Last modified by Saxer Lin on 2025/04/15 17:24
<
From version < 209.1 >
edited by Dilisi S
on 2024/11/22 19:34
To version < 199.1 >
edited by Dilisi S
on 2024/11/17 20:25
>
Change comment: Nov 17 edits - set 2

Summary

Details

Page properties
Content
... ... @@ -27,7 +27,7 @@
27 27  **This manual is also applicable to the LT-33222-L.**
28 28  {{/info}}
29 29  
30 -The Dragino (% style="color:blue" %)**LT-22222-L I/O Controller**(%%) is an advanced LoRaWAN end device designed to provide seamless wireless long-range connectivity with various I/O options, including analog current and voltage inputs, digital inputs and outputs, and relay outputs.
30 +The Dragino (% style="color:blue" %)**LT-22222-L I/O Controller**(%%) is an advanced LoRaWAN device designed to provide seamless wireless long-range connectivity with various I/O options, including analog current and voltage inputs, digital inputs and outputs, and relay outputs.
31 31  
32 32  The LT-22222-L I/O Controller simplifies and enhances I/O monitoring and controlling. It is ideal for professional applications in wireless sensor networks, including irrigation systems, smart metering, smart cities, building automation, and more. These controllers are designed for easy, cost-effective deployment using LoRa wireless technology.
33 33  )))
... ... @@ -40,20 +40,21 @@
40 40  (((
41 41  You can connect the LT-22222-L I/O Controller to a LoRaWAN network service provider in several ways:
42 42  
43 -* If there is public LoRaWAN network coverage in the area where you plan to install the device (e.g., The Things Stack Community Network), you can select a network and register the LT-22222-L I/O controller with it.
43 +* If there is public LoRaWAN network coverage in the area where you plan to install the device (e.g., The Things Network), you can select a network and register the LT-22222-L I/O controller with it.
44 44  * If there is no public LoRaWAN coverage in your area, you can set up a LoRaWAN gateway, or multiple gateways, and connect them to a LoRaWAN network server to create adequate coverage. Then, register the LT-22222-L I/O controller with this network.
45 45  * Setup your own private LoRaWAN network.
46 +
47 +{{info}}
48 + You can use a LoRaWAN gateway, such as the [[Dragino LG308>>https://www.dragino.com/products/lora-lorawan-gateway/item/140-lg308.html]], to expand or create LoRaWAN coverage in your area.
49 +{{/info}}
46 46  )))
47 47  
48 48  (((
49 -
53 +[[image:1653295757274-912.png]]
50 50  
51 -The network diagram below illustrates how the LT-22222-L communicates with a typical LoRaWAN network.
55 +
52 52  )))
53 53  
54 -(% class="wikigeneratedid" %)
55 -[[image:lorawan-nw.jpg||height="354" width="900"]]
56 -
57 57  == 1.2 Specifications ==
58 58  
59 59  (% style="color:#037691" %)**Hardware System:**
... ... @@ -114,21 +114,6 @@
114 114  * Smart cities
115 115  * Smart factory
116 116  
117 -== 1.5 Hardware Variants ==
118 -
119 -(% style="width:524px" %)
120 -|(% style="width:94px" %)**Model**|(% style="width:98px" %)**Photo**|(% style="width:329px" %)**Description**
121 -|(% style="width:94px" %)**LT33222-L**|(% style="width:98px" %)(((
122 -
123 -)))|(% style="width:329px" %)(((
124 -* 2 x Digital Input (Bi-direction)
125 -* 2 x Digital Output
126 -* 2 x Relay Output (5A@250VAC / 30VDC)
127 -* 2 x 0~~20mA Analog Input (res:0.01mA)
128 -* 2 x 0~~30V Analog Input (res:0.01v)
129 -* 1 x Counting Port
130 -)))
131 -
132 132  == 2. Assembling the device ==
133 133  
134 134  == 2.1 Connecting the antenna ==
... ... @@ -136,17 +136,17 @@
136 136  Connect the LoRa antenna to the antenna connector, **ANT**,** **located on the top right side of the device, next to the upper screw terminal block. Secure the antenna by tightening it clockwise.
137 137  
138 138  {{warning}}
139 -**Warning! Do not power on the device without connecting the antenna.**
125 +Warning! Do not power on the device without connecting the antenna.
140 140  {{/warning}}
141 141  
142 142  == 2.2 Terminals ==
143 143  
144 -The  LT-22222-L has two screw terminal blocks. The upper screw treminal block has 6 screw terminals and the lower screw terminal block has 10 screw terminals.
130 +The  LT-22222-L has two screw terminal blocks. The upper screw treminal block has 6 terminals and the lower screw terminal block has 10 terminals.
145 145  
146 -**Upper screw terminal block (from left to right):**
132 +Upper screw terminal block (from left to right):
147 147  
148 148  (% style="width:634px" %)
149 -|=(% style="width: 295px;" %)Screw Terminal|=(% style="width: 338px;" %)Function
135 +|=(% style="width: 295px;" %)Terminal|=(% style="width: 338px;" %)Function
150 150  |(% style="width:295px" %)GND|(% style="width:338px" %)Ground
151 151  |(% style="width:295px" %)VIN|(% style="width:338px" %)Input Voltage
152 152  |(% style="width:295px" %)AVI2|(% style="width:338px" %)Analog Voltage Input Terminal 2
... ... @@ -154,10 +154,10 @@
154 154  |(% style="width:295px" %)ACI2|(% style="width:338px" %)Analog Current Input Terminal 2
155 155  |(% style="width:295px" %)ACI1|(% style="width:338px" %)Analog Current Input Terminal 1
156 156  
157 -**Lower screw terminal block (from left to right):**
143 +Lower screw terminal block (from left to right):
158 158  
159 159  (% style="width:633px" %)
160 -|=(% style="width: 296px;" %)Screw Terminal|=(% style="width: 334px;" %)Function
146 +|=(% style="width: 296px;" %)Terminal|=(% style="width: 334px;" %)Function
161 161  |(% style="width:296px" %)RO1-2|(% style="width:334px" %)Relay Output 1
162 162  |(% style="width:296px" %)RO1-1|(% style="width:334px" %)Relay Output 1
163 163  |(% style="width:296px" %)RO2-2|(% style="width:334px" %)Relay Output 2
... ... @@ -169,12 +169,14 @@
169 169  |(% style="width:296px" %)DO2|(% style="width:334px" %)Digital Output 2
170 170  |(% style="width:296px" %)DO1|(% style="width:334px" %)Digital Output 1
171 171  
172 -== 2.3 Connecting LT-22222-L to a Power Source ==
158 +== 2.3 Powering the device ==
173 173  
174 -The LT-22222-L I/O Controller can be powered by a **7–24V DC** power source. Connect your power supply’s **positive wire** to the **VIN** and the **negative wire** to the **GND** screw terminals. The power indicator **(PWR) LED** will turn on when the device is properly powered.
160 +The LT-22222-L I/O Controller can be powered by a **7–24V DC** power source. Connect your power supply’s positive wire to the VIN and the negative wire to the GND screw terminals. The power indicator **(PWR) LED** will turn on when the device is properly powered.
175 175  
162 +Once powered, the **TX LED** will **fast-blink 5 times** which means the LT-22222-L will enter the **work mode** and start to **join** The Things Stack. The **TX LED** will be on for **5 seconds** after joining the network. When there is a **downlink** message from the server, the **RX LED** will be on for **1 second**. When the device is sending an uplink message to the server, the **TX LED** will be on for **1 second**. See also LED status.
163 +
176 176  {{warning}}
177 -**We recommend that you power on the LT-22222-L after configuring its registration information with a LoRaWAN network server. Otherwise, the device will continuously send join-request messages to attempt to join a LoRaWAN network but will fail.**
165 +We recommend that you power on the LT-22222-L after configuring its registration information with a LoRaWAN network server. Otherwise, the device will continuously send join-request messages to attempt to join a LoRaWAN network but will fail.
178 178  {{/warning}}
179 179  
180 180  
... ... @@ -181,51 +181,36 @@
181 181  [[image:1653297104069-180.png]]
182 182  
183 183  
184 -= 3. Registering LT-22222-L with a LoRaWAN Network Server =
172 += 3. Registering with a LoRaWAN Network Server =
185 185  
186 -The LT-22222-L supports both OTAA (Over-the-Air Activation) and ABP (Activation By Personalization) methods to activate with a LoRaWAN Network Server. However, OTAA is the most secure method for activating a device with a LoRaWAN Network Server. OTAA regenerates session keys upon initial registration and regenerates new session keys after any subsequent reboots. By default, the LT-22222-L is configured to operate in LoRaWAN Class C mode.
174 +By default, the LT-22222-L is configured to operate in LoRaWAN Class C mode. It supports OTAA (Over-the-Air Activation), the most secure method for activating a device with a LoRaWAN network server. The LT-22222-L comes with device registration information that allows you to register it with a LoRaWAN network, enabling the device to perform OTAA activation with the network server upon initial power-up and after any subsequent reboots.
187 187  
176 +After powering on, the **TX LED** will **fast-blink 5 times** which means the LT-22222-L will enter the **work mode** and start to **join** the LoRaWAN network. The **TX LED** will be on for **5 seconds** after joining the network. When there is a **downlink** message from the server, the **RX LED** will be on for **1 second**. When the device is sending an uplink message to the server, the **TX LED** will be on for **1 second**. See also LED status.
188 188  
178 +In case you can't set the root key and other identifiers in the network server and must use them from the server, you can use [[AT Commands>>||anchor="H4.UseATCommand"]] to configure them on the device.
179 +
180 +The network diagram below shows how the LT-22222-L is connected to a typical LoRaWAN network.
