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Content

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1	1
2	2
3	3	(% style="text-align:center" %)
4		-[[image:1652409757234-446.png]]
	4	+[[image:1652409757234-446.png||height="399" width="399"]]
5	5
6	6
7	7
...	...	@@ -8,7 +8,7 @@
8	8	**DLOS8N Outdoor LoRaWAN Gateway User Manual**
9	9
10	10
11		-Table of Contents
	11	+**Table of Contents：**
12	12
13	13	{{toc/}}
14	14
...	...	@@ -19,24 +19,35 @@
19	19
20	20	== 1.1 What is the DLOS8N ==
21	21
	22	+(((
22	22	The DLOS8N is an (% style="color:#4f81bd" %)open source outdoor LoRaWAN Gateway. (% style="color:black" %)It lets you bridge LoRa wireless network to an IP network via WiFi, Ethernet, 3G or 4G cellular. The LoRa wireless allows users to send data and reach extremely long ranges at low data-rates.
	24	+)))
23	23
	26	+(((
24	24	DLOS8N supports (% style="color:#4f81bd" %)Semtech packet forwarder (% style="color:black" %)and (% style="color:#4f81bd" %)LoRaWAN Station connection, (% style="color:black" %)it is fully compatible with LoRaWAN protocol. DLOS8N includes a (% style="color:#4f81bd" %)SX1302 LoRaWAN concentrator.
	28	+)))
25	25
	30	+(((
26	26	DLOS8N has (% style="color:#4f81bd" %)pre-configured standard LoRaWAN frequency bands (% style="color:black" %)to use for different countries.User can also customize the frequency bands to use in their own LoRaWAN network.
	32	+)))
27	27
	34	+(((
28	28	DLOS8N can communicate with ABP LoRaWAN end node without LoRaWAN server. System integrator can use it to integrate with their existing IoT Service without set up own LoRaWAN server or use 3rd party LoRaWAN service.
	36	+)))
29	29
	38	+(((
30	30	DLOS8N supports (% style="color:#4f81bd" %) auto-provision (% style="color:black" %) for mass deployment and long term maintain. System intergrator can easily change the settings.
	40	+)))
31	31
32	32	[[image:1652411526195-923.png]]
33	33
34		-
35	35	== 1.2 Specifications ==
36	36
37	37	**Hardware System:**
38	38
	48	+(((
39	39	Linux Part:
	50	+)))
40	40
41	41	* 400Mhz ar9331 processor
42	42	* 64MB RAM
...	...	@@ -117,14 +117,12 @@
117	117
118	118	== 1.4 Hardware System Structure ==
119	119
120		-[[image:1652411641871-482.png||height="425" width="732"]]
	131	+[[image:1652411641871-482.png||height="416" width="716"]]
121	121
122		-
123	123	== 1.5 DLOS8N Applications ==
124	124
125	125	[[image:1652411671209-920.png||height="618" width="650"]]
126	126
127		-
128	128	== 1.6 LED Indicators ==
129	129
130	130	[[image:1652411720670-489.png]]
...	...	@@ -147,7 +147,6 @@
147	147	)))
148	148	)))
149	149
150		-
151	151	== 1.7 WiFi Direction ==
152	152
153	153	DLOS8N use directional WiFi Antenna. The best direction is as below:
...	...	@@ -154,7 +154,6 @@
154	154
155	155	[[image:1652412859663-161.png||height="341" width="333"]]
156	156
157		-
158	158	= 2. Access and Configure DLOS8N =
159	159
160	160	The DLOS8N is configured as a WiFi Access Point by default. User can access and configure the DLOS8N after connecting to its WiFi network, or via its Ethernet port.
