Today we’ll explain how to exploit the potential of Arduino as a programmable logic controller, connecting it to appropriate interfaces for I/O.

The PLC (Programmable Logic Controller) has been and still is the basic component of the industrial automation world. The Industrial application made the PLC systems being very expensive, both to buy and repair, and also because of the highly specific skills requested to software designers to extract the maximum potentials from controllers. Arduino is a kind of universal programmable controller, although it is only the “core” and in any case it has been built for general applications; with a little of external hardware (essentially interfaces capable of transferring signals from sensors and to actuators, reducing the EMI which may damage the microcontroller) and an appropriate software may, however, become something very similar to a PLC.

In this tutorial we will explain how to “convert” our Arduino board in a PLC-like controller, programmable through the PLC proprietary language and logic, helping those who wish to start studying this fascinating world without spending a bunch of money on materials and training.

To turn Arduino into a Programmable Logic Controller, there are two approaches. The first one is to write our program using KOP language (ladder). To do that, we must use two more applications in addition to Arduino IDE: the first is LDmicro that is the editor and compiler of our ladder code (it can be downloaded from http://cq.cx/dl); the second consists of a web page that will help us creating the code for the ladder.h library (http://adam.horcica.cz/tools/ladder-gen); for simplicity’s sake, in this guide we’ll consider only the DIGITAL I / O with no special features. The second method is to use plcLIB (a library we suitably modified to take advantage of the IO shield coupled with Arduino UNO) so that you can edit our project code with a language similar to AWL (instructions: IF, AND, OR, …) having the control on timers and other functions; Here, too, our attention will be focused exclusively on using digital I / O without dealing with specific functions.

A practical example

As an example to understand how to take full advantage of the two methods described above, we will try to solve a problem of home automation found on the web: automate electric sunshades. Then we will proceed with a step-by-step explanation of the two methods described above. Briefly, we want to control the sunshades so that in case of a strong wind they must be automatically retracted, while unrolled only after the wind has calmed down. The behavior should be similar for the different lighting situations: roll them during the night and unroll on daylight, but obviously the wind conditions should prevail over the lighting.

As a possible solution we could use a real PLC, but given the simplicity of the algorithm and the high cost of that PLC, we will use the hardware shown above.

We will use two sensors, twilight NO (normally open) and wind NO that will be connected to the IO shield. In addition, we will have to adapt and change the power scheme of the sunshades engines so that Arduino could manage them.

Method 1: LDmicro











Before writing the ladder code (contact diagram), similar to that in figure, we need to download the LDmicro executable from the link http://cq.cx/ladder.pl. Once downloaded and saved to your desktop, just double click on the LDmicro icon. Now, before proceeding with the application of ladder diagram, we have to write a draft of the program that we want to create.

Since the program is very simple and we use few variables only, we can use the most basic and immediate programming approach for the PLC: the wired logic. This methodology consists of simple Boolean equations that will always return as output (after the equal sign) a value that can be 0 or 1. The only operators used will be the AND (series), the OR (parallel) and NOT (negation).

Input and Output variables in our program shall be the following:

– INPUT:

WIND SENSOR: XSEN_VENTO

LIMIT SWITCH ROLL: XFINE_COR_A

LIMIT SWITCH UNROLL: XFINE_COR_S

TWILIGHT SWITCH: XIN_CREP

– OUTPUT:

ROLLER: YAVVOLG

LED ROLLER: YL_AVV

UNROLLER: YSVOLG

LED UNROLLER: YL_SVO

IDLE STATE: YL_RIP

Note that the Arduino output pins have not yet been declared yet, while the “x” and “y” placed at the beginning of each variable represent respectively the input and the output. The software adds this letter automatically during the coding.











Once declared the variables, we can proceed on writing the logic equations, taking into account that Arduino with our shield reads all inputs as HIGH (1) when the contact is open and LOW (0) when the contact is closed: therefore we must negate the logic of all the inputs to ensure that they are properly executed.

Now that we have our Boolean equations, we can back to LDmicro. By pressing the “C” key or clicking on the “instruction->include contact” menu, we get the inclusion of an open contact. Now, without changing anything, by pressing “L” on keyboard (after placing the cursor after Xnew, on the right side), we should obtain a segment identical to that of figure.