181 +
182 +[[image:image-20220523172350-1.png||height="266" width="864"]]
183 +
189 189  === 3.2.1 Prerequisites ===
190 190  
191 -The LT-22222-L comes with device registration information such as DevEUI, AppEUI, and AppKey that allows you to register it with a LoRaWAN network. These registration information can be found on a sticker that can be found inside the package. Please keep the **registration information** sticker in a safe place for future reference.
186 +Make sure you have the device registration information such as DevEUI, AppEUI, and AppKey with you. The registration information can be found on a sticker that can be found inside the package. Please keep the **registration information** sticker in a safe place for future reference.
192 192  
193 193  [[image:image-20230425173427-2.png||height="246" width="530"]]
194 194  
195 -{{info}}
196 -In case you can't set the root key and other identifiers in the network server and must use them from the server, you can use [[AT Commands>>||anchor="H4.UseATCommand"]] to configure them on the device.
197 -{{/info}}
198 -
199 199  The following subsections explain how to register the LT-22222-L with different LoRaWAN network server providers.
200 200  
201 -=== 3.2.2 The Things Stack ===
192 +=== 3.2.2 The Things Stack Sandbox (TTSS) ===
202 202  
203 -This section guides you through how to register your LT-22222-L with The Things Stack Sandbox.
204 -
205 -{{info}}
206 206  The Things Stack Sandbox was formally called The Things Stack Community Edition.
207 -{{/info}}
208 208  
209 -
210 -The network diagram below illustrates the connection between the LT-22222-L and The Things Stack, as well as how the data can be integrated with the ThingsEye IoT platform.
211 -
212 -
213 -[[image:dragino-lorawan-nw-lt-22222-n.jpg]]
214 -
215 -{{info}}
216 - You can use a LoRaWAN gateway, such as the [[Dragino LPS8N>>https://www.dragino.com/products/lora-lorawan-gateway/item/200-lps8n.html]], to expand or create LoRaWAN coverage in your area.
217 -{{/info}}
218 -
219 -
220 -==== 3.2.2.1 Setting up ====
221 -
222 -* Sign up for a free account with [[The Things Stack Sandbox>>https://eu1.cloud.thethings.network]] if you do not have one yet.
223 -* Log in to your The Things Stack Sandbox account.
224 -* Create an **application** with The Things Stack if you do not have one yet (E.g., dragino-docs).
225 -* Go to your application's page and click on the **End devices** in the left menu.
196 +* Log in to your [[The Things Stack Sandbox>>https://eu1.cloud.thethings.network]] account.
197 +* Create an application with The Things Stack if you do not have one yet.
198 +* Go to your application page and click on the **End devices** in the left menu.
226 226  * On the End devices page, click on **+ Register end device**. Two registration options are available:
227 227  
228 -==== 3.2.2.2 Using the LoRaWAN Device Repository ====
201 +==== 3.2.2.1 Using the LoRaWAN Device Repository ====
229 229  
230 230  * On the **Register end device** page:
231 231  ** Select the option **Select the end device in the LoRaWAN Device Repository **under **Input method**.
... ... @@ -251,7 +251,7 @@
251 251  
252 252  ==== ====
253 253  
254 -==== 3.2.2.3 Adding device manually ====
227 +==== 3.2.2.2 Adding device manually ====
255 255  
256 256  * On the **Register end device** page:
257 257  ** Select the option **Enter end device specifies manually** under **Input method**.
... ... @@ -266,7 +266,7 @@
266 266  
267 267  
268 268  * Register end device page continued...
269 -** Enter the **AppEUI** in the **JoinEUI** field and click the **Confirm** button. If The Things Stack accepts the JoinEUI you provided, it will display the message '//**This end device can be registered on the network**//'
242 +** Enter the **AppEUI** in the **JoinEUI** field and click the **Confirm** button. If The Things Stack accepts the JoinEUI you provided, it will display the message 'This end device can be registered on the network'
270 270  ** In the **DevEUI** field, enter the **DevEUI**.
271 271  ** In the **AppKey** field, enter the **AppKey**.
272 272  ** In the **End device ID** field, enter a unique name for your LT-22222-N within this application.
... ... @@ -282,27 +282,24 @@
282 282  [[image:lt-22222-device-overview.png||height="625" width="1000"]]
283 283  
284 284  
285 -==== 3.2.2.4 Joining ====
258 +==== 3.2.2.3 Joining ====
286 286  
287 -On the Device's page, click on **Live data** tab. The Live data panel for your device will display.
260 +On the Device overview page, click on **Live data** tab. The Live data panel for your device will display.
288 288  
289 -Now power on your LT-22222-L. The **TX LED** will **fast-blink 5 times** which means the LT-22222-L will enter the **work mode** and start to **join** The Things Stack network server. The **TX LED** will be on for **5 seconds** after joining the network. In the **Live data** panel, you can see the **join-request** and **join-accept** messages exchanged between the device and the network server.
262 +Now power on your LT-22222-L. It will begin joining The Things Stack. In the **Live data** panel, you can see the **join-request** and **join-accept** messages exchanged between the device and the network server. Once successfully joined, the device will send its first **uplink data message** to the application it belongs to (in this example, **dragino-docs**).
290 290  
291 291  
292 292  [[image:lt-22222-join-network.png||height="625" width="1000"]]
293 293  
294 294  
295 -==== 3.2.2.5 Uplinks ====
268 +By default, you will receive an uplink data message from the device every 10 minutes.
296 296  
297 -
298 -After successfully joining, the device will send its first **uplink data message** to the application it belongs to (in this example, **dragino-docs**). When the LT-22222-L sends an uplink message to the server, the **TX LED** turns on for **1 second**. By default, you will receive an uplink data message from the device every 10 minutes.
299 -
300 300  Click on one of a **Forward uplink data messages **to see its payload content. The payload content is encapsulated within the decode_payload {} JSON object.
301 301  
302 302  [[image:lt-22222-ul-payload-decoded.png]]
303 303  
304 304  
305 -If you can't see the decoded payload, it is because you haven't added the uplink formatter code. To add the uplink formatter code, select **Applications > your application > End devices** > **your end device** > **Payload formatters** > **Uplink**. Then  select **Use Device repository formatters** for the **Formatter type** dropdown. Click the **Save changes** button to apply the changes.
275 +If you can't see the decoded payload, it is because you haven't added the uplink formatter code. To add the uplink formatter code, select **End devices** > **LT-22222-L** > **Payload formatters** > **Uplink**. Then  select **Use Device repository formatters** for the **Formatter type** dropdown. Click the **Save changes** button to apply the changes.
306 306  
307 307  {{info}}
308 308  The Things Stack provides two levels of payload formatters: application level and device level. The device-level payload formatters **override **the application-level payload formatters.
... ... @@ -311,11 +311,6 @@
311 311  [[image:lt-22222-ul-payload-fmt.png||height="686" width="1000"]]
312 312  
313 313  
314 -==== 3.2.2.6 Downlinks ====
315 -
316 -When the LT-22222-L receives a downlink message from the server, the **RX LED** turns on for **1 second**.
317 -
318 -
319 319  == 3.3 Working Modes and Uplink Payload formats ==
320 320  
321 321  
... ... @@ -591,13 +591,13 @@
591 591  )))
592 592  
593 593  (((
594 -AT Commands for counting are similar to the [[MOD2 Counting Command>>||anchor="H3.3.2AT2BMOD3D22C28DoubleDICounting29"]]s.
559 +Other AT Commands for counting are similar to the [[MOD2 Counting Command>>||anchor="H3.3.2AT2BMOD3D22C28DoubleDICounting29"]]s.
595 595  )))
596 596  
597 597  (((
598 598  **In addition to that, below are the commands for AVI1 Counting:**
599 599  
600 -(% style="color:blue" %)**AT+SETCNT=3,60 **(%%)**(Sets AVI1 Count to 60)**
565 +(% style="color:blue" %)**AT+SETCNT=3,60 **(%%)**(Sets AVI Count to 60)**
601 601  
602 602  (% style="color:blue" %)**AT+VOLMAX=20000 **(%%)**(If AVI1 voltage higher than VOLMAX (20000mV =20v), counter increase 1)**
603 603  
... ... @@ -1012,7 +1012,7 @@
1012 1012  (% border="2" style="width:500px" %)
1013 1013  |(% style="width:97px" %)**Payload**|(% style="width:401px" %)<prefix><enable/disable trigger_mode>
1014 1014  |(% style="width:97px" %)**Parameters**|(% style="width:401px" %)(((
1015 -**prefix** : 0x0A 06 (two bytes in hexadecimal)
980 +**prefix** : 0x0A 06
1016 1016  
1017 1017  **working mode** : enable (1) or disable (0), represented by 1 byte in hexadecimal.
1018 1018  )))
... ... @@ -1034,7 +1034,7 @@
1034 1034  
1035 1035  (% border="2" style="width:500px" %)
1036 1036  |(% style="width:95px" %)**Payload**|(% style="width:403px" %)<prefix>
1037 -|(% style="width:95px" %)**Parameters**|(% style="width:403px" %)**prefix **: AB 06 (two bytes in hexadecimal)
1002 +|(% style="width:95px" %)**Parameters**|(% style="width:403px" %)**prefix **: AB 06
1038 1038  |(% style="width:95px" %)**Example**|(% style="width:403px" %)(((
1039 1039  AB 06
1040 1040  
... ... @@ -1075,7 +1075,7 @@
1075 1075  (% border="2" style="width:500px" %)
1076 1076  |(% style="width:101px" %)**Payload**|(% style="width:397px" %)<prefix><DI1_trigger><DI2_trigger>
1077 1077  |(% style="width:101px" %)**Parameters**|(% style="width:397px" %)(((
1078 -**prefix :** AA 02 (two bytes in hexadecimal)
1043 +**prefix :** AA 02
1079 1079  
1080 1080  **DI1_trigger:**
1081 1081  
... ... @@ -1099,7 +1099,20 @@
1099 1099  
1100 1100  Sets DI1 or DI3 (for LT-33222-L) as a trigger.
