OpenPLC-with-LDmicro/C2/OpenPLC-Traffic-Light-and-Switchboard-Modules/English

From Script | Spoken-Tutorial
Revision as of 10:17, 30 June 2021 by Priyanka.guntaka123 (Talk | contribs)

(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to: navigation, search
VISUAL CUE NARRATION
Slide 1: Welcome Slide Welcome to the spoken tutorial on OpenPLC Traffic Light & Switchboard modules.
Slide 2: Learning Objectives
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
In this tutorial, we will learn about
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
Slide 3: System Requirements
  • Ubuntu Linux 18.04 operating system
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
  • OpenPLC Mainboard
  • 24V, 2A SMPS
To record this tutorial I am using:
  • Ubuntu Linux 18.04 operating system
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
  • OpenPLC Mainboard
  • 24V, 2A SMPS
Slide 4: Pre-requisites
  • To follow this tutorial, you should know about OpenPLC Mainboard.
  • If not, please refer to the relevant tutorials in this series on this website.
First we will learn about the OpenPLC Traffic light module.
Slide 5: Traffic Light module

This module is used to

  • implement the working of traffic lights
  • visualize the status of any process with the built-in LEDs

This module is used to

  • implement the working of traffic lights and
  • visualize the status of any process with the built-in LEDs.
Traffic.jpg This is a picture of the Traffic light module.

This module replicates a traffic light.

It has one red LED marked as STOP and one yellow LED marked as READY.

At the bottom, it has 3 green LEDs marked as LEFT, GO and RIGHT.

led-connectors.png You can access all these LEDs using the connectors present below.
traffic-sled.png or (traffic.jpg) The red LED can also be accessed through the two connectors on the right of it.

If you want to use a single LED you can use these connectors.

Let us see how to do simple experiments using a single LED.
traffic.jpg The anode and cathode of the red LED are given as connectors to the right of it.

The anode is marked as +5V and cathode as GND, which is Ground.

These connectors can be connected in 3 different ways.

We will see one by one.

traffic.jpg We can connect +5V pin to 5V and GND pin to any I/O pin of the microcontroller.
traffic.jpg Connect GND pin to 0V and +5V pin to any I/O pin of the microcontroller.
traffic.jpg Otherwise connect both +5V and GND pins to the I/O pins of the microcontroller.
Led-connectors.png

traffic.jpg image

We will see how to use LEDs with the connectors at the bottom of the module.

Each LED’s cathode is taken out through the connectors at the bottom of the module.

Note that the rightmost pin marked as ‘EN’ is not an LED connector.

Led-connectors.png

traffic.jpg image

Each connector is marked with the first letter of the respective LED name.

We will see one by one starting from right.

  1. Ri is for green LED marked as RIGHT
  2. S is for red LED marked as STOP
  3. Re is for yellow LED marked as READY
  4. G is for green LED marked as GO
  5. L is for green LED marked as LEFT.
traffic-enable.png ‘EN’ is an active low enable pin which enables all the LED pins.

To the left of the yellow LED, we can find a connector marked +5V.

This is the power pin of the module.

That is, none of the LED glows unless you make these two connections.

Slide 6: LED to glow
  • +5V pin should be given 5V.
  • EN and the respective LED pin should be grounded or given a logic-low signal.
Therefore, for any LED to glow you should follow the below:
  1. +5V pin should be given 5V.
  2. EN and the respective LED pin should be grounded or given a logic-low signal.
Now we’ll see the working of the module.
Slide 7: How can the Traffic Light module be powered?

Traffic Light module can be powered using the output power pins of the Mainboard

How can the Traffic Light module be powered?

It can be powered using the output power pins of the Mainboard.

SMPS-Mainboard.jpg - add in editing Connect the SMPS to the Mainboard as shown here.
led-connectors.png First we will see the demo of this module using the connectors available at the bottom.
demo1.png

Point to the image as per narration

Connect 5V to the power pin i.e. +5V pin to the left of the yellow LED.

Connect 0V to the ‘EN’ pin.

Then, connect 0V to any of the LEDs.

I’m connecting it to the pins marked ‘G’, ‘Re’ and ‘S’.

demo1.png Make the connections as shown in the picture.

Remember to turn off the power supply when you change or make new connections.

Turn on the power supply After making all the connections turn on the power supply of the Mainboard.

The red, yellow and middle green LED has started glowing.

Do not use I/O pins of the Mainboard to power up the pin marked +5V.

Because it may affect the intensity of the LED.

Disconnect the ‘EN’ pin Now disconnect the ‘EN’ pin.

We can observe that all LEDs go off.

Turn off the power supply Turn off the power supply.
traffic-sled.png Next, we will see the demo on how to use this module when a single LED is needed.
demo2.png Connect 5V to the +5V pin on the right of the red LED.

Connect 0V to the pin marked GND.

Turn on the power supply Turn on the power supply.

This will make only the red LED to glow.

Thus, there is no need to connect power and enable pins for this connection.