Moving the cursor below Xnew (by using the arrow keys on keyboard) and pressing “C”, we will get a new segment, always named Xnew but in parallel with the previous one; now, we must click on Ynew and putting the cursor vertically on the left (before) of the output, we have to press “C” twice. By doing this we have added two more contacts, in series with the two (parallel) previous ones. To finish up, we just need to click on Ynew (but this time positioning the cursor below the output symbol) and then press “L”: so we have added another output in parallel to the existing Ynew.

Now we need to modify all contact names accordingly to those used in the equations. To do this we simply double click on the first Xnew contact we have created, then we set the name and contact type in the pop-up shell. We will assign the name “SEN_VENTO” and select “INPUT PIN” and “|/| NORMALMENTE CHIUSO” (NC). Remember that the software automatically assign the initial letter “X” or “Y” whether the variable stands for INPUT or OUTPUT, respectively.

The whole procedure shall be repeated for all the remaining contacts and equations.

To insert a new segment, click on “Edit->Insert segment behind”. After having completed the configuration, from the menu “settings” we shall select “Microcontroller->ANSI C Code”, then we can compile choosing from menu “Compile->Compile as”.

We choose to save the file on “Desktop” with these settings:

Save as: All Files

Filename: ladder.cpp

After saving the file, a popup windows will warn us to configure the I/O addresses map: we click on “OK”, save our LDmicro project (menu File->save as) always on Desktop naming it as “ladder.ld”.

Then we need one-step further. Open the ladder.cpp file with notepad, select all the text and copy paste it on the website http://adam.horcica.cz/tools/ladder-gen. After clicking on “Generate”, we will get a new code. Copy and paste this code to a new notepad file, saving it with the following parameters:

Save as: All Files

Filename: ladder.h

In this exercise, we have chosen to set the pin configuration as follows:

pinMode(2, INPUT);

pinMode(3, INPUT);

pinMode(4, INPUT);

pinMode(5, INPUT);

pinMode(8, OUTPUT);

pinMode(9, OUTPUT);

pinMode(10, OUTPUT);

pinMode(11, OUTPUT);

pinMode(12, OUTPUT);

Then we can modify the “ladder.h” library with this pinout setting, as shown in “Code listing 1” (the code lines highlighted in yellow are the ones to be modified, without affecting the remaining parts)