1101 1101  
1067 +* (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+TRIG1=a,b**
1102 1102  
1069 +(% style="color:red" %)**a :** (%%)Interrupt mode. 0: falling edge; 1: rising edge, 2: falling and raising edge(for MOD=1).
1070 +
1071 +(% style="color:red" %)**b :** (%%)delay timing.
1072 +
1073 +**Example:** AT+TRIG1=1,100(set DI1 port to trigger on high level, valid signal is 100ms )
1074 +
1075 +
1076 +* (% style="color:#037691" %)**Downlink Payload (prefix 0x09 01 ):**
1077 +
1078 +(% style="color:blue" %)**0x09 01 aa bb cc    ** (%%) ~/~/ same as AT+TRIG1=aa,0x(bb cc)
1079 +
1080 +
1103 1103  (% style="color:#037691" %)**AT Command**
1104 1104  
1105 1105  (% border="2" style="width:500px" %)
... ... @@ -1122,7 +1122,7 @@
1122 1122  (% border="2" style="width:500px" %)
1123 1123  |(% style="width:101px" %)**Payload**|(% style="width:397px" %)<prefix><interrupt_mode><minimum_signal_duration>
1124 1124  |(% style="width:101px" %)**Parameters**|(% style="width:397px" %)(((
1125 -**prefix** : 09 01 (hexadecimal)
1103 +**prefix** : 09 01
1126 1126  
1127 1127  **interrupt_mode** : 0: falling edge; 1: rising edge, 2: falling and raising edge (for MOD=1), represented by 1 byte in hexadecimal.
1128 1128  
... ... @@ -1138,7 +1138,20 @@
1138 1138  
1139 1139  Sets DI2 as a trigger.
1140 1140  
1119 +* (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+TRIG2=a,b**
1141 1141  
1121 +(% style="color:red" %)**a :** (%%)Interrupt mode. 0: falling edge; 1: rising edge, 2: falling and raising edge (for MOD=1).
1122 +
1123 +(% style="color:red" %)**b :** (%%)delay timing.
1124 +
1125 +**Example:** AT+TRIG2=0,100 (Set the DI1 port to trigger on a falling edge; the valid signal duration is 100 ms)
1126 +
1127 +
1128 +* (% style="color:#037691" %)**Downlink Payload (prefix 0x09 02 ):**
1129 +
1130 +(% style="color:blue" %)**0x09 02 aa bb cc   ** (%%)~/~/ same as AT+TRIG2=aa,0x(bb cc)
1131 +
1132 +
1142 1142  (% style="color:#037691" %)**AT Command**
1143 1143  
1144 1144  (% border="2" style="width:500px" %)
... ... @@ -1160,7 +1160,7 @@
1160 1160  (% border="2" style="width:500px" %)
1161 1161  |(% style="width:96px" %)**Payload**|(% style="width:402px" %)<prefix><interrupt_mode><minimum_signal_duration>
1162 1162  |(% style="width:96px" %)**Parameters**|(% style="width:402px" %)(((
1163 -**prefix** : 09 02 (hexadecimal)
1154 +**prefix** : 09 02
1164 1164  
1165 1165  **interrupt_mode **: 0: falling edge; 1: rising edge, 2: falling and raising edge (for MOD=1), represented by 1 byte in hexadecimal.
1166 1166  
... ... @@ -1168,12 +1168,16 @@
1168 1168  )))
1169 1169  |(% style="width:96px" %)**Example**|(% style="width:402px" %)09 02 **00 00 64**
1170 1170  
1171 -==== ====
1172 -
1173 1173  ==== 3.4.2.9 Trigger – Set AC (current) as a trigger ====
1174 1174  
1175 1175  Sets the current trigger based on the AC port. See also [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1176 1176  
1166 +* (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+ACLIM**
1167 +
1168 +* (% style="color:#037691" %)**Downlink Payload (prefix 0xAA 01 )**
1169 +
1170 +(% style="color:blue" %)**0x AA 01 aa bb cc dd ee ff gg hh        ** (%%) ~/~/ same as AT+ACLIM See [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1171 +
1177 1177  (% style="color:#037691" %)**AT Command**
1178 1178  
1179 1179  (% border="2" style="width:500px" %)
... ... @@ -1182,13 +1182,13 @@
1182 1182  )))
1183 1183  |(% style="width:104px" %)**Response**|(% style="width:394px" %)
1184 1184  |(% style="width:104px" %)**Parameters**|(% style="width:394px" %)(((
1185 -**AC1_LIMIT_LOW** : lower limit of the current to be checked
1180 +**AC1_LIMIT_LOW** : lower limit of the current to be checked / threshold
1186 1186  
1187 -**AC1_LIMIT_HIGH **: higher limit of the current to be checked
1182 +**AC1_LIMIT_HIGH **: higher limit of the current to be checked / threshold
1188 1188  
1189 -**AC2_LIMIT_HIGH **: lower limit of the current to be checked
1184 +**AC2_LIMIT_HIGH **: lower limit of the current to be checked / threshold
1190 1190  
1191 -**AC2_LIMIT_LOW** : higher limit of the current to be checked
1186 +**AC2_LIMIT_LOW** : higher limit of the current to be checked / threshold
1192 1192  )))
1193 1193  |(% style="width:104px" %)**Example**|(% style="width:394px" %)(((
1194 1194  AT+ACLIM=10000,15000,0,0
... ... @@ -1195,7 +1195,6 @@
1195 1195  
1196 1196  Triggers an uplink if AC1 current is lower than 10mA or higher than 15mA
1197 1197  )))
1198 -|(% style="width:104px" %)Note|(% style="width:394px" %)See also, [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1199 1199  
1200 1200  (% style="color:#037691" %)**Downlink Payload**
1201 1201  
... ... @@ -1202,15 +1202,15 @@
1202 1202  (% border="2" style="width:500px" %)
1203 1203  |(% style="width:104px" %)**Payload**|(% style="width:394px" %)<prefix><AC1_LIMIT_LOW>,< AC1_LIMIT_HIGH>,<AC2_LIMIT_LOW>,< AC2_LIMIT_HIGH>
1204 1204  |(% style="width:104px" %)**Parameters**|(% style="width:394px" %)(((
1205 -**prefix **: AA 01 (hexadecimal)
1199 +**prefix **: AA 01 - two bytes in hexadecimal
1206 1206  
1207 -**AC1_LIMIT_LOW** : lower limit of the current to be checked, two bytes in hexadecimal
1201 +**AC1_LIMIT_LOW** : lower limit of the current to be checked / threshold, two bytes in hexadecimal
1208 1208  
1209 -**AC1_LIMIT_HIGH **: higher limit of the current to be checked, two bytes in hexadecimal
1203 +**AC1_LIMIT_HIGH **: higher limit of the current to be checked / threshold, two bytes in hexadecimal
1210 1210  
1211 -**AC2_LIMIT_HIGH **: lower limit of the current to be checked, two bytes in hexadecimal
1205 +**AC2_LIMIT_HIGH **: lower limit of the current to be checked / threshold, two bytes in hexadecimal
1212 1212  
1213 -**AC2_LIMIT_LOW** : higher limit of the current to be checked, two bytes in hexadecimal
1207 +**AC2_LIMIT_LOW** : higher limit of the current to be checked / threshold, two bytes in hexadecimal
1214 1214  )))
1215 1215  |(% style="width:104px" %)**Example**|(% style="width:394px" %)(((
1216 1216  AA 01 **27** **10 3A** **98** 00 00 00 00
... ... @@ -1217,121 +1217,69 @@
1217 1217  
1218 1218  Triggers an uplink if AC1 current is lower than 10mA or higher than 15mA. Set all values to zero for AC2 limits because we are only checking AC1 limits.
