and send with (% style="color:red" %)**A SIGNLE UPLINK**.
	466	+)))
469	469
470		-Compose the uplink payload with value returns in sequence and send with **A SIGNLE UPLINK**.
471		-
	468	+(((
472	472	Final Payload is
	470	+)))
473	473
474		-Battery Info+PAYVER + VALID Value from RETURN1 + Valid Value from RETURN2 + … + RETURNx
	472	+(((
	473	+(% style="color:#4f81bd" %)**Battery Info+PAYVER + VALID Value from RETURN1 + Valid Value from RETURN2 + … + RETURNx**
	474	+)))
475	475
	476	+(((
476	476	Where PAYVER is defined by AT+PAYVER, below is an example screen shot.
	478	+)))
477	477
478		-[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image019.png]]
	480	+[[image:1653269759169-150.png||height="513" width="716"]]
479	479
	482	+(% style="color:#4f81bd" %)**Examples: AT+DATAUP=1**
480	480
	484	+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
	488	+(% 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
	494	+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]]
	496	+[[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
	501	+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
	503	+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
	505	+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]]
	509	+[[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:
	512	+(% 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
	522	+=== 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:
...	...	@@ -537,8 +537,8 @@
537	537
538	538
539	539
540		-1.
541		-11.
	534	+1.
	535	+11.
542	542	111. Uplink on Interrupt
543	543
544	544	Put the interrupt sensor between 3.3v_out and GPIO ext.[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image022.png]]
...	...	@@ -552,7 +552,7 @@
552	552	AT+INTMOD=3  Interrupt trigger by rising edge.
553	553
554	554
555		-1.
	549	+1.
556	556	11. Uplink Payload
557	557
558	558	|**Size(bytes)**|**2**|**1**|**Length depends on the return from the commands**
...	...	@@ -614,15 +614,15 @@
614	614
615	615	* **Sensor Related Commands**: These commands are special designed for RS485-BL.  User can see these commands below:
616	616
617		-1.
618		-11.
	611	+1.
	612	+11.
619	619	111. Common Commands:
620	620
621	621	They should be available for each of Dragino Sensors, such as: change uplink interval, reset device. For firmware v1.3, user can find what common commands it supports: [[http:~~/~~/wiki.dragino.com/index.php?title=End_Device_AT_Commands_and_Downlink_Commands>>url:http://wiki.dragino.com/index.php?title=End_Device_AT_Commands_and_Downlink_Commands]]
622	622
623	623
624		-1.
625		-11.
	618	+1.
	619	+11.
626	626	111. Sensor related commands:
627	627
628	628	==== Choose Device Type (RS485 or TTL) ====
...	...	@@ -928,13 +928,13 @@
928	928
929	929
930	930
931		-1.
	925	+1.
932	932	11. Buttons
933	933
934	934	|**Button**|**Feature**
935	935	|**RST**|Reboot RS485-BL
936	936
937		-1.
	931	+1.
938	938	11. +3V3 Output
939	939
940	940	RS485-BL has a Controllable +3V3 output, user can use this output to power external sensor.
...	...	@@ -952,7 +952,7 @@
952	952	By default, the AT+3V3T=0. This is a special case, means the +3V3 output is always on at any time
953	953
954	954
955		-1.
	949	+1.
956	956	11. +5V Output
957	957
958	958	RS485-BL has a Controllable +5V output, user can use this output to power external sensor.
...	...	@@ -972,13 +972,13 @@
972	972
973	973
974	974
975		-1.
	969	+1.
976	976	11. LEDs
977	977
978	978	|**LEDs**|**Feature**
979	979	|**LED1**|Blink when device transmit a packet.
980	980
981		-1.
	975	+1.
982	982	11. Switch Jumper
983	983
984	984	|**Switch Jumper**|**Feature**
...	...	@@ -1024,7 +1024,7 @@
1024	1024
1025	1025
1026	1026
1027		-1.
	1021	+1.
1028	1028	11. Common AT Command Sequence
1029	1029	111. Multi-channel ABP mode (Use with SX1301/LG308)
1030	1030
...	...	@@ -1043,8 +1043,8 @@
1043	1043
1044	1044	ATZ
1045	1045
1046		-1.
1047		-11.
	1040	+1.
	1041	+11.
1048	1048	111. Single-channel ABP mode (Use with LG01/LG02)
1049	1049
1050	1050	AT+FDR   Reset Parameters to Factory Default, Keys Reserve
...	...	@@ -1119,7 +1119,7 @@
1119	1119	[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image035.png]] [[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image036.png]]
1120	1120
1121	1121
1122		-1.
	1116	+1.
1123	1123	11. How to change the LoRa Frequency Bands/Region?
1124	1124
1125	1125	User can follow the introduction for [[how to upgrade image>>path:#upgrade_image]]. When download the images, choose the required image file for download.
...	...	@@ -1126,7 +1126,7 @@
1126	1126
1127	1127
1128	1128
1129		-1.
	1123	+1.
1130	1130	11. How many RS485-Slave can RS485-BL connects?
1131	1131
1132	1132	The RS485-BL can support max 32 RS485 devices. Each uplink command of RS485-BL can support max 16 different RS485 command. So RS485-BL can support max 16 RS485 devices pre-program in the device for uplink. For other devices no pre-program, user can use the [[downlink message (type code 0xA8) to poll their info>>path:#downlink_A8]].
...	...	@@ -1143,7 +1143,7 @@
1143	1143
1144	1144
1145	1145
1146		-1.
	1140	+1.
1147	1147	11. Why I can’t join TTN V3 in US915 /AU915 bands?
1148	1148
1149	1149	It might about the channels mapping. Please see for detail.

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