...	...	@@ -165,7 +165,6 @@
165	165
166	166	[[image:1652412985720-934.png]]
167	167
168		-
169	169	At the first boot of DLOS8N, it will auto generate a WiFi network called (% style="color:green" %)**//dragino-xxxxxx //**(% style="color:black" %)with password:
170	170
171	171	[[image:1652413127647-377.png]]
...	...	@@ -172,17 +172,19 @@
172	172
173	173	(% style="background-color:#ffffcc" %)dragino+dragino
174	174
	181	+(((
175	175	User can use a PC to connect to this WiFi network. The PC will get an IP address 10.130.1.xxx and the DLOS8N has the default IP (% style="color:green" %)10.130.1.1
	183	+)))
176	176
177		-
178	178	=== 2.1.2 Connect via Ethernet with DHCP IP from router ===
179	179
180	180	[[image:1652414114583-532.png]]
181	181
182	182
	190	+(((
183	183	Alternatively, connect the DLOS8N Ethernet port to your router and DLOS8N will obtain an IP address from your router. In the router’s management portal, you should be able to find what IP address the router has assigned to the DLOS8N. You can also use this IP to connect.
	192	+)))
184	184
185		-
186	186	=== 2.1.3 Connect via WiFi with DHCP IP from router ===
187	187
188	188	[[image:1652414137639-956.png]]
...	...	@@ -190,12 +190,10 @@
190	190
191	191	If the DLOS8N already connect to the router via WiFi, use can use the WiFi IP to connect to DLOS8N.
192	192
193		-
194	194	=== 2.1.4 Connect via Ethernet with fall back ip ===
195	195
196	196	The WAN port also has a [[fall back ip address>>path:#_I_configured_LPS8]] for access if user doesn’t connect to uplink router. Click [[here>>path:#_I_configured_LPS8]] to see how to configure.
197	197
198		-
199	199	== 2.2 Access Configure Web UI ==
200	200
201	201	**Web Interface**
...	...	@@ -219,9 +219,6 @@
219	219
220	220	[[image:1652414287022-223.png]]
221	221
222		-
223		-
224		-
225	225	= 3. Typical Network Setup =
226	226
227	227	== 3.1 Overview ==
...	...	@@ -239,53 +239,56 @@
239	239
240	240	[[image:1652420169255-959.png]]
241	241
242		-
243	243	== 3.3 Access the Internet as a WiFi Client ==
244	244
245	245	In the WiFi Client Mode, DLOS8N acts as a WiFi client and gets DHCP from an upstream router via WiFi.
246	246
	249	+(((
247	247	The settings for WiFi Client is under page (% style="color:#4f81bd" %)**System~-~-> WiFi ~-~-> WiFi WAN Client Settings**
	251	+)))
248	248
249	249	[[image:1652420327792-211.png]]
250	250
251		-
	255	+(((
252	252	In the WiFi Survey Choose the WiFi AP, and input the Passphrase then click Save & Apply to connect.
	257	+)))
253	253
254		-
255	255	== 3.4 Access the Internet via Cellular ==
256	256
257	257	If the DLOS8N support 3G/4G Cellular modem option, When the label on the shell is displayed as Model : DLOS8N-EC25, it indicates that DLOS8 already has EC25 3G/4G modules,user can use it as main internet connection or back up.
258	258
259		-
	263	+(((
260	260	First, release the four screws of DLOS8N, pull out PCB and install SIM card as below:
	265	+)))
261	261
262	262	[[image:1652420606018-181.png]]
263	263
264	264
265		-[[image:1652420718132-929.png||height="450" width="766"]]
	270	+[[image:1652420718132-929.png||height="427" width="727"]]
266	266
267		-
	272	+(((
268	268	The set up page is (% style="color:#4f81bd" %)**System ~-~-> Cellular**
	274	+)))
269	269
270	270
	277	+(((
271	271	While use the cellular as Backup WAN, device will use Cellular for internet connection while WAN port or WiFi is not valid and switch back to WAN port or WiFi after they recover.
	279	+)))
272	272
273	273	[[image:1652421032117-341.png||height="329" width="752"]]
274	274
275	275	(% style="color:red" %)**Note** *: For DLOS8N which doesn’t have the cellular module, this page will shows Cellular not detected.