1219 1219  )))
1220 -|(% style="width:104px" %)Note|(% style="width:394px" %)See also, [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1221 1221  
1222 1222  ==== 3.4.2.10 Trigger – Set AV (voltage) as trigger ====
1223 1223  
1224 1224  Sets the current trigger based on the AV port. See also [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1225 1225  
1226 -(% style="color:#037691" %)**AT Command**
1219 +* (% style="color:#037691" %)**AT Command**(%%): (% style="color:blue" %)**AT+AVLIM    **(%%)** See [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]**
1227 1227  
1228 -(% border="2" style="width:500px" %)
1229 -|(% style="width:104px" %)**Command**|(% style="width:387px" %)AT+AVLIM= AV1_LIMIT_LOW>,< AV1_LIMIT_HIGH>,<AV2_LIMIT_LOW>,< AV2_LIMIT_HIGH>
1230 -|(% style="width:104px" %)**Response**|(% style="width:387px" %)
1231 -|(% style="width:104px" %)**Parameters**|(% style="width:387px" %)(((
1232 -**AC1_LIMIT_LOW** : lower limit of the current to be checked
1221 +* (% style="color:#037691" %)**Downlink Payload (prefix 0xAA 00 )**
1233 1233  
1234 -**AC1_LIMIT_HIGH **: higher limit of the current to be checked
1223 +(% style="color:blue" %)**0x AA 00 aa bb cc dd ee ff gg hh    ** (%%) ~/~/ same as AT+AVLIM See [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1235 1235  
1236 -**AC2_LIMIT_HIGH **: lower limit of the current to be checked
1237 1237  
1238 -**AC2_LIMIT_LOW** : higher limit of the current to be checked
1239 -)))
1240 -|(% style="width:104px" %)**Example**|(% style="width:387px" %)(((
1241 -AT+AVLIM=3000,6000,0,2000
1242 -
1243 -Triggers an uplink if AVI1 voltage is lower than 3V or higher than 6V, or if AV2 voltage is higher than 2V
1244 -)))
1245 -|(% style="width:104px" %)**Note**|(% style="width:387px" %)See also, [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1246 -
1247 -(% style="color:#037691" %)**Downlink Payload**
1248 -
1249 1249  (% border="2" style="width:500px" %)
1250 -|(% style="width:104px" %)**Payload**|(% style="width:394px" %)<prefix><AV1_LIMIT_LOW>,< AV1_LIMIT_HIGH>,<AV2_LIMIT_LOW>,< AV2_LIMIT_HIGH>
1251 -|(% style="width:104px" %)**Parameters**|(% style="width:394px" %)(((
1252 -**prefix **: AA 00 (hexadecimal)
1227 +|(% style="width:104px" %)Command|(% style="width:387px" %)AT+AVLIM= AV1_LIMIT_LOW>,< AV1_LIMIT_HIGH>,<AV2_LIMIT_LOW>,< AV2_LIMIT_HIGH>
1228 +|(% style="width:104px" %)Response|(% style="width:387px" %)
1229 +|(% style="width:104px" %)Parameters|(% style="width:387px" %)(((
1230 +**AC1_LIMIT_LOW** : lower limit of the current to be checked / threshold, two bytes in hexadecimal
1253 1253  
1254 -**AV1_LIMIT_LOW** : lower limit of the voltage to be checked, two bytes in hexadecimal
1232 +**AC1_LIMIT_HIGH **: higher limit of the current to be checked / threshold, two bytes in hexadecimal
1255 1255  
1256 -**AV1_LIMIT_HIGH **: higher limit of the voltage to be checked, two bytes in hexadecimal
1234 +**AC2_LIMIT_HIGH **: lower limit of the current to be checked / threshold, two bytes in hexadecimal
1257 1257  
1258 -**AV2_LIMIT_HIGH **: lower limit of the voltage to be checked, two bytes in hexadecimal
1259 -
1260 -**AV2_LIMIT_LOW** : higher limit of the voltage to be checked, two bytes in hexadecimal
1236 +**AC2_LIMIT_LOW** : higher limit of the current to be checked / threshold, two bytes in hexadecimal
1261 1261  )))
1262 -|(% style="width:104px" %)**Example**|(% style="width:394px" %)(((
1263 -AA 00 **0B B8 17 70 00 00 07 D0**
1238 +|(% style="width:104px" %)Example|(% style="width:387px" %)
1264 1264  
1265 -Triggers an uplink if AVI1 voltage is lower than 3V or higher than 6V, or if AV2 voltage is higher than 2V.
1266 -)))
1267 -|(% style="width:104px" %)**Note**|(% style="width:394px" %)See also, [[trigger mode>>||anchor="H3.3.6AT2BADDMOD3D6.28TriggerMode2COptional29"]]
1268 1268  
1241 +
1269 1269  ==== 3.4.2.11 Trigger – Set minimum interval ====
1270 1270  
1271 -Sets the AV and AC trigger minimum interval. The device won't respond to a second trigger within this set time after the first trigger.
1244 +Sets AV and AC trigger minimum interval. Device won't response to the second trigger within this set time after the first trigger.
1272 1272  
1273 -(% style="color:#037691" %)**AT Command**
1246 +* (% style="color:#037691" %)**AT Command**(%%): (% style="color:blue" %)**AT+ATDC=5        ** ~/~/ (%%)Device won't response the second trigger within 5 minute after the first trigger.
1274 1274  
1275 -(% border="2" style="width:500px" %)
1276 -|(% style="width:113px" %)**Command**|(% style="width:385px" %)AT+ATDC=<time>
1277 -|(% style="width:113px" %)**Response**|(% style="width:385px" %)
1278 -|(% style="width:113px" %)**Parameters**|(% style="width:385px" %)(((
1279 -**time** : in minutes
1280 -)))
1281 -|(% style="width:113px" %)**Example**|(% style="width:385px" %)(((
1282 -AT+ATDC=5
1248 +* (% style="color:#037691" %)**Downlink Payload (prefix 0xAC )**
1283 1283  
1284 -The device won't respond to the second trigger within 5 minutes after the first trigger.
1285 -)))
1286 -|(% style="width:113px" %)Note|(% style="width:385px" %)(% style="color:red" %)**The time must be greater than 5 minutes.**
1250 +(% style="color:blue" %)**0x AC aa bb   **(%%) ~/~/ same as AT+ATDC=0x(aa bb)   . Unit (min)
1287 1287  
1288 -(% style="color:#037691" %)**Downlink Payload**
1289 -
1290 -(% border="2" style="width:500px" %)
1291 -|(% style="width:112px" %)**Payload**|(% style="width:386px" %)<prefix><time>
1292 -|(% style="width:112px" %)**Parameters**|(% style="width:386px" %)(((
1293 -**prefix** : AC (hexadecimal)
1294 -
1295 -**time **: in minutes (two bytes in hexadecimal)
1252 +(((
1253 +(% style="color:red" %)**Note: ATDC setting must be more than 5min**
1296 1296  )))
1297 -|(% style="width:112px" %)**Example**|(% style="width:386px" %)(((
1298 -AC **00 05**
1299 1299  
1300 -The device won't respond to the second trigger within 5 minutes after the first trigger.
1301 -)))
1302 -|(% style="width:112px" %)Note|(% style="width:386px" %)(% style="color:red" %)**The time must be greater than 5 minutes.**
1303 1303  
1257 +
1304 1304  ==== 3.4.2.12 DO ~-~- Control Digital Output DO1/DO2/DO3 ====
1305 1305  
1306 1306  Controls the digital outputs DO1, DO2, and DO3
1307 1307  
1308 -(% style="color:#037691" %)**AT Command**
1262 +* (% style="color:#037691" %)**AT Command**
1309 1309  
1310 -There is no AT Command to control the Digital Output.
1264 +There is no AT Command to control Digital Output
1311 1311  
1312 1312  
1313 -(% style="color:#037691" %)**Downlink Payload**
1267 +* (% style="color:#037691" %)**Downlink Payload (prefix 0x02)**
1314 1314  
1315 -(% border="2" style="width:500px" %)
1316 -|(% style="width:115px" %)**Payload**|(% style="width:383px" %)<prefix><DO1><DO2><DO3>
1317 -|(% style="width:115px" %)**Parameters**|(% style="width:383px" %)(((
1318 -**prefix** : 02 (hexadecimal)
1269 +(% style="color:blue" %)**0x02 aa bb cc     ** (%%)~/~/ Set DO1/DO2/DO3 output
1319 1319  
1320 -**DOI** : 01: Low,  00: High, 11: No action (1 byte in hex)
1321 -
1322 -**DO2** : 01: Low,  00: High, 11: No action (1 byte in hex)
1323 -
1324 -**DO3 **: 01: Low,  00: High, 11: No action (1 byte in hex)
1271 +(((
1272 +If payload = 0x02010001, while there is load between V+ and DOx, it means set DO1 to low, DO2 to high and DO3 to low.
1325 1325  )))
1326 -|(% style="width:115px" %)**Examples**|(% style="width:383px" %)(((
1327 -02 **01 00 01**
1328 1328  
1329 -If there is a load between V+ and DOx, it means DO1 is set to low, DO2 is set to high, and DO3 is set to low.
1330 -
1331 -**More examples:**
1332 -
1333 1333  (((
1334 -01: Low,  00: High,  11: No action
1276 +01: Low,  00: High ,  11: No action
1335 1335  
1336 1336  (% border="1" cellspacing="4" style="background-color:#f2f2f2; width:510px" %)
1337 1337  |(% style="background-color:#4f81bd; color:white" %)**Downlink Code**|(% style="background-color:#4f81bd; color:white" %)**DO1**|(% style="background-color:#4f81bd; color:white" %)**DO2**|(% style="background-color:#4f81bd; color:white" %)**DO3**
... ... @@ -1341,18 +1341,15 @@
1341 1341  )))
1342 1342  
1343 1343  (((
1344 -(((
1345 -(% style="color:red" %)**Note: For the LT-22222-L, there is no DO3; the last byte can have any value.**
1286 +(% style="color:red" %)**Note: For LT-22222-L, there is no DO3, the last byte can use any value.**
1346 1346  )))
1347 1347  
1348 1348  (((
1349 -(% style="color:red" %)**The device will upload a packet if downlink code executes successfully.**
1290 +(% style="color:red" %)**Device will upload a packet if downlink code executes successfully.**
1350 1350  )))
1351 -)))
1352 -)))
1353 1353  
1354 -==== ====
1355 1355  
1294 +
1356 1356  ==== 3.4.2.13 DO ~-~- Control Digital Output DO1/DO2/DO3 with time control ====
1357 1357  
1358 1358  
... ... @@ -1377,7 +1377,7 @@
1377 1377  00: DO pins will change to an inverter state after timeout 
1378 1378  
1379 1379  
1380 -(% style="color:#4f81bd" %)**Third Byte**(%%): Control Method and Port status:
1319 +(% style="color:#4f81bd" %)**Third Byte**(%%): Control Method and Ports status:
1381 1381  
1382 1382  (% border="1" cellspacing="4" style="background-color:#f2f2f2; width:300px" %)
1383 1383  |(% style="background-color:#4f81bd; color:white" %)**Second Byte**|(% style="background-color:#4f81bd; color:white" %)**Status**
... ... @@ -1385,7 +1385,7 @@
1385 1385  |0x00|DO1 set to high
1386 1386  |0x11|DO1 NO Action
1387 1387  
1388 -(% style="color:#4f81bd" %)**Fourth Byte**(%%): Control Method and Port status:
1327 +(% style="color:#4f81bd" %)**Fourth Byte**(%%): Control Method and Ports status:
1389 1389  
1390 1390  (% border="1" cellspacing="4" style="background-color:#f2f2f2; width:300px" %)
1391 1391  |(% style="background-color:#4f81bd; color:white" %)**Second Byte**|(% style="background-color:#4f81bd; color:white" %)**Status**
... ... @@ -1393,7 +1393,7 @@
1393 1393  |0x00|DO2 set to high
1394 1394  |0x11|DO2 NO Action
1395 1395  
1396 -(% style="color:#4f81bd" %)**Fifth Byte**(%%): Control Method and Port status:
1335 +(% style="color:#4f81bd" %)**Fifth Byte**(%%): Control Method and Ports status:
1397 1397  
1398 1398  (% border="1" cellspacing="4" style="background-color:#f2f2f2; width:300px" %)
1399 1399  |(% style="background-color:#4f81bd; color:white" %)**Second Byte**|(% style="background-color:#4f81bd; color:white" %)**Status**
... ... @@ -1401,16 +1401,16 @@
1401 1401  |0x00|DO3 set to high
1402 1402  |0x11|DO3 NO Action
1403 1403  
1404 -(% style="color:#4f81bd" %)**Sixth, Seventh, Eighth, and Ninth Bytes**:(%%) Latching time (Unit: ms)
1343 +(% style="color:#4f81bd" %)**Sixth and Seventh and Eighth and Ninth Byte**:(%%) Latching time. Unit: ms
1405 1405  
1406 1406  
1407 1407  (% style="color:red" %)**Note: **
1408 1408  
1409 - Since firmware v1.6.0, the latch time support 4 bytes and 2 bytes
1348 + Since Firmware v1.6.0, the latch time support 4 bytes and 2 bytes
1410 1410  
1411 - Before firmware v1.6.0, the latch time only supported 2 bytes.
