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...	...	@@ -104,23 +104,15 @@
104	104
105	105	[[image:https://wiki.dragino.com/images/thumb/3/3a/CN470_FRE_BAND-1.png/600px-CN470_FRE_BAND-1.png||height="205" width="600"]]
106	106
107		-(((
108	108	CN470 Channels
109		-)))
110	110
111		-(((
112	112	If we look at the [[TTN network server frequency plan>>url:https://www.thethingsnetwork.org/docs/lorawan/frequency-plans.html]], we can see the US915 frequency band use the channel 8~~15.So the End Node must work at the same frequency in US915 8~~15 channels for TTN server.
113		-)))
114	114
115	115	[[image:https://wiki.dragino.com/images/thumb/9/9a/US915_FRE_BAND-2.png/600px-US915_FRE_BAND-2.png||height="288" width="600"]]
116	116
117		-(((
118	118	TTN FREQUENCY PLAN
119		-)))
120	120
121		-(((
122	122	In dragino end node, user can use AT+CHE command to set what frequencies set the end node will use. The default settings for Dragino end node are preconfigure for TTN server, so use 8~~15 channels, which is **AT+CHE=2**. (AT+CHE=1 for first 8 channels, AT+CHE=2 for second 8 channels.. etc, and AT+CHE=0 for all 72 channels. )
123		-)))
124	124
125	125
126	126	= 3. Why i see data lost/unperiocially uplink data? Even the signal strength is good =
...	...	@@ -131,40 +131,18 @@
131	131	* **Gateway** ~-~-> Use Sub-band2 (Channel 8,9,10,11,12,13,14,15) for Dragino Gateway. this is the default settings for dragino sensors.
132	132	* **LoRaWAN server** ~-~-> ChirpStack default installation and use Sub-band1, **enabled_uplink_channels=[0, 1, 2, 3, 4, 5, 6, 7]** in the file chirpstack-network-server.toml.
133	133
134		-(((
135	135	When Sensor power on, it will use sub-band2 to join the network, the frequency matches the settings in gateway so all Join Request will be passed to the server for Join. Server will ask the sensor to change to Sub-band1 in the Join Accept downlink message. Sensor will change to sub-band1 for data upload. This cause the sensor and gateway have different frequencies so user see lost of most data or even no data.
136		-)))
137	137
138		-(((
139		-
140		-)))
141		-
142		-(((
143	143	Use Subband2 as a default subband cause the sensor to have problem to work with the LoRaWAN server which use other subband, and use need to access to the end node to change the subband by console. that is not user frendily,. So since Dragino LoRaWAN Stack version DLS-005(release on end of 2020), we have changed the device to use All Subbands for OTAA join, for example, device will use the first frequency in Sub-Band1 as firt OTAA join packet, then use the first frequency in Sub-Band 2 , then first frequency in sub-band 3, and so on. LoRaWAN server will normally provide the required subband in the OTAA accept process, so end node will know what subband it use after join. If LoRaWAN server doesn't provide subband info in OTAA join, end node will use the subband which join success as the working subband. So the new method cause a longer OTAA Join time but will be compatible with all LoRaWAN server. And new method won't affect the normal uplink after Join Success.
144		-)))
145	145
146	146
147	147	= 4. Transmision on ABP Mode =
148	148
149		-(((
150	150	In ABP mode, there is a Frame Counter Checks. With this check enabled, the server will only accept the frame with a higher counter. If you reboot the device in ABP mode, the device will start from count 0, so you won't be able to see the frame update in server.
151		-)))
152	152
153		-(((
154		-
155		-)))
156		-
157		-(((
158	158	So in ABP mode, first check if the packet already arrive your gateway, if the packet arrive gatewat but didn't arrive server. Please check if this is the issue.
159		-)))
160	160
161		-(((
162		-
163		-)))
164		-
165		-(((
166	166	To solve this, disable the Frame Counter Check will solve this issue , or reset the frame counter in the device page.
167		-)))
168	168
169	169	[[~[~[image:https://wiki.dragino.com/images/thumb/1/19/ABP_Issue-1.jpg/600px-ABP_Issue-1.jpg~|~|height="340" width="600"~]~]>>url:https://wiki.dragino.com/index.php/File:ABP_Issue-1.jpg]]
170	170
...	...	@@ -177,9 +177,7 @@
177	177
178	178	LoRaWAN End node will open two receive windows to receive the downstream data. If the downstream packets arrive the end node at these receive windows, the end node will be able to get this packet and process it.
