Tago.IO - DRAGINO

Make sure to use Base64 Code. [[Reference>>http://wiki.dragino.com/xwiki/bin/view/Main/Notes%20for%20ChirpStack/#H4.1A0ChirpstackDownlinkNote]] for how to get Base64

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[[image:image-20220526143317-1.png||height="330" width="942"]]

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= 3. Example - Create TrackerD/LGT92 positioning widget =

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Creating TrackerD/ LGT92 in TTN does not require manual creation, you directly select LGT92 in the brand.

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Devices registered from the LoRaWAN device repository do not need to add a decoder. To manually create a device, you need to add a decoder.

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[[image:image-20220526145723-1.png]]

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The same steps are used to create widgets and location maps.

[[image:image-20220526145753-2.png]]

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[[image:image-20220526145831-3.png]]

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[[image:image-20220526145901-4.png]]

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LGT92 displays the walking track according to the location of the sent data packet.

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The device sets the time interval for sending data packets to control the positioning track.

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[[image:image-20220526145932-5.png]]

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= 4. Example - Real Time Location System demo(RTLS) =

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== 4.1 Introduction ==

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The purpose of this document is to describe the Real Time Location System demo(RTLS). It is created as a manual guide for understanding each process of the application, explaining types of users and setting the application.

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You can access the application through: [[https:~~/~~/rtls.run.tago.io>>url:https://rtls.run.tago.io/]]

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* The user can read this document for the description of the real-time positioning system demonstration.

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[[https:~~/~~/www.dragino.com/downloads/downloads/LoRa_End_Node/LBT1/RTLS_demo_documentation.pdf>>url:https://www.dragino.com/downloads/downloads/LoRa_End_Node/LBT1/RTLS_demo_documentation.pdf]]

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== 4.2 Instructions for using LBT1 with RTLS ==

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（1）RTLS supports TTNv3 and helium servers for indoor positioning.

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（2）The user needs to register the device with LBT1 on the TTNv3 or helium server.

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（3）Then the user needs to integrate the application into Tago.

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（4）Create LBT1 devices and beacons in RTLS. Please refer to the RTLS instruction document for the specific process.

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（5）The coordinate position will be updated every time the device sends a data packet.

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[[image:image-20220526150133-6.png]]

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= 5. Install Tago Core in LPS8v2 =

== 5.1 Tago Core ==

Tago Core is a (% style="color:blue" %)**free**(%%), (% style="color:blue" %)**fast**(%%), and (% style="color:blue" %)**open-source**(%%) IoT platform for edge computing that you can use to parse, and analyze the data from your devices!

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Tago Core supports all major operating systems and can be downloaded on this [[Downloads page>>https://downloads.tagocore.com/]].

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For more information on Tago Core, Users can check out this [[Link>>https://tagocore.com/docs#tagocore ]].

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Once you have downloaded and extracted TagoCore, you can run it by opening a terminal in the folder where the tagocore binary is located and typing the following command:

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(% class="box infomessage" %)

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(((

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wget [[https:~~/~~/downloads.tagocore.com/v0.4.1/tagocore-v0.4.1-linux-armv7.tar.gz>>https://downloads.tagocore.com/v0.4.1/tagocore-v0.4.1-linux-armv7.tar.gz]]

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tar -xvzf tagocore-v0.4.1-linux-armv7.tar.gz

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)))

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[[image:image-20220713185521-1.png]]

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== 5.2 Run Tago Core ==

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When you run the following command, you can access the GUI of TagoCore using the LPS8v2 gateway (% style="color:blue" %)**IP_ADDRESS:8888.**

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(% class="box infomessage" %)

(((

./tagocore start

./tagocore logs

)))

[[image:image-20220713191020-2.png||height="73" width="589"]]

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[[image:image-20220713194013-1.png||height="246" width="558"]]

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[[image:image-20220713191539-3.png||height="538" width="938"]]