1350 + Before Firmwre v1.6.0 the latch time only suport 2 bytes.
1412 1412  
1413 -(% style="color:red" %)**Device will upload a packet if the downlink code executes successfully.**
1352 +(% style="color:red" %)**Device will upload a packet if downlink code executes successfully.**
1414 1414  
1415 1415  
1416 1416  **Example payload:**
... ... @@ -1417,21 +1417,22 @@
1417 1417  
1418 1418  **~1. A9 01 01 01 01 07 D0**
1419 1419  
1420 -DO1 pin, DO2 pin, and DO3 pin will be set to low, last for 2 seconds, and then revert to their original state.
1359 +DO1 pin & DO2 pin & DO3 pin will be set to Low, last 2 seconds, then change back to original state.
1421 1421  
1422 1422  **2. A9 01 00 01 11 07 D0**
1423 1423  
1424 -DO1 pin is set to high, DO2 pin is set to low, and DO3 pin takes no action. This lasts for 2 seconds and then reverts to the original state.
1363 +DO1 pin set high, DO2 pin set low, DO3 pin no action, last 2 seconds, then change back to original state.
1425 1425  
1426 1426  **3. A9 00 00 00 00 07 D0**
1427 1427  
1428 -DO1 pin, DO2 pin, and DO3 pin will be set to high, last for 2 seconds, and then all change to low.
1367 +DO1 pin & DO2 pin & DO3 pin will be set to high, last 2 seconds, then both change to low.
1429 1429  
1430 1430  **4. A9 00 11 01 00 07 D0**
1431 1431  
1432 -DO1 pin takes no action, DO2 pin is set to low, and DO3 pin is set to high. This lasts for 2 seconds, after which DO1 pin takes no action, DO2 pin is set to high, and DO3 pin is set to low.
1371 +DO1 pin no action, DO2 pin set low, DO3 pin set high, last 2 seconds, then DO1 pin no action, DO2 pin set high, DO3 pin set low
1433 1433  
1434 1434  
1374 +
1435 1435  ==== 3.4.2.14 Relay ~-~- Control Relay Output RO1/RO2 ====
1436 1436  
1437 1437  
... ... @@ -1446,11 +1446,11 @@
1446 1446  
1447 1447  
1448 1448  (((
1449 -If payload is 0x030100, it means setting RO1 to close and RO2 to open.
1389 +If payload = 0x030100, it means set RO1 to close and RO2 to open.
1450 1450  )))
1451 1451  
1452 1452  (((
1453 -00: Close ,  01: Open , 11: No action
1393 +00: Closed ,  01: Open , 11: No action
1454 1454  
1455 1455  (% border="1" cellspacing="4" style="background-color:#f2f2f2; width:320px" %)
1456 1456  |(% style="background-color:#4f81bd; color:white" %)**Downlink Code**|(% style="background-color:#4f81bd; color:white" %)**RO1**|(% style="background-color:#4f81bd; color:white" %)**RO2**
... ... @@ -1467,9 +1467,9 @@
1467 1467  (% style="color:red" %)**Device will upload a packet if downlink code executes successfully.**
1468 1468  
1469 1469  
1410 +
1470 1470  ==== 3.4.2.15 Relay ~-~- Control Relay Output RO1/RO2 with time control ====
1471 1471  
1472 -Controls the relay output time.
1473 1473  
1474 1474  * (% style="color:#037691" %)**AT Command:**
1475 1475  
... ... @@ -1481,15 +1481,15 @@
1481 1481  (% style="color:blue" %)**0x05 aa bb cc dd     ** (%%)~/~/ Set RO1/RO2 relay with time control
1482 1482  
1483 1483  
1484 -This is to control the relay output time. It includes four bytes:
1424 +This is to control the relay output time of relay. Include four bytes:
1485 1485  
1486 1486  (% style="color:#4f81bd" %)**First Byte **(%%)**:** Type code (0x05)
1487 1487  
1488 1488  (% style="color:#4f81bd" %)**Second Byte(aa)**(%%): Inverter Mode
1489 1489  
1490 -01: Relays will change back to their original state after timeout.
1430 +01: Relays will change back to original state after timeout.
1491 1491  
1492 -00: Relays will change to the inverter state after timeout.
1432 +00: Relays will change to an inverter state after timeout
1493 1493  
1494 1494  
1495 1495  (% style="color:#4f81bd" %)**Third Byte(bb)**(%%): Control Method and Ports status:
... ... @@ -1502,12 +1502,12 @@
1502 1502  
1503 1503  (% style="color:red" %)**Note:**
1504 1504  
1505 - Since firmware v1.6.0, the latch time supports both 4 bytes and 2 bytes.
1445 + Since Firmware v1.6.0, the latch time support 4 bytes and 2 bytes
1506 1506  
1507 - Before firmware v1.6.0, the latch time only supported 2 bytes.
1447 + Before Firmwre v1.6.0 the latch time only suport 2 bytes.
1508 1508  
1509 1509  
1510 -(% style="color:red" %)**Device will upload a packet if the downlink code executes successfully.**
1450 +(% style="color:red" %)**Device will upload a packet if downlink code executes successfully.**
1511 1511  
1512 1512  
1513 1513  **Example payload:**
... ... @@ -1514,19 +1514,19 @@
1514 1514  
1515 1515  **~1. 05 01 11 07 D0**
1516 1516  
1517 -Relay1 and Relay2 will be set to NC, lasting 2 seconds, then revert to their original state
1457 +Relay1 and Relay 2 will be set to NC , last 2 seconds, then change back to original state.
1518 1518  
1519 1519  **2. 05 01 10 07 D0**
1520 1520  
1521 -Relay1 will change to NC, Relay2 will change to NO, lasting 2 seconds, then both will revert to their original state.
1461 +Relay1 will change to NC, Relay2 will change to NO, last 2 seconds, then both change back to original state.
1522 1522  
1523 1523  **3. 05 00 01 07 D0**
1524 1524  
1525 -Relay1 will change to NO, Relay2 will change to NC, lasting 2 seconds, then Relay1 will change to NC, and Relay2 will change to NO.
1465 +Relay1 will change to NO, Relay2 will change to NC, last 2 seconds, then relay change to NC,Relay2 change to NO.
1526 1526  
1527 1527  **4. 05 00 00 07 D0**
1528 1528  
1529 -Relay1 and Relay2 will change to NO, lasting 2 seconds, then both will change to NC.
1469 +Relay 1 & relay2 will change to NO, last 2 seconds, then both change to NC.