276	276
277		-
278	278	== 3.5 Check Internet connection ==
279	279
280	280	In the (% style="color:#4f81bd" %)**home**(%%) page, we can check the Internet connection.
281	281
282		-* GREEN Tick ​​​​[[image:1652421151598-130.png||height="23" width="24"]] : This interface has Internet connection.
283		-* Yellow Tick  [[image:1652421168047-470.png||height="22" width="21"]] : This interface has IP address but don’t use it for internet connection.
284		-* RED Cross   [[image:1652421179500-890.png||height="24" width="27"]] : This interface doesn’t connected.
	289	+* GREEN Tick ​​​​ [[image:1652436675869-206.png||height="14" width="15"]] : This interface has Internet connection.
	290	+* Yellow Tick   [[image:1652436705761-420.png||height="15" width="15"]] : This interface has IP address but don’t use it for internet connection.
	291	+* RED Cross    [[image:1652436787176-950.png||height="14" width="15"]] : This interface doesn’t connected.
285	285
286	286	[[image:1652421351382-793.png||height="339" width="765"]]
287	287
288		-
289	289	= 4. Example: Configure as a LoRaWAN gateway =
290	290
291	291	DLOS8N is fully compatible with LoRaWAN protocol. It uses the legacy Semtech Packet forwarder to forward the LoRaWAN packets to server. The structure is as below.
...	...	@@ -296,12 +296,13 @@
296	296
297	297	[[T>>url:https://www.thethingsnetwork.org/]]heThingsNetwork v3(T[[TN>>url:https://www.thethingsnetwork.org/]] v3[[)>>url:http://)]][[ LoRaWAN Server>>url:https://www.thethingsnetwork.org/]]  ([[www.thethingsnetwork.org>>url:http://www.thethingsnetwork.org/]])
298	298
299		-
300	300	== 4.1 Create a gateway in TTN V3 Server ==
301	301
302	302	(% style="color:#4f81bd" %)**Step 1: Get a Unique gateway ID.**
303	303
	309	+(((
304	304	Every DLOS8N has a unique gateway id. The ID can be found at LoRaWAN page:
	311	+)))
305	305
306	306	[[image:1652421929753-168.png||height="403" width="739"]]
307	307
...	...	@@ -345,7 +345,6 @@
345	345
346	346	[[image:1652422509034-682.png||height="299" width="739"]]
347	347
348		-
349	349	== 4.2 Configure DLOS8N to connect to TTN v3 ==
350	350
351	351	You can now configure the DLOS8N to let it connect to TTN network V3.
...	...	@@ -366,7 +366,6 @@
366	366
367	367	[[image:1652422703020-955.png||height="343" width="730"]]
368	368
369		-
370	370	== 4.3 Configure frequency ==
371	371
372	372	We also need to set the frequency plan in DLOS8N to match the end node we use, so to receive the LoRaWAN packets from the LoRaWAN sensor.
...	...	@@ -378,33 +378,56 @@
378	378
379	379	[[image:1652422763536-750.png||height="514" width="730"]]
380	380
	386	+== 4.4 Add a LoRaWAN End Device ==
381	381
382		-4.4 Add a LoRaWAN End Device
383		-
	388	+(((
384	384	This section shows how to add a LoRaWAN End device to a LoRaWAN network and see the data from TTN web site.
	390	+)))
385	385
	392	+(((
386	386	We use [[LT-22222-L>>url:http://www.dragino.com/products/lora-lorawan-end-node/item/156-lt-22222-l.html]] IO Controller as a reference device - the setup for other LoRaWAN devices will be similar.
	394	+)))
387	387
388	388	[[image:1652422794767-871.png]]
389	389
	398	+(((
390	390	(% style="color:#4f81bd" %)**Step 1**: (% style="color:black" %)Create a Device definition in TTN v3 with the OTAA keys from the example LT-22222-L IO Controller device.