Turn off the power supply Turn off the power supply.
We have seen how Traffic light module can be used in different ways.
Now we’ll learn about the OpenPLC Switchboard module.
Slide 5: Switchboard module
  • The goal of this module is to get familiarized with different types of switches
  • In particular their usage in the real time applications in industries

The goal of this module is to get familiarized with different types of switches.

In particular their usage in the real time applications in industries.

Slide 6: Main Components
  • 4 Normally Open switches
  • 4 Normally Closed switches
  • 2 Latched action switches and
  • LEDs for each switch
This module has
  • 4 Normally Open switches
  • 4 Normally Closed switches
  • 2 Latched action switches and
  • LEDs for each switch
switchboard.jpg This is the Switchboard module.
Slide 7: Types of Switches:
  • Normally open (NO)
  • Normally closed (NC)
  • Latched action (L)
In this module, there are three kinds of switches available.

They are Normally Open, Normally Closed and Latched action switches.

Normally Open is represented as NO and Normally Closed is represented as NC.

Latched action switches are represented as L.

SB-switches.png We will now look at their arrangement on the module from bottom to top.
SB-switches.png

Highlight Latch switches

Then NC and then NO

At the bottom, we have two Latched action switches.

Above that we have 4 Normally Closed and then 4 Normally Open switches.

SB-leds.png Above these switches we have LEDs corresponding to each switch.

The LEDs are arranged in the same order as that of switches.

Each LED glow indicates a corresponding switch press.
SB-connectors.png On the top we have female berg connectors for connections.
SB-connectors-z.png

Point to each particular pin

Next, we will see about the pins.

Starting from the right, the first two pins are GND and 5V respectively.

These are the input power pins of this module.

Then we have 4 pins for 4 NO switches and 4 pins for 4 NC switches.

The last 2 pins are for 2 latched action switches.

Slide 8: Important Note
  • NO and latched action switches must be connected to the I/Os of the microcontroller
  • Only then the LEDs of the corresponding switches will work
  • LEDs of NC switches will work, even if they are not connected to I/Os
NO and Latched action switches must be connected to the I/Os of the microcontroller.

Only then the LEDs of the corresponding switches will work.

LEDs of NC switches will work, even if they are not connected to the I/Os of the microcontroller.

Now, we’ll learn how each type of the switch works.
Slide 9: Normally Open Switch
  • The output pin of a NO switch will read logic 0 when it is not pressed
  • When the switch is pressed, the output pin will read 5V
  • This is due to the supply from the microcontroller’s internal pull up register
The output pin of a NO switch will read logic 0 when it is not pressed.

When the switch is pressed, the output pin will read 5V.

This is due to the supply from the microcontroller’s internal pull up register.

Slide 10: Normally Closed switch
  • The output pin of a NC switch will read 5V when it is not pressed
  • This is due to the supply from the microcontroller’s internal pull up register
  • Upon switch press, the output pin will read logic 0 or ground
The output pin of a NC switch will read 5V when it is not pressed.

This is due to the supply from the microcontroller’s internal pull up register.

Upon switch press, the output pin will read logic 0 or ground.

Slide 11: Latched action switch
  • It is basically a push-to-make, push-to-break type of switch
  • That is, the output pin will read 5V, when it is pressed for the first time
  • The output pin will read 0V, when it is pressed for the second time
Latched action switch is basically a push-to-make, push-to-break type of switch.

That is, the output pin will read 5V, when it is pressed for the first time.

The output pin will read 0V, when it is pressed for the second time.

Working of the LED of a latched action switch corresponds to that of a NO switch.

Slide 12: How can the Switchboard module be powered?

Switchboard module can be powered using the output power pins of the Mainboard

How can the Switchboard module be powered?

It can be powered using the output power pins of the Mainboard.

We have learnt about the different types of switches in the Switchboard module.
Using these modules we will learn about LDmicro instructions on OpenPLC in future tutorials.
This brings us to the end of this tutorial.

Let us summarize.

Slide 8: Summary
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
In this tutorial, we learnt about
  • OpenPLC Traffic light module
  • OpenPLC Switchboard module
Slide 9: About

Spoken Tutorial project

The video at the following link summarises the Spoken Tutorial project.

Please download and watch it

Slide 10:

Spoken Tutorial workshops

The Spoken Tutorial Project team:
  • conducts workshops using spoken tutorials and
  • gives certificates on passing online tests.

For more details, please write to us.

Slide 11:

Forum for specific questions:

Please post your timed queries in this forum.
Slide 12:

Forum for specific questions:

Do you have any general / technical questions on OpenPLC?

Please visit the FOSSEE forum and post your question.

Slide 13:

Acknowledgement

Spoken Tutorial Project is funded by MHRD, Government of India.
Slide 14:

Thank you slide

This tutorial has been contributed by FOSSEE and Spoken Tutorial Project, IIT Bombay.

And this is Harsha Priyanka from the FOSSEE team, signing off.

Thanks for watching.

Contributors and Content Editors

Nirmala Venkat, Priyanka.guntaka123