1530 1530  
1531 1531  
1532 1532  
... ... @@ -1533,7 +1533,7 @@
1533 1533  ==== 3.4.2.16 Counting ~-~- Voltage threshold counting ====
1534 1534  
1535 1535  
1536 -When the voltage exceeds the threshold, counting begins. For details, see [[MOD4>>||anchor="H3.3.4AT2BMOD3D42CSingleDICounting2B1xVoltageCounting"]]
1476 +When voltage exceed the threshold, count. Feature see [[MOD4>>||anchor="H3.3.4AT2BMOD3D42CSingleDICounting2B1xVoltageCounting"]]
1537 1537  
1538 1538  * (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+VOLMAX   ** (%%)~/~/ See [[MOD4>>||anchor="H3.3.4AT2BMOD3D42CSingleDICounting2B1xVoltageCounting"]]
1539 1539  
... ... @@ -1542,76 +1542,15 @@
1542 1542  (% style="color:blue" %)**0xA5 aa bb cc   ** (%%)~/~/ Same as AT+VOLMAX=(aa bb),cc
1543 1543  
1544 1544  
1545 -(% style="color:#037691" %)**AT Command**
1546 1546  
1547 -(% border="2" style="width:500px" %)
1548 -|(% style="width:137px" %)**Command**|(% style="width:361px" %)AT+VOLMAX=<voltage><logic>
1549 -|(% style="width:137px" %)**Response**|(% style="width:361px" %)
1550 -|(% style="width:137px" %)**Parameters**|(% style="width:361px" %)(((
1551 -**voltage** : voltage threshold in mV
1552 -
1553 -**logic**:
1554 -
1555 -0 : lower than
1556 -
1557 -1: higher than
1558 -
1559 -if you leave logic parameter blank, it is considered 0
1560 -)))
1561 -|(% style="width:137px" %)**Examples**|(% style="width:361px" %)(((
1562 -AT+VOLMAX=20000
1563 -
1564 -If AVI1 voltage higher than VOLMAX (20000mV =20v), counter increase 1
1565 -
1566 -AT+VOLMAX=20000,0
1567 -
1568 -If AVI1 voltage lower than VOLMAX (20000mV =20v), counter increase 1
1569 -
1570 -AT+VOLMAX=20000,1
1571 -
1572 -If AVI1 voltage higher than VOLMAX (20000mV =20v), counter increase 1
1573 -)))
1574 -
1575 -(% style="color:#037691" %)**Downlink Payload**
1576 -
1577 -(% border="2" style="width:500px" %)
1578 -|(% style="width:140px" %)**Payload**|(% style="width:358px" %)<prefix><voltage><logic>
1579 -|(% style="width:140px" %)**Parameters**|(% style="width:358px" %)(((
1580 -**prefix** : A5 (hex)
1581 -
1582 -**voltage** : voltage threshold in mV (2 bytes in hex)
1583 -
1584 -**logic**: (1 byte in hexadecimal)
1585 -
1586 -0 : lower than
1587 -
1588 -1: higher than
1589 -
1590 -if you leave logic parameter blank, it is considered 1 (higher than)
1591 -)))
1592 -|(% style="width:140px" %)**Example**|(% style="width:358px" %)(((
1593 -A5 **4E 20**
1594 -
1595 -If AVI1 voltage higher than VOLMAX (20000mV =20v), counter increase 1
1596 -
1597 -A5 **4E 20 00**
1598 -
1599 -If AVI1 voltage lower than VOLMAX (20000mV =20v), counter increase 1
1600 -
1601 -A5 **4E 20 01**
1602 -
1603 -If AVI1 voltage higher than VOLMAX (20000mV =20v), counter increase 1
1604 -)))
1605 -
1606 1606  ==== 3.4.2.17 Counting ~-~- Pre-configure the Count Number ====
1607 1607  
1608 -This command allows users to pre-configure specific count numbers for various counting parameters such as Count1, Count2, or AVI1 Count. Use the AT command to set the desired count number for each configuration.
1609 1609  
1610 1610  * (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+SETCNT=aa,(bb cc dd ee) **
1611 1611  
1612 1612  (% style="color:red" %)**aa:**(%%) 1: Set count1; 2: Set count2; 3: Set AV1 count
1613 1613  
1614 -(% style="color:red" %)**bb cc dd ee: **(%%)The number to be set
1493 +(% style="color:red" %)**bb cc dd ee: **(%%)number to be set
1615 1615  
1616 1616  
1617 1617  * (% style="color:#037691" %)**Downlink Payload (prefix 0xA8):**
... ... @@ -1619,55 +1619,12 @@
1619 1619  (% style="color:blue" %)**0x A8 aa bb cc dd ee     ** (%%)~/~/ same as AT+SETCNT=aa,(bb cc dd ee)
1620 1620  
1621 1621  
1622 -(% style="color:#037691" %)**AT Command**
1623 1623  
1624 -(% border="2" style="width:500px" %)
1625 -|(% style="width:134px" %)**Command**|(% style="width:364px" %)AT+SETCNT=<counting_parameter><number>
1626 -|(% style="width:134px" %)**Response**|(% style="width:364px" %)
1627 -|(% style="width:134px" %)**Parameters**|(% style="width:364px" %)(((
1628 -**counting_parameter** :
1629 -
1630 -1: COUNT1
1631 -
1632 -2: COUNT2
1633 -
1634 -3: AVI1 Count
1635 -
1636 -**number** : Start number
1637 -)))
1638 -|(% style="width:134px" %)**Example**|(% style="width:364px" %)(((
1639 -AT+SETCNT=1,10
1640 -
1641 -Sets the COUNT1 to 10.
1642 -)))
1643 -
1644 -(% style="color:#037691" %)**Downlink Payload**
1645 -
1646 -(% border="2" style="width:500px" %)
1647 -|(% style="width:135px" %)**Payload**|(% style="width:363px" %)<prefix><counting_parameter><number>
1648 -|(% style="width:135px" %)**Parameters**|(% style="width:363px" %)(((
1649 -prefix : A8 (hex)
1650 -
1651 -**counting_parameter** : (1 byte in hexadecimal)
1652 -
1653 -1: COUNT1
1654 -
1655 -2: COUNT2
1656 -
1657 -3: AVI1 Count
1658 -
1659 -**number** : Start number, 4 bytes in hexadecimal
1660 -)))
1661 -|(% style="width:135px" %)**Example**|(% style="width:363px" %)(((
1662 -A8 **01 00 00 00 0A**
1663 -
1664 -Sets the COUNT1 to 10.
1665 -)))
1666 -
1667 1667  ==== 3.4.2.18 Counting ~-~- Clear Counting ====
1668 1668  
1669 -This command clears the counting in counting mode.
1670 1670  
1505 +Clear counting for counting mode
1506 +
1671 1671  * (% style="color:#037691" %)**AT Command:**(%%) (% style="color:blue" %)**AT+CLRCOUNT         **(%%) ~/~/ clear all counting
1672 1672  
1673 1673  * (% style="color:#037691" %)**Downlink Payload (prefix 0xA6):**
... ... @@ -1674,30 +1674,14 @@
1674 1674  
1675 1675  (% style="color:blue" %)**0x A6 01    ** (%%)~/~/ clear all counting
1676 1676  
1677 -(% style="color:#037691" %)**AT Command**
1678 1678  
1679 -(% border="2" style="width:500px" %)
1680 -|(% style="width:142px" %)**Command**|(% style="width:356px" %)AT+CLRCOUNT
1681 -|(% style="width:142px" %)**Response**|(% style="width:356px" %)-
1682 1682  
1683 -(% style="color:#037691" %)**Downlink Payload**
1684 -
1685 -(% border="2" style="width:500px" %)
1686 -|(% style="width:141px" %)**Payload**|(% style="width:357px" %)<prefix><clear?>
1687 -|(% style="width:141px" %)**Parameters**|(% style="width:357px" %)(((
1688 -prefix : A6 (hex)
1689 -
1690 -clear? : 01 (hex)
1691 -)))
1692 -|(% style="width:141px" %)**Example**|(% style="width:357px" %)A6 **01**
1693 -
1694 1694  ==== 3.4.2.19 Counting ~-~- Change counting mode to save time ====
1695 1695  
1696 -This command allows you to configure the device to save its counting result to internal flash memory at specified intervals. By setting a save time, the device will periodically store the counting data to prevent loss in case of power failure. The save interval can be adjusted to suit your requirements, with a minimum value of 30 seconds.
1697 1697  
1698 1698  * (% style="color:#037691" %)**AT Command:**
1699 1699  
1700 -(% style="color:blue" %)**AT+COUTIME=60  **(%%)~/~/ Sets the save time to 60 seconds. The device will save the counting result in internal flash every 60 seconds. (Min value: 30 seconds)
1520 +(% style="color:blue" %)**AT+COUTIME=60  **(%%)~/~/ Set save time to 60 seconds. Device will save the counting result in internal flash every 60 seconds. (min value: 30)
1701 1701  
1702 1702  
1703 1703  * (% style="color:#037691" %)**Downlink Payload (prefix 0xA7):**
... ... @@ -1705,46 +1705,19 @@
1705 1705  (% style="color:blue" %)**0x A7 aa bb cc     ** (%%)~/~/ same as AT+COUTIME =aa bb cc,
1706 1706  
1707 1707  (((
1708 -Range: aa bb cc:0 to 16777215,  (unit: seconds)
1528 +range: aa bb cc:0 to 16777215,  (unit:second)
1709 1709  )))
1710 1710  
1711 1711  
1712 -(% style="color:#037691" %)**AT Command**
1713 1713  
1714 -(% border="2" style="width:500px" %)
1715 -|(% style="width:124px" %)**Command**|(% style="width:374px" %)AT+COUTIME=<time>
1716 -|(% style="width:124px" %)**Response**|(% style="width:374px" %)
1717 -|(% style="width:124px" %)**Parameters**|(% style="width:374px" %)time : seconds (0 to 16777215)
1718 -|(% style="width:124px" %)**Example**|(% style="width:374px" %)(((
1719 -AT+COUTIME=60
1720 -
1721 -Sets the device to save its counting results to the memory every 60 seconds.
1722 -)))
1723 -
1724 -(% style="color:#037691" %)**Downlink Payload**
1725 -
1726 -(% border="2" style="width:500px" %)
1727 -|(% style="width:123px" %)**Payload**|(% style="width:375px" %)<prefix><time>
1728 -|(% style="width:123px" %)**Parameters**|(% style="width:375px" %)(((
1729 -prefix : A7
1730 -
1731 -time : seconds, 3 bytes in hexadecimal
1732 -)))
1733 -|(% style="width:123px" %)**Example**|(% style="width:375px" %)(((
1734 -A7 **00 00 3C**
1735 -
1736 -Sets the device to save its counting results to the memory every 60 seconds.
1737 -)))
1738 -
1739 1739  ==== 3.4.2.20 Reset save RO DO state ====
1740 1740  
1741 -This command allows you to reset the saved relay output (RO) and digital output (DO) states when the device joins the network. By configuring this setting, you can control whether the device should retain or reset the relay states after a reset and rejoin to the network.