	400	+)))
391	391
	402	+(((
392	392	Three codes are required to define the device in TTN v3:
	404	+)))
393	393
394	394	* DEV EUI - Unique ID code for a particular device.
395	395	* APP EUI - ID code for an Application defined in TTN v3.
396	396	* APP Key - Unique key to secure communications with a particular device.
397	397
	410	+(((
398	398	A set of these codes are stored in each device by the manufacturer as the default codes for that particular device. Each device is shipped with a sticker with the default Device EUI as shown below.
	412	+)))
399	399
400	400	[[image:1652422840936-838.png]]
401	401
402	402
	417	+(((
403	403	(% style="color:red" %)Note: You may be able to change these codes in a device by using a configuration facility on the device e.g. the LT-22222 uses a serial port access and a series of AT commands.  Changing the codes may be necessary in the case where you have to use codes assigned by a LoRa WAN server.
	419	+)))
404	404
	421	+(((
	422	+
	423	+)))
	424	+
	425	+(((
405	405	For the TTN v3 server, you can use the codes set in the device as in the following example.
	427	+)))
406	406
	429	+(((
	430	+
	431	+)))
	432	+
	433	+(((
407	407	Select **Add Application** to open the screen below.
	435	+)))
408	408
409	409	[[image:1652422946999-255.png||height="356" width="744"]]
410	410
...	...	@@ -414,10 +414,14 @@
414	414
415	415	[[image:1652422975885-591.png||height="359" width="726"]]
416	416
	445	+(((
417	417	Select OTAA activation mode
	447	+)))
418	418
419	419
	450	+(((
420	420	The LoRaWAN version for your device should be provided by the manufacturer in a datasheet as LoRaWAN version or LoRaWAN specification. The most commonly used LoRaWAN versions are v1.0.2 and v1.0.3.
	452	+)))
421	421
422	422	[[image:1652422998005-968.png||height="352" width="744"]]
423	423
...	...	@@ -429,16 +429,21 @@
429	429
430	430	[[image:1652423046741-467.png||height="355" width="736"]]
431	431
	464	+(((
432	432	Finally, Application layer settings input the corresponding AppKey. Before saving the configuration, check that the data matches the device.
	466	+)))
433	433
434	434
	469	+(((
435	435	(% style="color:#4f81bd" %)**Step 2**: (% style="color:black" %)Power on LT-22222-L device and it will automatically join the TTN network. After joining successfully, it will start to upload messages to the TTN v3. Select the Live data tab and you will see the data appearing in the panel.
	471	+)))
436	436
	473	+(((
437	437	(% style="color:red" %)Note that it may take some time for the device data to appear in the TTN v3 display.
	475	+)))
438	438
439	439	[[image:1652423277549-324.png||height="273" width="745"]]
440	440
441		-
442	442	= 5. Web Configure Pages =
443	443
444	444	== 5.1 Home ==
...	...	@@ -447,19 +447,24 @@
447	447
448	448	[[image:1652423418568-752.png||height="329" width="724"]]
449	449
450		-
451	451	== 5.2 LoRa Settings ==
452	452
453	453	=== 5.2.1 LoRa ~-~-> LoRa ===
454	454
	491	+(((
455	455	This page shows the LoRa Radio Settings. There are a set of default frequency band according to LoRaWAN protocol, and user can customized the band* as well.
	493	+)))
456	456
	495	+(((
457	457	Different DLOS8N hardware version can support different frequency range:
	497	+)))
458	458
459	459	* **868**: valid frequency: 863Mhz ~~ 870Mhz. for bands EU868, RU864, IN865 or KZ865.
