Update README.md
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@ -109,7 +109,9 @@ The configuration will be loaded from "Resources/Xbee_Config.xml". Most of the e
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We consider the following setup (**Fig.1**). The block (Drone + Manifold) can be replaced by any Desktop/Laptop meeting the prerequisites.
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**Fig.1:** Experimental Setup.
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**Fig.1:** Experimental Setup:
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![][fig1]
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[fig1]: https://github.com/MISTLab/XbeeMav/tree/master/Resources/Fig1.png "Fig.1"
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One of the drones will behave as a Master while the other one will act as a Slave. The Master drone will send commands to the Slave drone.
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Each drone is running a dummy flight controller node "test_controller". According to the drone type Master/Slave, the "test_controller" node will respectively send or receive and display a command. The commands in the Master drone will be introduced with the keyboard. When a command is received in the Slave drone, it will be printed on the screen. The following table (**Table.2**) depicts the keys of each command:
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@ -126,7 +128,9 @@ Each drone is running a dummy flight controller node "test_controller". Accordin
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| 23 | Start Mission |
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**Fig.2:** ROS nodes running on the drone.
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**Fig.2:** ROS nodes running on the drone:
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![][fig2]
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[fig2]: https://github.com/MISTLab/XbeeMav/tree/master/Resources/Fig1.png "Fig.2"
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The communication between both drones is performed with Xbees. The “xbee_mav” node (**Fig.2**) will handle all communications with other ROS nodes (test_controller(Flight Controller) or test_buzz (ROS Buzz)) and the connected Xbee device. Therefore, both Xbees must be configured for Digi-Mesh with the maximum baud rate (230400).
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We recognize two modes of communications:
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