1742 1742  
1743 1743  * (% style="color:#037691" %)**AT Command:**
1744 1744  
1745 1745  (% style="color:blue" %)**AT+RODORESET=1    **(%%)~/~/ RODO will close when the device joining the network. (default)
1746 1746  
1747 -(% style="color:blue" %)**AT+RODORESET=0    **(%%)~/~/ After the device is reset, the previously saved RODO state (only MOD2 to MOD5) is read, and its state will not change when the device reconnects to the network.
1540 +(% style="color:blue" %)**AT+RODORESET=0    **(%%)~/~/ After the device is reset, the previously saved RODO state (only MOD2 to MOD5) is read, and its state is not changed when it is reconnected to the network.
1748 1748  
1749 1749  
1750 1750  * (% style="color:#037691" %)**Downlink Payload (prefix 0xAD):**
... ... @@ -1752,50 +1752,9 @@
1752 1752  (% style="color:blue" %)**0x AD aa      ** (%%)~/~/ same as AT+RODORET =aa
1753 1753  
1754 1754  
1755 -(% border="2" style="width:500px" %)
1756 -|(% style="width:127px" %)**Command**|(% style="width:371px" %)AT+RODORESET=<state>
1757 -|(% style="width:127px" %)**Response**|(% style="width:371px" %)
1758 -|(% style="width:127px" %)**Parameters**|(% style="width:371px" %)(((
1759 -**state** :
1760 1760  
1761 -**0** : RODO will close when the device joins the network. (default)
1762 -
1763 -**1**: After the device is reset, the previously saved RODO state (limited to MOD2 to MOD5) is read, and it will not change when the device reconnects to the network.
1764 -)))
1765 -|(% style="width:127px" %)**Example**|(% style="width:371px" %)(((
1766 -(% style="color:blue" %)**AT+RODORESET=1 **
1767 -
1768 -RODO will close when the device joins the network. (default)
1769 -
1770 -(% style="color:blue" %)**AT+RODORESET=0 **
1771 -
1772 -After the device is reset, the previously saved RODO state (limited to MOD2 to MOD5) is read, and it will not change when the device reconnects to the network.
1773 -)))
1774 -
1775 -(% border="2" style="width:500px" %)
1776 -|(% style="width:127px" %)**Payload**|(% style="width:371px" %)<prefix><state>
1777 -|(% style="width:127px" %)**Parameters**|(% style="width:371px" %)(((
1778 -**prefix** : AD
1779 -
1780 -**state** :
1781 -
1782 -**0** : RODO will close when the device joins the network. (default), represents as 1 byte in hexadecimal.
1783 -
1784 -**1**: After the device is reset, the previously saved RODO state (limited to MOD2 to MOD5) is read, and it will not change when the device reconnects to the network. - represents as 1 byte in hexadecimal
1785 -)))
1786 -|(% style="width:127px" %)**Example**|(% style="width:371px" %)(((
1787 -AD **01**
1788 -
1789 -RODO will close when the device joins the network. (default)
1790 -
1791 -AD **00**
1792 -
1793 -After the device is reset, the previously saved RODO state (limited to MOD2 to MOD5) is read, and it will not change when the device reconnects to the network.
1794 -)))
1795 -
1796 1796  ==== 3.4.2.21 Encrypted payload ====
1797 1797  
1798 -This command allows you to configure whether the device should upload data in an encrypted format or in plaintext. By default, the device encrypts the payload before uploading. You can toggle this setting to either upload encrypted data or transmit it without encryption.
1799 1799  
1800 1800  * (% style="color:#037691" %)**AT Command:**
1801 1801  
... ... @@ -1804,67 +1804,21 @@
1804 1804  (% style="color:blue" %)**AT+DECRYPT=0    **(%%)~/~/  Encrypt when uploading payload (default)
1805 1805  
1806 1806  
1807 -(% border="2" style="width:500px" %)
1808 -|(% style="width:127px" %)**Command**|(% style="width:371px" %)AT+DECRYPT=<state>
1809 -|(% style="width:127px" %)**Response**|(% style="width:371px" %)
1810 -|(% style="width:127px" %)**Parameters**|(% style="width:371px" %)(((
1811 -state :
1812 1812  
1813 -1 : The payload is uploaded without encryption
1814 -
1815 -0 : The payload is encrypted when uploaded (default)
1816 -)))
1817 -|(% style="width:127px" %)**Example**|(% style="width:371px" %)(((
1818 -AT+DECRYPT=1
1819 -
1820 -The payload is uploaded without encryption
1821 -
1822 -AT+DECRYPT=0
1823 -
1824 -The payload is encrypted when uploaded (default)
1825 -)))
1826 -
1827 -There is no downlink payload for this configuration.
1828 -
1829 -
1830 1830  ==== 3.4.2.22 Get sensor value ====
1831 1831  
1832 -This command allows you to retrieve and optionally uplink sensor readings through the serial port.
1833 1833  
1834 1834  * (% style="color:#037691" %)**AT Command:**
1835 1835  
1836 -(% style="color:blue" %)**AT+GETSENSORVALUE=0    **(%%)~/~/ The serial port retrieves the reading of the current sensor.
1565 +(% style="color:blue" %)**AT+GETSENSORVALUE=0    **(%%)~/~/ The serial port gets the reading of the current sensor
1837 1837  
1838 -(% style="color:blue" %)**AT+GETSENSORVALUE=1    **(%%)~/~/ The serial port retrieves the current sensor reading and uploads it.
1567 +(% style="color:blue" %)**AT+GETSENSORVALUE=1    **(%%)~/~/ The serial port gets the current sensor reading and uploads it.
1839 1839  
1840 1840  
1841 -(% border="2" style="width:500px" %)
1842 -|(% style="width:127px" %)**Command**|(% style="width:371px" %)AT+GETSENSORVALUE=<state>
1843 -|(% style="width:127px" %)**Response**|(% style="width:371px" %)
1844 -|(% style="width:127px" %)**Parameters**|(% style="width:371px" %)(((
1845 -**state** :
1846 1846  
1847 -**0 **: Retrieves the current sensor reading via the serial port.
1571 +==== 3.4.2.23 Resets the downlink packet count ====
1848 1848  
1849 -**1 **: Retrieves and uploads the current sensor reading via the serial port.
1850 -)))
1851 -|(% style="width:127px" %)**Example**|(% style="width:371px" %)(((
1852 -AT+GETSENSORVALUE=0
1853 1853  
1854 -Retrieves the current sensor reading via the serial port.
1855 -
1856 -AT+GETSENSORVALUE=1
1857 -
1858 -Retrieves and uplinks the current sensor reading via the serial port.
1859 -)))
1860 -
1861 -There is no downlink payload for this configuration.
1862 -
1863 -
1864 -==== 3.4.2.23 Resetting the downlink packet count ====
1865 -
1866 -This command manages how the node handles mismatched downlink packet counts. It offers two modes: one disables the reception of further downlink packets if discrepancies occur, while the other resets the downlink packet count to align with the server, ensuring continued communication.
1867 -
1868 1868  * (% style="color:#037691" %)**AT Command:**
1869 1869  
1870 1870  (% style="color:blue" %)**AT+DISFCNTCHECK=0   **(%%)~/~/ When the downlink packet count sent by the server is less than the node downlink packet count or exceeds 16384, the node will no longer receive downlink packets (default)
... ... @@ -1872,37 +1872,10 @@
1872 1872  (% style="color:blue" %)**AT+DISFCNTCHECK=1   **(%%)~/~/ When the downlink packet count sent by the server is less than the node downlink packet count or exceeds 16384, the node resets the downlink packet count and keeps it consistent with the server downlink packet count.
1873 1873  
1874 1874  
1875 -(% border="2" style="width:500px" %)
1876 -|(% style="width:130px" %)**Command**|(% style="width:368px" %)AT+DISFCNTCHECK=<state>
1877 -|(% style="width:130px" %)**Response**|(% style="width:368px" %)(((
1878 -
1879 -)))
1880 -|(% style="width:130px" %)**Parameters**|(% style="width:368px" %)(((
1881 -**state **:
1882 1882  
1883 -**0** : When the downlink packet count sent by the server is less than the node's downlink packet count or exceeds 16,384, the node stops receiving further downlink packets (default).
1884 -
1885 -
1886 -**1** : When the downlink packet count sent by the server is less than the node's downlink packet count or exceeds 16,384, the node resets its downlink packet count to match the server's, ensuring consistency.
1887 -)))
1888 -|(% style="width:130px" %)**Example**|(% style="width:368px" %)(((
1889 -AT+DISFCNTCHECK=0
1890 -
1891 -When the downlink packet count sent by the server is less than the node's downlink packet count or exceeds 16,384, the node stops receiving further downlink packets (default).
1892 -
1893 -AT+DISFCNTCHECK=1
1894 -
1895 -When the downlink packet count sent by the server is less than the node's downlink packet count or exceeds 16,384, the node resets its downlink packet count to match the server's, ensuring consistency.
1896 -)))
1897 -
1898 -There is no downlink payload for this configuration.
1899 -
1900 -
1901 1901  ==== 3.4.2.24 When the limit bytes are exceeded, upload in batches ====
1902 1902  
1903 1903  
1904 -This command controls the behavior of the node when the combined size of the MAC commands (MACANS) from the server and the payload exceeds the allowed byte limit for the current data rate (DR). The command provides two modes: one enables splitting the data into batches to ensure compliance with the byte limit, while the other prioritizes the payload and ignores the MACANS in cases of overflow.