460	460	* **915**: valid frequency: 902Mhz ~~ 928Mhz. for bands US915, AU915, AS923 or KR920
461	461
	502	+(((
462	462	After user choose the frequency plan, he can see the actually frequency in used by checking the page **LogRead ~-~-> LoRa Log**
	504	+)))
463	463
464	464	[[image:1652423554776-574.png||height="380" width="740"]]
465	465
...	...	@@ -467,7 +467,6 @@
467	467
468	468	[[http:~~/~~/wiki.dragino.com/index.php?title=Customized_Frequency_Band_for_Gateway>>url:http://wiki.dragino.com/index.php?title=Customized_Frequency_Band_for_Gateway]]
469	469
470		-
471	471	=== 5.2.2 LoRa ~-~-> ABP Decryption ===
472	472
473	473	The DLOS8N can communicate with LoRaWAN ABP End Node without the need of LoRaWAN server. It can be used in some cases such as:
...	...	@@ -475,11 +475,12 @@
475	475	* No internet connection.
476	476	* User wants to get data forward in gateway and forward to their server based on MQTT/HTTP, etc. (Combine ABP communication method and [[MQTT forward together>>http://8.211.40.43:8080/xwiki/bin/view/Main/MQTT%20Forward%20Instruction/]]).
477	477
	519	+(((
478	478	Detail of this feature: [[Communication with ABP End Node>>http://8.211.40.43:8080/xwiki/bin/view/Main/Communicate%20with%20ABP%20End%20Node%20without%20LoRaWAN%20Network%20Server%20---%20LG308/]]
	521	+)))
479	479
480	480	[[image:1652423628833-467.png||height="357" width="755"]]
481	481
482		-
483	483	== 5.3 LoRaWAN Settings ==
484	484
485	485	=== 5.3.1 LoRaWAN ~-~-> LoRaWAN ===
...	...	@@ -496,23 +496,26 @@
496	496
497	497	See :[[Filter unwanted LoRaWAN packets>>http://8.211.40.43:8080/xwiki/bin/view/Main/Filter%20unwanted%20LoRaWAN%20packets/]]
498	498
499		-
500	500	=== 5.3.2 LoRaWAN ~-~-> Amazon AWS-IoT ===
501	501
502	502	[[image:1652428499323-384.png||height="275" width="723"]]
503	503
	545	+(((
504	504	Please see this instruction to know more detail and demo for how to connect to AWS-IoT LoRaWAN Core: [[http:~~/~~/wiki.dragino.com/index.php?title=Notes_for_AWS-IoT-Core>>url:http://wiki.dragino.com/index.php?title=Notes_for_AWS-IoT-Core]]
	547	+)))
505	505
506		-
507	507	=== 5.3.3 LoRaWAN ~-~-> LORIOT ===
508	508
	551	+(((
509	509	Settings to communicate to LORIOT LoRaWAN Network Server: [[https:~~/~~/www.loriot.io/>>url:https://www.loriot.io/]]
	553	+)))
510	510
	555	+(((
511	511	Instruction: [[http:~~/~~/wiki.dragino.com/index.php?title=Notes_for_LORIOT>>url:http://wiki.dragino.com/index.php?title=Notes_for_LORIOT]]
	557	+)))
512	512
513	513	[[image:1652428648903-878.png||height="266" width="731"]]
514	514
515		-
516	516	== 5.4 MQTT Settings ==
517	517
518	518	If end nodes works in ABP mode, user can configure DLOS8N to transfer the data to MQTT broker,
...	...	@@ -647,7 +647,6 @@
647	647
648	648	[[image:1652429711145-862.png||height="270" width="737"]]
649	649
650		-
651	651	Select the required image and click **Flash Image.** The image will be uploaded to the device, and then click **Process Update** to upgrade.
652	652
653	653	(% style="color:red" %)**NOTE**: (% style="color:black" %)You normally need to **//uncheck//** the **Preserve Settings** checkbox when doing an upgrade to ensure that there is no conflict between the old settings and the new firmware. The new firmware will start up with its default settings.