/* This is autogenerated code. */ /* (generated Wed, 13 Nov 2013 14:06:53 +0100 by ladder-gen v 1.0) */ #ifndef LADDER_H #define LADDER_H #if ARDUINO >= 100 #include "Arduino.h" #else #include "WProgram.h" #endif #define BOOL boolean #define SWORD int #define EXTERN_EVERYTHING #define NO_PROTOTYPES void PlcCycle(void); /* Configure digital I/O according to LD (call this in setup()). */ inline void PlcSetup() { pinMode(2, INPUT); pinMode(3, INPUT); pinMode(4, INPUT); pinMode(5, INPUT); pinMode(8, OUTPUT); pinMode(9, OUTPUT); pinMode(10, OUTPUT); pinMode(11, OUTPUT); pinMode(12, OUTPUT); } /* Individual pins (this code is used in ladder.cpp) */ inline extern BOOL Read_U_b_XSEN_VENTO(void) { return digitalRead(2); // TODO } inline extern BOOL Read_U_b_XIN_CREP(void) { return digitalRead(5); //TODO } inline extern BOOL Read_U_b_XFINE_COR_A(void) { return digitalRead(3); //TODO } inline BOOL Read_U_b_YL_SVO(void) { return digitalRead(11); //TODO } inline void Write_U_b_YL_SVO(BOOL v) { digitalWrite(11, v); //TODO } inline BOOL Read_U_b_YAVVOLG(void) { return digitalRead(8); //TODO } inline void Write_U_b_YAVVOLG(BOOL v) { digitalWrite(8, v); //TODO } inline BOOL Read_U_b_YL_AVV(void) { return digitalRead(9); //TODO } inline void Write_U_b_YL_AVV(BOOL v) { digitalWrite(9, v); //TODO } inline extern BOOL Read_U_b_XFINE_COR_S(void) { return digitalRead(4); //TODO } inline BOOL Read_U_b_YSVOLG(void) { return digitalRead(10); //TODO } inline void Write_U_b_YSVOLG(BOOL v) { digitalWrite(10, v); //TODO } inline BOOL Read_U_b_YL_RIP(void) { return digitalRead(12); //TODO } inline void Write_U_b_YL_RIP(BOOL v) { digitalWrite(12, v); //TODO } #endif 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 /* This is autogenerated code. */ /* (generated Wed, 13 Nov 2013 14:06:53 +0100 by ladder-gen v 1.0) */ #ifndef LADDER_H #define LADDER_H #if ARDUINO >= 100 #include "Arduino.h" #else #include "WProgram.h" #endif #define BOOL boolean #define SWORD int #define EXTERN_EVERYTHING #define NO_PROTOTYPES void PlcCycle ( void ) ; /* Configure digital I/O according to LD (call this in setup()). */ inline void PlcSetup ( ) { pinMode ( 2 , INPUT ) ; pinMode ( 3 , INPUT ) ; pinMode ( 4 , INPUT ) ; pinMode ( 5 , INPUT ) ; pinMode ( 8 , OUTPUT ) ; pinMode ( 9 , OUTPUT ) ; pinMode ( 10 , OUTPUT ) ; pinMode ( 11 , OUTPUT ) ; pinMode ( 12 , OUTPUT ) ; } /* Individual pins (this code is used in ladder.cpp) */ inline extern BOOL Read_U_b_XSEN_VENTO ( void ) { return digitalRead ( 2 ) ; // TODO } inline extern BOOL Read_U_b_XIN_CREP ( void ) { return digitalRead ( 5 ) ; //TODO } inline extern BOOL Read_U_b_XFINE_COR_A ( void ) { return digitalRead ( 3 ) ; //TODO } inline BOOL Read_U_b_YL_SVO ( void ) { return digitalRead ( 11 ) ; //TODO } inline void Write_U_b_YL_SVO ( BOOL v ) { digitalWrite ( 11 , v ) ; //TODO } inline BOOL Read_U_b_YAVVOLG ( void ) { return digitalRead ( 8 ) ; //TODO } inline void Write_U_b_YAVVOLG ( BOOL v ) { digitalWrite ( 8 , v ) ; //TODO } inline BOOL Read_U_b_YL_AVV ( void ) { return digitalRead ( 9 ) ; //TODO } inline void Write_U_b_YL_AVV ( BOOL v ) { digitalWrite ( 9 , v ) ; //TODO } inline extern BOOL Read_U_b_XFINE_COR_S ( void ) { return digitalRead ( 4 ) ; //TODO } inline BOOL Read_U_b_YSVOLG ( void ) { return digitalRead ( 10 ) ; //TODO } inline void Write_U_b_YSVOLG ( BOOL v ) { digitalWrite ( 10 , v ) ; //TODO } inline BOOL Read_U_b_YL_RIP ( void ) { return digitalRead ( 12 ) ; //TODO } inline void Write_U_b_YL_RIP ( BOOL v ) { digitalWrite ( 12 , v ) ; //TODO } #endif

Once you changed the library as just shown, we save the changes without modifying neither the name nor the file extension, keeping it always on your “Desktop”.

At this time we need to create the file “pinmap.ini”. In this file, we have to declare the names of our variables and the respective pins. This step may also be skipped but we do not guarantee proper operation of the program without.

The changes to this file are closely related to our project and must be consistent with the ladder.h code (Listing 2).

; This file contains mapping between variable name in the LD and actual ; pin number of the Arduino. ; SEN_VENTO on pin 2 SEN_VENTO = 2 ; FINE_COR_A on pin 3 FINE_COR_A = 3 ; FINE_COR_S on pin 4 FINE_COR_S = 4 ; IN_CREP on pin 5 IN_CREP = 5 ; AVVOLG on pin 8 AVVOLG = 8 ; L_AVV on pin 9 L_AVV = 9 ; SVOLG on pin 10 SVOLG = 10 ; L_SVO on pin 11 L_SVO = 11 ; L_RIP on pin 12 L_RIP = 12 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 ; This file contains mapping between variable name in the LD and actual ; pin number of the Arduino . ; SEN_VENTO on pin 2 SEN_VENTO = 2 ; FINE_COR_A on pin 3 FINE_COR_A = 3 ; FINE_COR_S on pin 4 FINE_COR_S = 4 ; IN_CREP on pin 5 IN_CREP = 5 ; AVVOLG on pin 8 AVVOLG = 8 ; L_AVV on pin 9 L_AVV = 9 ; SVOLG on pin 10 SVOLG = 10 ; L_SVO on pin 11 L_SVO = 11 ; L_RIP on pin 12 L_RIP = 12