1905 -
1906 1906  * (% style="color:#037691" %)**AT Command:**
1907 1907  
1908 1908  (% style="color:blue" %)**AT+DISMACANS=0**   (%%) ~/~/ When the MACANS of the reply server plus the payload exceeds the maximum number of bytes of 11 bytes (DR0 of US915, DR2 of AS923, DR2 of AU195), the node will send a packet with a payload of 00 and a port of 4. (default)
... ... @@ -1914,50 +1914,10 @@
1914 1914  
1915 1915  (% style="color:blue" %)**0x21 00 01 ** (%%) ~/~/ Set  the DISMACANS=1
1916 1916  
1917 -(% style="color:#037691" %)**AT Command**
1918 1918  
1919 -(% border="2" style="width:500px" %)
1920 -|(% style="width:127px" %)**Command**|(% style="width:371px" %)AT+DISMACANS=<state>
1921 -|(% style="width:127px" %)**Response**|(% style="width:371px" %)
1922 -|(% style="width:127px" %)**Parameters**|(% style="width:371px" %)(((
1923 -**state** :
1924 1924  
1925 -**0** : When the combined size of the MACANS from the server and the payload exceeds the byte limit (11 bytes for DR0 of US915, DR2 of AS923, DR2 of AU915), the node sends a packet with a payload of 00 and a port of 4. (default)
1926 -
1927 -**1** : When the combined size of the MACANS from the server and the payload exceeds the byte limit for the current DR, the node ignores the MACANS and only uploads the payload.
1928 -)))
1929 -|(% style="width:127px" %)**Example**|(% style="width:371px" %)(((
1930 -AT+DISMACANS=0
1931 -
1932 -When the combined size of the MACANS from the server and the payload exceeds the byte limit (11 bytes for DR0 of US915, DR2 of AS923, DR2 of AU915), the node sends a packet with a payload of 00 and a port of 4. (default)
1933 -
1934 -AT+DISMACANS=1
1935 -
1936 -When the combined size of the MACANS from the server and the payload exceeds the byte limit for the current DR, the node ignores the MACANS and only uploads the payload.
1937 -)))
1938 -
1939 -(% style="color:#037691" %)**Downlink Payload**
1940 -
1941 -(% border="2" style="width:500px" %)
1942 -|(% style="width:126px" %)**Payload**|(% style="width:372px" %)<prefix><state>
1943 -|(% style="width:126px" %)**Parameters**|(% style="width:372px" %)(((
1944 -**prefix** : 21
1945 -
1946 -**state** : (2 bytes in hexadecimal)
1947 -
1948 -**0** : When the combined size of the MACANS from the server and the payload exceeds the byte limit (11 bytes for DR0 of US915, DR2 of AS923, DR2 of AU915), the node sends a packet with a payload of 00 and a port of 4. (default)
1949 -
1950 -**1 **: When the combined size of the MACANS from the server and the payload exceeds the byte limit for the current DR, the node ignores the MACANS and only uploads the payload.
1951 -)))
1952 -|(% style="width:126px" %)**Example**|(% style="width:372px" %)(((
1953 -21 **00 01**
1954 -
1955 -Set DISMACANS=1
1956 -)))
1957 -
1958 1958  ==== 3.4.2.25 Copy downlink to uplink ====
1959 1959  
1960 -This command enables the device to immediately uplink the content of a received downlink packet back to the server. The command allows for quick data replication from downlink to uplink, with a fixed port number of 100.
1961 1961  
1962 1962  * (% style="color:#037691" %)**AT Command**(%%)**:**
1963 1963  
... ... @@ -1970,22 +1970,8 @@
1970 1970  
1971 1971  For example, sending 11 22 33 44 55 66 77 will return invalid configuration 00 11 22 33 44 55 66 77.
1972 1972  
1973 -(% border="2" style="width:500px" %)
1974 -|(% style="width:122px" %)**Command**|(% style="width:376px" %)(((
1975 -AT+RPL=5
1976 1976  
1977 -After receiving a downlink packet from the server, the node immediately uplinks the content of the packet back to the server using port number 100.
1978 -)))
1979 -|(% style="width:122px" %)**Example**|(% style="width:376px" %)(((
1980 -Downlink:
1981 1981  
1982 -01 00 02 58
1983 -
1984 -Uplink:
1985 -
1986 -01 01 00 02 58
1987 -)))
1988 -
1989 1989  [[image:http://wiki.dragino.com/xwiki/bin/download/Main/User%20Manual%20for%20LoRaWAN%20End%20Nodes/LSN50%20%26%20LSN50-V2%20-%20LoRaWAN%20Sensor%20Node%20User%20Manual/WebHome/image-20220823173833-7.png?width=1124&height=149&rev=1.1||alt="image-20220823173833-7.png"]]
1990 1990  
1991 1991  For example, if 01 00 02 58 is issued, a valid configuration of 01 01 00 02 58 will be returned.
... ... @@ -1992,16 +1992,14 @@
1992 1992  
1993 1993  
1994 1994  
1995 -==== 3.4.2.26 Query firmware version, frequency band, sub band, and TDC time ====
1620 +==== 3.4.2.26 Query version number and frequency band TDC ====
1996 1996  
1997 -This command is used to query key information about the device, including its firmware version, frequency band, sub band, and TDC time. By sending the specified payload as a downlink, the server can retrieve this essential data from the device.
1998 1998  
1999 1999  * (((
2000 2000  (% style="color:#037691" %)**Downlink Payload**(%%)**:**
2001 2001  
2002 -(% style="color:blue" %)**26 01  ** (%%) ~/~/  The downlink payload 26 01 is used to query the device's firmware version, frequency band, sub band, and TDC time.
1626 +(% style="color:blue" %)**26 01  ** (%%) ~/~/  Downlink 26 01 can query device upload frequency, frequency band, software version number, TDC time.
2003 2003  
2004 -
2005 2005  
2006 2006  )))
2007 2007  
... ... @@ -2031,8 +2031,6 @@
2031 2031  
2032 2032  === 3.5.2 Configuring ThingsEye.io ===
2033 2033  
2034 -The ThingsEye.io IoT platform is not open for self-registration at the moment. If you are interested in testing the platform, please send your project information to admin@thingseye.io, and we will create an account for you.
2035 -
2036 2036  * Login to your [[ThingsEye.io >>https://thingseye.io]]account.
2037 2037  * Under the **Integrations center**, click **Integrations**.
2038 2038  * Click the **Add integration** button (the button with the **+** symbol).
... ... @@ -2081,7 +2081,7 @@
2081 2081  
2082 2082  * Choose **Region** from the **Host type**.
2083 2083  * Enter the **cluster** of your **The Things Stack** in the **Region** textbox. You can find the cluster in the url (e.g., https:~/~/**eu1**.cloud.thethings.network/...).
2084 -* Enter the **Username** and **Password** of the MQTT integration in the **Credentials** section. The **username **and **password **can be found on the MQTT integration page of your The Things Stack account (see **3.5.1 Configuring The Things Stack**).
1705 +* Enter the **Username** and **Password** of the MQTT integration in the **Credentials** section. The **username **and **password **can be found on the MQTT integration page of your The Things Stack account (see Configuring The Things Stack).
2085 2085  * Click the **Check connection** button to test the connection. If the connection is successful, you will see the message saying **Connected**.
2086 2086  
2087 2087  [[image:message-1.png]]
... ... @@ -2092,7 +2092,7 @@
2092 2092  [[image:thingseye-io-step-5.png||height="625" width="1000"]]
2093 2093  
2094 2094  
2095 -Your integration has been added to the** Integrations** list and will be displayed on the **Integrations** page. Check whether the status is shown as **Active**. If not, review your configuration settings and correct any errors.
1716 +Your integration has been added to the** Integrations** list and will be displayed on the **Integrations** page. Check whether the status is shown as **Active**. If not, review your configuration settings.
2096 2096  
2097 2097  
2098 2098  [[image:thingseye.io_integrationsCenter_integrations.png||height="686" width="1000"]]
... ... @@ -2108,7 +2108,7 @@
2108 2108  If you want to edit the settings you have provided, click on the **Toggle edit mode** button. Once you have done click on the **Apply changes **button.
2109 2109  
2110 2110  {{info}}
2111 -See also [[ThingsEye documentation>>https://wiki.thingseye.io/xwiki/bin/view/Main/]].
1732 +See also ThingsEye documentation.
2112 2112  {{/info}}
2113 2113  
2114 2114  ==== **3.5.2.2 Viewing events** ====
... ... @@ -2121,7 +2121,7 @@
2121 2121  [[image:thingseye-events.png||height="686" width="1000"]]
2122 2122  
2123 2123  
2124 -* To view the **JSON payload** of a message, click on the **three dots (...)** in the Message column of the desired message.
1745 +* To view the JSON payload of a message, click on the three dots (...) in the Message column of the desired message.
2125 2125  
2126 2126  [[image:thingseye-json.png||width="1000"]]
2127 2127  
... ... @@ -2131,14 +2131,9 @@
2131 2131  If you want to delete an integration, click the **Delete integratio**n button on the Integrations page.
2132 2132  
2133 2133  
2134 -==== 3.5.2.4 Creating a Dashboard to Display and Analyze LT-22222-L Data ====
2135 -
2136 -This will be added soon.
2137 -
2138 -
2139 2139  == 3.6 Interface Details ==
2140 2140  
2141 -=== 3.6.1 Digital Input Ports: DI1/DI2/DI3 (For LT-33222-L, Low Active) ===
1757 +=== 3.6.1 Digital Input Ports: DI1/DI2/DI3 (For LT-33222-L, Low Active ) ===
2142 2142  
2143 2143  
2144 2144  Supports NPN-type sensors.
dragino-lorawan-nw-lt-22222-n.jpg
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.pradeeka
Size
... ... @@ -1,1 +1,0 @@
1 -267.3 KB
Content
dragino-ttn-te.jpg
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.pradeeka
Size
... ... @@ -1,1 +1,0 @@
1 -273.8 KB
Content
lorawan-nw.jpg
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.pradeeka
Size
... ... @@ -1,1 +1,0 @@
1 -250.6 KB
Content

Applications

Navigation

Copyright ©2010-2024 Dragino Technology Co., LTD. All rights reserved
Dragino Wiki v2.0