...	...	@@ -670,6 +670,9 @@
670	670
671	671	[[image:1652430197132-330.png||height="256" width="724"]]
672	672
	717	+(((
	718	+
	719	+)))
673	673
674	674	=== 5.5.10 System ~-~-> Package Maintain ===
675	675
...	...	@@ -677,6 +677,9 @@
677	677
678	678	Place to show what package has installed and possible to upgrade packages.
679	679
	727	+(((
	728	+
	729	+)))
680	680
681	681	== 5.6 LogRead ==
682	682
...	...	@@ -686,6 +686,9 @@
686	686
687	687	Show the frequency for LoRa Radio and traffics.
688	688
	739	+(((
	740	+
	741	+)))
689	689
690	690	=== 5.6.2 LogRead ~-~-> System Log ===
691	691
...	...	@@ -700,6 +700,9 @@
700	700
701	701	[[http:~~/~~/wiki.dragino.com/index.php?title=Main_Page#LoRa.2FLoRaWAN_Gateway_Instruction>>url:http://wiki.dragino.com/index.php?title=Main_Page#LoRa.2FLoRaWAN_Gateway_Instruction]]
702	702
	756	+(((
	757	+
	758	+)))
703	703
704	704	= 7. Linux System =
705	705
...	...	@@ -780,7 +780,7 @@
780	780	)))
781	781
782	782	(((
783		-(% style="background-color:#dcdcdc" %)//Downloading //[[//http:~~/~~/downloads.openwrt.org/snapshots/packages/mips_24kc/base/iperf_2.0.12-1_mips_24kc.ipk//>>url:http://downloads.openwrt.org/snapshots/packages/mips_24kc/base/iperf_2.0.12-1_mips_24kc.ipk]]
	839	+(% style="background-color:#dcdcdc" %)//Downloading //[[(% style="background-color: rgb(220, 220, 220); background-color: rgb(220, 220, 220)" %)//http:~~/~~/downloads.openwrt.org/snapshots/packages/mips_24kc/base/iperf_2.0.12-1_mips_24kc.ipk//>>url:http://downloads.openwrt.org/snapshots/packages/mips_24kc/base/iperf_2.0.12-1_mips_24kc.ipk]]
784	784	)))
785	785
786	786	(((
...	...	@@ -788,7 +788,7 @@
788	788	)))
789	789
790	790	(((
791		-(% style="background-color:#dcdcdc" %)//Downloading //[[//http:~~/~~/downloads.openwrt.org/snapshots/packages/mips_24kc/base/uclibcxx_0.2.4-3_mips_24kc.ipk//>>url:http://downloads.openwrt.org/snapshots/packages/mips_24kc/base/uclibcxx_0.2.4-3_mips_24kc.ipk]]
	847	+(% style="background-color:#dcdcdc" %)//Downloading //[[(% style="background-color: rgb(220, 220, 220); background-color: rgb(220, 220, 220)" %)//http:~~/~~/downloads.openwrt.org/snapshots/packages/mips_24kc/base/uclibcxx_0.2.4-3_mips_24kc.ipk//>>url:http://downloads.openwrt.org/snapshots/packages/mips_24kc/base/uclibcxx_0.2.4-3_mips_24kc.ipk]]
792	792	)))
793	793
794	794	(((
...	...	@@ -799,10 +799,11 @@
799	799	(% style="background-color:#dcdcdc" %)//Configuring iperf.//
800	800	)))
801	801
802		-== 8. Upgrade Linux Firmware ==
	858	+= 8. Upgrade Linux Firmware =
803	803
804		-== 9. FAQ ==
805	805
	861	+= 9. FAQ =
	862	+
806	806	== 9.1 How can I configure for a customized frequency band? ==
807	807
808	808	See below link for how to customize frequency band:
...	...	@@ -809,10 +809,12 @@
809	809
810	810	[[http:~~/~~/wiki.dragino.com/index.php?title=Customized_Frequency_Band_for_Gateway>>url:http://wiki.dragino.com/index.php?title=Customized_Frequency_Band_for_Gateway]]
811	811
	869	+
812	812	== 9.2 Can I connect DLOS8N to LORIOT? ==
813	813
814	814	Yes, the set up instruction is here: [[http:~~/~~/wiki.dragino.com/index.php?title=Notes_for_LORIOT>>url:http://wiki.dragino.com/index.php?title=Notes_for_LORIOT]]
815	815
	874	+
816	816	== 9.3 Can I make my own firmware for the gateway, where can I find the source code? ==
817	817
818	818	Yes, You can make your own firmware for the DLOS8N for branding purposes or to add customized applications.