179	179
180		-(((
181	181	Depends on Class A or Class C, the receive windows will be a little difference,
182		-)))
183	183
184	184	[[image:https://wiki.dragino.com/images/thumb/1/1a/Downstream_LoRaWAN-1.png/600px-Downstream_LoRaWAN-1.png||height="590" width="600"]]
185	185
...	...	@@ -206,9 +206,7 @@
206	206	Set a downstream in TTN and see it is sent
207	207
208	208
209		-(((
210	210	This downstream info will then pass to the gateway downstream list. and include the DR which is used (SF9BW125) in EU868 is DR3
211		-)))
212	212
213	213	[[image:https://wiki.dragino.com/images/thumb/d/dc/Downstream_debug_2.png/600px-Downstream_debug_2.png||height="245" width="600"]]
214	214
...	...	@@ -217,9 +217,7 @@
217	217
218	218	**For LoRaWAN Gateway**
219	219
220		-(((
221	221	When the downstream packet appear on the traffic of Gateway page. The LoRaWAN gateway can get it from LoRaWAN server and transmit it. In Dragion Gateway, this can be checked by runinng "logread -f" in the SSH console. and see below:
222		-)))
223	223
224	224	[[image:https://wiki.dragino.com/images/thumb/2/21/Downstream_debug_3.png/600px-Downstream_debug_3.png||height="195" width="600"]]
225	225
...	...	@@ -232,63 +232,48 @@
232	232
233	233	(% class="box infomessage" %)
234	234	(((
235		- AT+RX2FQ=869525000 ~-~--> The RX2 Window frequency
	199	+AT+RX2FQ=869525000 ~-~--> The RX2 Window frequency
236	236	)))
237	237
238	238	(% class="box infomessage" %)
239	239	(((
240		- AT+RX2DR=3 ~-~--> The RX2 DataRate
	204	+AT+RX2DR=3 ~-~--> The RX2 DataRate
241	241	)))
242	242
243	243	(% class="box infomessage" %)
244	244	(((
245		- AT+RX1DL=1000 ~-~--> Receive Delay 1
	209	+AT+RX1DL=1000 ~-~--> Receive Delay 1
246	246	)))
247	247
248	248	(% class="box infomessage" %)
249	249	(((
250		- AT+RX2DL=2000 ~-~--> Receive Delay 2
	214	+AT+RX2DL=2000 ~-~--> Receive Delay 2
251	251	)))
252	252
253		-(((
254		-**when the device running, we can see below info:**
255		-)))
	217	+when the device running, we can see below info:
256	256
257		-(((
258		-
259		-)))
	219	+{{{[12502]***** UpLinkCounter= 0 *****
	220	+[12503]TX on freq 868500000 Hz at DR 0
	221	+[13992]txDone
	222	+[15022]RX on freq 868500000 Hz at DR 0 --> RX1 window open at frequency: 868500000, DR0, after 15022-13992= 1030ms of txdone
	223	+[15222]rxTimeOut --> no packet arrive in RX1 window. (duration: 200ms)
	224	+[15987]RX on freq 869525000 Hz at DR 3 --> RX2 window open at frequency: 869525000, DR3, after 15987-13992= 1995ms of txdone
	225	+[16027]rxTimeOut --> no packet arrive in RX2 window. (duration: 40 ms)
	226	+}}}
260	260
261		-(% class="box" %)
262		-(((
263		- [12502]~*~*~*~** UpLinkCounter= 0 ~*~*~*~**
264		- [12503]TX on freq 868500000 Hz at DR 0
265		- [13992]txDone
266		- [15022]RX on freq 868500000 Hz at DR 0     ~-~-> RX1 window open at frequency: 868500000, DR0, after 15022-13992= 1030ms of txdone
267		- [15222]rxTimeOut                           ~-~-> no packet arrive in RX1 window. (duration: 200ms)
268		- [15987]RX on freq 869525000 Hz at DR 3     ~-~-> RX2 window open at frequency: 869525000, DR3, after 15987-13992= 1995ms of txdone
269		- [16027]rxTimeOut                           ~-~-> no packet arrive in RX2 window. (duration: 40 ms)
270		-)))
	228	+{{{Another message:
	229	+[12502]***** UpLinkCounter= 0 *****
	230	+[12503]TX on freq 868100000 Hz at DR 0
	231	+[13992]txDone
	232	+[15022]RX on freq 868100000 Hz at DR 0
	233	+[15222]rxTimeOut
	234	+[15987]RX on freq 869525000 Hz at DR 3
	235	+[16185]rxDone --> We have got the downstream packet.
	236	+Rssi= -64
	237	+Receive data
	238	+1:0012345678
	239	+}}}
271	271
272		-(((
273		-
274		-)))
275		-
276		-(((
277		-**Another message:**
278		-)))
279		-
280		-
281		- [12502]~*~*~*~** UpLinkCounter= 0 ~*~*~*~**
282		- [12503]TX on freq 868100000 Hz at DR 0
283		- [13992]txDone
284		- [15022]RX on freq 868100000 Hz at DR 0
285		- [15222]rxTimeOut
286		- [15987]RX on freq 869525000 Hz at DR 3
287		- [16185]rxDone                              ~-~-> We have got the downstream packet.
288		- Rssi= -64
289		- Receive data
290		- 1:0012345678
291		-
292	292	== 5.3 If problem doesn’t solve ==
293	293
294	294	**If user has checked below steps and still can't solve the problem, please send us (support @ dragino.com) the sceenshots for each step to check. They include:**
...	...	@@ -300,25 +300,14 @@
300	300
301	301	= 6. Downlink Issue ~-~- Packet REJECTED, unsupported frequency =
302	302
303		-(((
304	304	In LoRaWAN, the gatewat will use the frequency specify by the server to transmit a packet as downlink purpose. Each Frequency band has different downlink frequency. and the gateway has a frequency range limited to transmit downlink.
305		-)))
306	306
307		-(((
308		-
309		-)))
310		-
311		-(((
312	312	So if the LoRaWAN server is an AS923 server which ask the gateway to transmit at 923.2Mhz frequency, but the gateway is IN868 frequency band (support 865~~867Mhz to transmit). In the gateway log it will show something like below:
313		-)))
314	314
315		-(((
316		-Sat Nov 21 08:04:17 2020 daemon.info lora_pkt_fwd[1680]: ERROR~~ Packet REJECTED, unsupported frequency - 923200000 (min:865000000,max:867000000)
317		-)))
	256	+{{{Sat Nov 21 08:04:17 2020 daemon.info lora_pkt_fwd[1680]: ERROR~ Packet REJECTED, unsupported frequency - 923200000 (min:865000000,max:867000000)
	257	+}}}
318	318
319		-(((
320	320	In this case, please double check the gateway frequency and the server frequency band.
321		-)))
322	322
323	323
324	324	= 7. Decrypt a LoRaWAN Packet =