Now we can move our four files 1.”ladder.ld” 2.”ladder.cpp” 3.”ladder.h” 4.”pinmap.ini” to a single folder called “ladder”. Then move this folder to (W7) C: \ programmiX86 \ Arduino \ libraries (or for older editions of Windows (XP) to C: \ Program Files \ Arduino \ libraries).

Open or restart the Arduino IDE and write the following code (NOTE: it is not intended for using of timers or other special functions).

From the menu “SKETCH”, we select “import library” and choose “ladder”. Now, type the following code, which is valid for all projects similar to this:

#include <ladder.h> void setup() { PlcSetup(); } void loop() { PlcCycle(); delay(10); } 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 #include <ladder.h> void setup ( ) { PlcSetup ( ) ; } void loop ( ) { PlcCycle ( ) ; delay ( 10 ) ; }

Now, please click on the “verification check” of our code and wait until the sketch has been compiled. We should get a positive result, if not please follow again the instructions above systematically.

After the compilation is finished you can click on the icon on the side, to transfer our program to Arduino; wait until it’s loaded and … Congratulations: you’ve managed to turn your Arduino into a controller very similar to its rival PLC. Now you just have to interface your system, respecting the logic that we have established for inputs and outputs.

Attention: When you create a new project, before importing the new folder (whose name must always be “ladder” and it shall contain the files with the same name as before), you must remove from the directory the previous project folder. In case you want to keep it, just rename it and save it in another directory. If you want to restore it, simply call it “ladder” and repeat the process in reverse.

For more information and further clarifications, please connect to the site http://electronics4dogs.blogspot.it/2011/07/ldmicro-and-arduino.html

Methodology 2: plcLIB

To follow this approach you must download the suitably modified library from our website.

The plcLIB library that we have modified to optimally interface the IO shield with Arduino UNO, is dedicated to those who want to start studying the world of automation without having to “hack” the code too.

Simply download from our website the library plcLIB and once unzipped, paste the folder in “C:\programmiX86\arduino\libraries” for Windows 7 or to “C:\ program files\arduino\libraries” for older Windows versions (XP).

Even in this case, our discussion will be mainly focused on digital logic without using special functions even if, respect to LDmicro example above, in this case we could easily take advantage of certain features such as timers.

Once you have imported our library as described above we will not have to change it, regardless of the project we are going to realize. Just edit our code taking into consideration some factors:

The digital I / Os must follow the naming shown on table.

By reusing the Boolean equations listed above, we write our code in the Arduino IDE: in this way, i.e. considering them as real equations respecting the order of operators (calculating parenthesis first and then the rest).

#include <plcLib.h> void setup() { setupPLC(); } void loop() { inNot(X1); orNotBit(X4); andBit(X2); andNotBit(Y4); out(Y1); in(Y1); out(Y2); in(X4); andBit(X3); andNotBit(Y2); andBit(X1); out(Y3); in(Y3); out(Y4); inNot(Y2); andNotBit(Y4); out(Y5); } 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 #include <plcLib.h> void setup ( ) { setupPLC ( ) ; } void loop ( ) { inNot ( X1 ) ; orNotBit ( X4 ) ; andBit ( X2 ) ; andNotBit ( Y4 ) ; out ( Y1 ) ; in ( Y1 ) ; out ( Y2 ) ; in ( X4 ) ; andBit ( X3 ) ; andNotBit ( Y2 ) ; andBit ( X1 ) ; out ( Y3 ) ; in ( Y3 ) ; out ( Y4 ) ; inNot ( Y2 ) ; andNotBit ( Y4 ) ; out ( Y5 ) ; }











Once you have edited this code, simply click on Verify and wait for the IDE to compile the sketch: we should get a positive result, otherwise revise the instructions step-by-step. Once the compilation is complete click on “Upload” to program the Arduino. Wait until the loading is completed and CONGRATULATIONS! You have turned your Arduino to PLC.