...	...	@@ -819,33 +819,35 @@
819	819
820	820	The source code and compile instructions can be found at: [[https:~~/~~/github.com/dragino/openwrt_lede-18.06>>url:https://github.com/dragino/openwrt_lede-18.06]]
821	821
	881	+
822	822	== 9.4 Can I use 868Mhz version for 915Mhz bands? ==
823	823
824	824	It is possible but the distance will be very short, you can select US915 frequency band in 868Mhz version hardware. It will work but you will see the performance is greatly decreased because the 868Mhz version has an RF filter for band 863~~870Mhz, all other frequencies will have high attenuation.
825	825
826		-== 10. Trouble Shooting ==
827	827
	887	+= 10. Trouble Shooting =
	888	+
828	828	== 10.1 I get kernel error when install new package, how to fix? ==
829	829
830	830	In some cases, when installing a package with **//opkg//**, it will generate a kernel error such as below due to a mismatch I the kernel ID:
831	831
832		-root@dragino-16c538:~~# opkg install kmod-dragino2-si3217x_3.10.49+0.2-1_ar71xx.ipk
	893	+(% style="background-color:yellow" %)root@dragino-16c538:~~# opkg install kmod-dragino2-si3217x_3.10.49+0.2-1_ar71xx.ipk
833	833
834		-Installing kmod-dragino2-si3217x (3.10.49+0.2-1) to root…
	895	+(% style="background-color:yellow" %)Installing kmod-dragino2-si3217x (3.10.49+0.2-1) to root…
835	835
836		-Collected errors:
	897	+(% style="background-color:yellow" %)Collected errors:
837	837
838		-~* satisfy_dependencies_for: Cannot satisfy the following dependencies for kmod-dragino2-si3217x:
	899	+(% style="background-color:yellow" %)* satisfy_dependencies_for: Cannot satisfy the following dependencies for kmod-dragino2-si3217x:
839	839
840		-*      kernel (= 3.10.49-1-4917516478a753314254643facdf360a) *
	901	+(% style="background-color:yellow" %)*      kernel (= 3.10.49-1-4917516478a753314254643facdf360a) *
841	841
842		- ~* opkg_install_cmd: Cannot install package kmod-dragino2-si3217x.
	903	+ (% style="background-color:yellow" %)* opkg_install_cmd: Cannot install package kmod-dragino2-si3217x.
843	843
844		-
845	845	In this case, you can use the –force-depends option to install such package as long as the actual kernel version is the same.
846	846
847		-Opkg install kmod-dragino2-si3217x_3.10.49+0.2-1_ar71xx.ipk –force-depends
	907	+(% style="background-color:yellow" %)Opkg install kmod-dragino2-si3217x_3.10.49+0.2-1_ar71xx.ipk –force-depends
848	848
	909	+
849	849	== 10.2 How to recover the DLOS8N if the firmware crashes ==
850	850
851	851	Please follow this instruction to recover your gateway:
...	...	@@ -852,48 +852,52 @@
852	852
853	853	[[http:~~/~~/wiki.dragino.com/index.php?title=Recover_Gateway>>url:http://wiki.dragino.com/index.php?title=Recover_Gateway]]
854	854
	916	+
855	855	== 10.3 I configured DLOS8N for WiFi access and lost its IP. What to do now? ==
856	856
857		-[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image067.png]]
	919	+[[image:1652435238615-272.png||height="247" width="727"]]
858	858
859	859	The DLOS8N has a fall-back IP address on its WAN port. This IP is always enabled so you can use the fall-back IP to access DLOS8N no matter what the WiFi IP is. The fall back IP is useful for connecting and debug the unit.
