Dashboard for RaspPi-controlled toy sailboat with Node-RED

Sail Away

© Lead Image © shamain, 123RF.com

© Lead Image © shamain, 123RF.com

Article from Issue 215/2018
Author(s):

With Node-RED, you can create a web dashboard that instructs a Raspberry Pi to set the rudder position on a toy sailboat.

My daughters and I have built a number of toy boat projects with an assortment of Arduino, ESP8266 (WiFi), Bluetooth, and radio frequency interference (RFI) components, but the version we created for this article using a Raspberry Pi and Node-RED [1] offers one of the simplest solutions. The sailboat uses a basic catamaran design with a Raspberry Pi mounting inside a waterproof container. With Node-RED dashboards, you can control the sailboat's rudder from a smartphone. The complete Node-RED logic comprises only six nodes.

Building the Sailboat

Of the many different building materials from which you could choose, K'Nex construction pieces [2] are lighter than either Lego or Meccano, and they allow you to create reasonably large structures with a minimum number of pieces. If you do not have access to K'Nex pieces, popsicle sticks and cardboard would offer a good low-cost solution.

To build the sailboat we used:

  • K'Nex building pieces
  • Four plastic bottles
  • Small plastic container with a lid
  • String
  • Duct tape
  • Garbage bag
  • Low-torque servo
  • Raspberry Pi Zero W or 3
  • Small USB phone charger

The base of the sailboat was a rectangular structure with 16 water-facing K'Nex pieces that allowed plastic bottles to be duct-taped in place (Figure 1). A few K'Nex pieces created a compartment for the servo, and wire secured the servo in place. A rudder was built by screwing a small piece of wood into the servo arm (Figure 2). A garbage bag was cut to the required size and taped to the mast to form a sail. The boom had a swivel connection to the mast and guide ropes connected to both the boom and mast (Figure 3).

Figure 1: Sailboat base.
Figure 2: Servo and rudder mounting.
Figure 3: Sailboat top view.

Servo and Rudder

Only very low torque servos can be connected directly to Raspberry Pi GPIO pins (Figure 4). An example of a low-torque servo would be the TowerPro SG90 [3] ($4), which has a torque of 25 oz/in (1.80 kg/cm). If you have servos with greater torque, you will need to use either a custom Raspberry Pi servo hat (there are some good ones on the market) or a separate power and ground circuit for the servo.

Figure 4: Raspberry Pi Zero W servo circuit.

The WiringPi gpio tool can be used to control the servo. This package is pre-installed on the Raspbian image, or it can be installed manually by entering:

sudo apt-get install -y wiringpi

Servos typically want a pulse frequency of 50Hz; however, the Raspberry Pi pulse width modulation (PWM) pins have a frequency of 19,200Hz, so some range definitions and scaling are required:

gpio -g mode 18 pwm  #define pin 18 as the PWM pin
gpio pwm-ms  # use "mark space" mode
gpio pwmc 192  # set freq as 19200
gpio pwmr 2000  # use a range of 2000

The gpio pwm commands are not persistent after a reboot. A simple solution for this problem is to put the above commands in the Pi user login file $HOME/.bash_login.

After running the PWM setup commands, you need to do some manual testing to define your various rudder (servo) positions (Figure 5), such as Hard Left, Hard Right, Easy Left, Easy Right, and Straight. The pwm timing numbers will vary according to your requirements and the positioning of the servo arm. We used the commands

gpio -g pwm 18 200 #straight
gpio -g pwm 18 260 #hard left
gpio -g pwm 18 140 #hard right
gpio -g pwm 18 230 #easy left
gpio -g pwm 18 170 #easy right

for our sailboat.

Figure 5: Servo/rudder settings.

Node-RED Logic and Dashboards

Node-RED is pre-installed on the Raspbian image, but it will need to be set to autostart on a Pi reboot with:

sudo systemctl enable nodered.service

The Node-RED web interface for configuration is accessed at http://localhost:1880 or http://<pi_ip_address>:1880. Selecting View | Dashboard brings up the options button on the far right (Figure 6), where you can define and change the web dashboard layout. To create logic, nodes are selected from the left node panel and dragged and dropped onto the center flow panel. Logic flow is then created by clicking and joining together the inputs and outputs on the nodes [4]. When a dashboard node is dropped onto the flow panel, it is added to the default web dashboard.

Figure 6: Node-RED dashboard layout.

To call the gpio -g pwm command, use the exec node (Figure 7). The button dashboard node will pass the defined payload value (e.g., a 260 is passed when the Hard Left button is pushed). The button's payload value is appended to the exec command to make a complete servo position command.

Figure 7: Node-RED logic.

Once you have completed your logic setup, press the Deploy button on the top right to make your configuration live and ready to test.

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