Warning: This library has been modified and tuned by us to take advantage of the Arduino UNO digital I/O. In addition, for a new project, you should only change the code enclosed in the void loop () {…}, maintaining unchanged the previous part. You can save your sketch without changing the library: an operation very advantageous from a practical and timesaving point of view respect to the LDmicro example. With this method, you cannot use the GUI “LADDER” but you can fully exploit the logic of plc, with a considerable saving of time and reducing the risk of compilation errors or code mismatches without the need to switch to other software. In fact, a good programmer is someone who is able to create a good product regardless of the SDK or GUI he is using: the important thing is that the algorithm logic is always the same.

More information: please note that the pins mapping of our library has been modified to interface with the IO shield and Arduino UNO. The notions taken from this site are valid only if you used the original library found at the link below so that all special functions are available and explained. Our library has been adapted for the IO shield, so some features that you might find at the link below might not work properly due to the adaptation done, and then we do not guarantee the proper working of all the functions mentioned by “electronics”. However, we guarantee that the timerOn function works fine (we tested it successfully). If you wish to try all the other functions, you may download the original library and follow the step-by-step instructions from the linked website.

Here an example of the use of timers.

unsigned long TIMER0 = 0; void setup() { setupPLC(); } void loop() { in(X1); timerOn(TIMER0, 2000); out(Y1); } 1 2 3 4 5 6 7 8 9 10 11 unsigned long TIMER0 = 0 ; void setup ( ) { setupPLC ( ) ; } void loop ( ) { in ( X1 ) ; timerOn ( TIMER0 , 2000 ) ; out ( Y1 ) ; }

unsigned long TIMER0 = 0;

void setup() {

setupPLC();

}

void loop() {

in(X1);

timerOn(TIMER0, 2000);

out(Y1);

}

Learn more and download the original library plcLIB without our changes (here is their link):

– www.electronics-micros.com/software-hardware/plclib-arduino/

– www.electronics-micros.com/resources/arduino/plclib/plcLib.zip.

In figure, you see the wiring diagram of sensors and the motor of the sunshade (220V single-phase motor with two-way rotation versus). NOTE: Since the wiring diagram have been used for potentially hazardous voltages, we take no responsibility in case of accident, injury to persons or property resulting from a misinterpretation of the wiring diagram or by any inopportune change from your side.

Method 2b: plcLIB ANALOG-DIGITAL

To follow this example, please download a library that was suitably modified.

In this section, we deviate a little from the world of electrical engineering and automation PLCs and take a step towards electronics. We propose a second plcLIB library we suitably modified to take advantage of our IO shield so to have three digital inputs, three PWM outputs, six inputs and six analog outputs.

Unzip the file PlcLIB.zip and copy the folder to the directory “….\arduino\libraries”

Attention: If you installed the library indicated in the previous path, you have to cut and paste it into another directory to avoid conflicts with this (keep it if you want to create a purely digital project, you shall use the library specified in the methodology 2). In case you want to build a prototype that integrates both digital and analog/PWM controls, use the library indicated in this paragraph.

Table shows the mapping of inputs and outputs adapted to our IO board.

We remind you that on analog inputs, the maximum voltage and current allowed are 5V 100mA.

Here is an example application; we want to dim a led (L1; AY1) according to the value assumed by potentiometer (R1; AX1) in real time.

The Arduino solution, easily understandable after studying previous paragraph, is shown on listing:

#include <plcLib.h> void setup() { setupPLC(); } void loop() { inAnalog(AX1); outPWM(AY1); } 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 #include <plcLib.h> void setup ( ) { setupPLC ( ) ; } void loop ( ) { inAnalog ( AX1 ) ; outPWM ( AY1 ) ; }

After verifying the code, we can upload to Arduino and…. Good job! You succeeded in interfacing the analog world with Arduino-based PLC!!

From Store

Arduino UNO

Input/Output shield KA05