860	860
861		-(Note: fallback IP can be disabled in the WAN and DHCP page)
	923	+(% style="color:red" %)Note: fallback IP can be disabled in the WAN and DHCP page.
862	862
863	863
864	864	Steps to connect via fall back IP:
865	865
866		-1. Connect PC’s Ethernet port to DLOS8N’s WAN port
867		-1. Configure PC’s Ethernet port has
868		-IP: 172.31.255.253 and
869		-Netmask: 255.255.255.252
	928	+~1. Connect PC’s Ethernet port to DLOS8N’s WAN port
870	870
	930	+2. Configure PC’s Ethernet port has
	931	+ IP: 172.31.255.253 and
	932	+ Netmask: 255.255.255.252
	933	+
871	871	As below photo:
872	872
873		-[[image:file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image068.jpg]]
	936	+[[image:1652435256286-879.png]]
874	874
875		-1. In the PC, use IP address 172.31.255.254 to access the DLOS8N via Web or Console.
	938	+3. In the PC, use IP address 172.31.255.254 to access the DLOS8N via Web or Console.
876	876
877	877	Please note the latest firmware uses port 8000 for http and 2222 for ssh access.
878	878
	942	+
879	879	= 11. Order Info =
880	880
881		-**//PART: DLOS8N-XXX-YYY//:**
	945	+(% style="color:#4f81bd" %) **//PART: DLOS8N-XXX-YYY//: **
882	882
883		-**//XXX: Frequency Band//**
	947	+(% style="color:#4f81bd" %) **//XXX: Frequency Band//**
884	884
885		-* **868**: valid frequency: 863Mhz ~~ 870Mhz. for bands EU868, RU864, IN865 or KZ865.
886		-* **915**: valid frequency: 902Mhz ~~ 928Mhz. for bands US915, AU915, AS923 or KR920
	949	+* (% style="color:#4f81bd" %)** 868**(% style="color:black" %) : valid frequency: 863Mhz ~~ 870Mhz. for bands EU868, RU864, IN865 or KZ865.
	950	+* (% style="color:#4f81bd" %)** 915**(% style="color:black" %): valid frequency: 902Mhz ~~ 928Mhz. for bands US915, AU915, AS923 or KR920
887	887
888		-**//YYY: 4G Cellular Option//**
	952	+(% style="color:#4f81bd" %) **//YYY: 4G Cellular Option//**
889	889
890		-* **E**: EMEA, Korea, Thailand, India.
891		-* **A**: North America/ Rogers/AT&T/T-Mobile.
892		-* **AU**: Latin America, New Zeland, Taiwan
893		-* **J**: Japan, DOCOMO/SoftBank/ KDDI
	954	+* (% style="color:#4f81bd" %)** E**(% style="color:black" %): EMEA, Korea, Thailand, India.
	955	+* (% style="color:#4f81bd" %)** A**(% style="color:black" %): North America/ Rogers/AT&T/T-Mobile.
	956	+* (% style="color:#4f81bd" %)** AU**(% style="color:black" %): Latin America, New Zeland, Taiwan
	957	+* (% style="color:#4f81bd" %)** J**(% style="color:black" %): Japan, DOCOMO/SoftBank/ KDDI
894	894
895	895	More info about valid bands, please see [[EC25-E product page>>url:https://www.quectel.com/product/ec25.htm]].
896	896
	961	+
897	897	= 12. Packing Info =
898	898
899	899	**Package Includes**:
...	...	@@ -908,6 +908,7 @@
908	908	* Weight: 187g
909	909	* Package Size: 14.5 x 13.5 x 6 cm
910	910	* Weight: 300g
	976	+*
911	911
912	912	= 13. Support =
913	913

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