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Wiki source code of Tago.IO

Applications

Navigation

author	version	line-number	content
		1
		2
		3
		4	~
		5
		6	~ Table of Contents:
		7
		8	{{toc/}}
		9
		10
		11
		12	= 1. Parse Payload =
		13
		14
		15	(((
		16	The following is our operation process and interface.
		17	)))
		18
		19	(((
		20	The code can be run in the payload parser.
		21
		22
		23	)))
		24
		25	[[image:image-20220526143905-6.png]]
		26
		27	Parse Payload
		28
		29
		30
		31	[[image:image-20220526143653-4.png]]
		32
		33	Parse Payload
		34
		35
		36	= 2. Create device steps at Tago =
		37
		38	== 2.1 General Steps ==
		39
		40
		41	Take the creation of LGT92 as an example
		42
		43
		44	[[image:image-20220526143953-7.png]]
		45
		46
		47
		48	Get the authorization code and fill in it
		49
		50
		51	[[image:image-20220526144034-8.png]]
		52
		53
		54
		55	All the following options require authorization.
		56
		57
		58	[[image:image-20220526144110-9.png]]
		59
		60
		61
		62	create device.
		63
		64
		65	[[image:image-20220526145059-13.png\|\|height="559" width="1314"]]
		66
		67
		68	[[image:image-20220526145031-12.png]]
		69
		70
		71	[[image:image-20220526145237-14.png\|\|height="228" width="1287"]]
		72
		73
		74	[[image:image-20220526145316-15.png]]
		75
		76
		77
		78
		79	The corresponding widget can be created according to the decoding of the device on TTN.
		80
		81
		82	[[image:image-20220526145459-16.png]]
		83
		84
		85	[[image:image-20220526145527-17.png]]
		86
		87
		88	== 2.2 Downlink Message to LoRaWAN End node ==
		89
		90
		91	Make sure to use Base64 Code. [[Reference>>http://wiki.dragino.com/xwiki/bin/view/Main/Notes%20for%20ChirpStack/#H4.1A0ChirpstackDownlinkNote]] for how to get Base64
		92
		93
		94	[[image:image-20220526143317-1.png\|\|height="330" width="942"]]
		95
		96
		97	= 3. Example - Create TrackerD/LGT92 positioning widget =
		98
		99
		100	Creating TrackerD/ LGT92 in TTN does not require manual creation, you directly select LGT92 in the brand.
		101
		102	Devices registered from the LoRaWAN device repository do not need to add a decoder. To manually create a device, you need to add a decoder.
		103
		104	[[image:image-20220526145723-1.png]]
		105
		106	The same steps are used to create widgets and location maps.
		107
		108
		109
		110	[[image:image-20220526145753-2.png]]
		111
		112
		113	[[image:image-20220526145831-3.png]]
		114
		115
		116	[[image:image-20220526145901-4.png]]
		117
		118
		119	LGT92 displays the walking track according to the location of the sent data packet.
		120
		121	The device sets the time interval for sending data packets to control the positioning track.
		122
		123
		124	[[image:image-20220526145932-5.png]]
		125
		126
		127	= 4. Example - Real Time Location System demo(RTLS) =
		128
		129	== 4.1 Introduction ==
		130
		131
		132	The purpose of this document is to describe the Real Time Location System demo(RTLS). It is created as a manual guide for understanding each process of the application, explaining types of users and setting the application.
		133
		134	You can access the application through: [[https:~~/~~/rtls.run.tago.io>>url:https://rtls.run.tago.io/]]
		135
		136
		137	* The user can read this document for the description of the real-time positioning system demonstration.
		138
		139	[[https:~~/~~/www.dragino.com/downloads/downloads/LoRa_End_Node/LBT1/RTLS_demo_documentation.pdf>>url:https://www.dragino.com/downloads/downloads/LoRa_End_Node/LBT1/RTLS_demo_documentation.pdf]]
		140
		141
		142	== 4.2 Instructions for using LBT1 with RTLS ==
		143
		144
		145	（1）RTLS supports TTNv3 and helium servers for indoor positioning.
		146
		147	（2）The user needs to register the device with LBT1 on the TTNv3 or helium server.
		148
		149	（3）Then the user needs to integrate the application into Tago.
		150
		151	（4）Create LBT1 devices and beacons in RTLS. Please refer to the RTLS instruction document for the specific process.
		152
		153	（5）The coordinate position will be updated every time the device sends a data packet.
		154
		155
		156	[[image:image-20220526150133-6.png]]
		157
		158
		159	= 5. Install Tago Core in LPS8v2 =
		160
		161	== 5.1 Tago Core ==
		162
		163
		164	Tago Core is a (% style="color:blue" %)free(%%), (% style="color:blue" %)fast(%%), and (% style="color:blue" %)open-source(%%) IoT platform for edge computing that you can use to parse, and analyze the data from your devices!
		165
		166	Tago Core supports all major operating systems and can be downloaded on this [[Downloads page>>https://downloads.tagocore.com/]].
		167
		168	For more information on Tago Core, Users can check out this [[Link>>https://tagocore.com/docs#tagocore ]].
		169
		170	Once you have downloaded and extracted TagoCore, you can run it by opening a terminal in the folder where the tagocore binary is located and typing the following command:
		171
		172
		173	(% class="box infomessage" %)
		174	(((
		175	wget [[https:~~/~~/downloads.tagocore.com/v0.4.1/tagocore-v0.4.1-linux-armv7.tar.gz>>https://downloads.tagocore.com/v0.4.1/tagocore-v0.4.1-linux-armv7.tar.gz]]
		176	tar -xvzf tagocore-v0.4.1-linux-armv7.tar.gz
		177	)))
		178
		179	[[image:image-20220713185521-1.png]]
		180
		181
		182	== 5.2 Run Tago Core ==
		183
		184
		185	When you run the following command, you can access the GUI of TagoCore using the LPS8v2 gateway (% style="color:blue" %)IP_ADDRESS:8888.
		186
		187
		188	(% class="box infomessage" %)
		189	(((
		190	./tagocore start
		191
		192	./tagocore logs
		193	)))
		194
		195	[[image:image-20220713191020-2.png\|\|height="73" width="589"]]
		196
		197
		198	[[image:image-20220713194013-1.png\|\|height="246" width="558"]]
		199
		200
		201	[[image:image-20220713191539-3.png\|\|height="538" width="938"]]
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		203