Thursday 28 August 2014

Fundamental concept of PLC - Boolean Algebra

AND, OR and NOT

Life is full of decisions. What is true for us is also true of PLCs. We gather information (input) and based on that we make choices that determine our output. All though I've always found computers to be quite a bit more logical then human beings.

For an example of how we use logic in everyday life consider these statements:

If Tommy OR Bob want to play basketball then I'll play too.
It's 6 o'clock AND I'm NOT hungry therefore I'm going to keep playing.
If Mom comes out AND orders me inside OR it get's dark then I'll stop playing.

Now these are pretty simple decisions especially if you're a ten year old boy.  You'll notice that they all involve three types of comparisions: AND, OR and NOT.  Now we could get more complex but all that we'd be doing is using these simple building blocks.

In the world of automation these types of TRUE or FALSE conditions come down to a device being ON or OFF, CLOSED or OPEN, PRESENT or ABSENT, 24 VOLTS or 0 VOLTS.  In the PLC it all boils down to our now familiar binary system of a 1 or a 0.  Typically having a bit ON represents a TRUE condition while OFF is FALSE.  This is abitrary though as it may make more sense to use what is called failsafe logic and have an ON bit as a FALSE condition.

Let's turn again to some simple statements but this time using automation examples.

When the button is pressed AND the door is closed then turn on the motor.

If the process is done OR the emergency stop button signal is NOT on then turn off the motor.  (This is an example of a failsafe operation as the emergency stop button could be      pressed or the wire has been disconnected.  In either case we want to check this for safety reasons.  Relying on a signal to turn on when a wire has fallen off long ago may cause an awkward moment when we truly have to stop the machine in an emergency.)

If the tank is full OR the button is pressed AND there are no alarms then start the process.
It would be nice to program like this but computers like to be a little bit more structured.  A series of graphical objects have been used for years to represent these logic elements and they can be easily converted to a common ladder logic equivalent.  These functions are also called gates as they act like gate keepers for different logic. 

The simple switching circuits presented further down should be sufficient to understand practical implementation in hardware of Boolean Algebra. For clarity, we have attached the correspondent firmware/software logic equivalent formulas.
   
  


  
 

BOOLEAN EQUIVALENT OF SWITCHING CIRCUITS
 

CIRCUIT
 
DESCRIPTION
Switching logic

 Fig 1 : 
Function LED

 LED = A * B  (in Boolean hardware)
 is equivalent to:
 LED = A AND B (in firmware logic)
 
Switching logic
 Fig 2 : 
Function LED

 LED = A + B  (in Boolean hardware)
 
LED = A OR B (in firmware logic)
Switching logic
 Fig 3 : 
Function LED

 LED = A * B * (C + D)  (in Boolean hardware)
 
LED = A AND B AND (C OR D) (in firmware logic)
Switching logic

 Fig 4 : 
Function LED

 LED = A * D + B * C (in Boolean hardware)
 
LED = (A AND D) OR (B AND C) (in firmware logic)
Switching logic Fig 5 : Function LED

 LED = A * (B + C) (in Boolean hardware)
 
LED = A AND (B OR C) (in firmware logic)
Switching logic

 Fig 6 : 
Function LED
 
 LED = A * B + A * B 
(in Boolean hardware)

 
LED = (A AND B) OR [(NOT A) AND (NOT B)] (in firmware logic)
 


The NOT function

The simplest of all logic functions is the NOT gate. 


It's sole function in life is to invert of flip the logic state.  So an input of 1 will come out as a 0 and visa versa.  Shown below is a truth table (it doesn't lie) showing all possible inputs and the resulting logical output.
   
Input A
Output 
 0
 1
1
 0


The ladder logic equivalent for a NOT function looks like a normal contact but with a slash through it.




The AND function

The AND gate is associated with the following symbol that can have any number of inputs but only one output.  



The truth table below shows that the output is only turned on when all the inputs are true (1).  An easy way to remember this is AND works like multiplication.

Input A
Input B 
 Output
 0
 0
 0
1
 0
 0
 0
 1
 0
 1
 1
 1

The ladder logic equivalent for an AND function looks like two normal contacts side by side.


The OR function

Last but not least the OR gate is associated with the following symbol that also can have any number of inputs but only one output.  



The truth table below shows that the output is turned on (1) when any of the inputs are true (1).  An easy way to remember this is OR works like addition.

Input A
Input B 
 Output
 0
 0
 0
1
 0
 1
 0
 1
 1
 1
 1
 1

The ladder logic equivalent for an OR function looks like two normal contacts on top of each other.


Combining AND or OR with NOT 
The NOT gate might not look like much help if you haven't programmed much but you'll find yourself actually using it frequently.  It's very common to use it in combination with AND and OR.  So the engineering gods decided to make some symbols for these combinations. 

Putting the NOT and AND gates together forms the NAND gate.The truth table below shows that it is simply an inverted output of the AND gate.

Input A
Input B 
 Output
 0
 0
 1
1
 0
 1
 0
 1
 1
 1
 1
 0

A little circle (or if you like, a bubble) at the end of a AND gate is used to signify the NAND function.  Its symbol and corresponding ladder logic are shown below.  Now pay close attention to the ladder logic because the contacts are in parallel and not in series like the AND function.




Putting the NOT and OR gates together forms... you got it... the NOR gate.  The truth table below shows that it is simply an inverted output of the OR gate.

Input A
Input B 
 Output
 0
 0
 1
1
 0
 0
 0
 1
 0
 1
 1
 0


Again a little circle is placed at the end of an OR gate to signify the NOR function.  Its symbol and corresponding ladder logic are shown below.  The ladder logic is very different from the regular OR gate.


But wait!  Don't order yet... the XOR gate.

So far with our logic gates we've covered almost all possible combinations except for one shown by the truth table below.

Input A
Input B 
 Output
 0
 0
 0
1
 0
 1
 0
 1
 1
 1
 1
 0

The logic to produce this output is called an Exclusive OR gate otherwise known as the XOR gate.  It's a specialized form of the OR gate.  So if either one of the inputs are on then the output is true, otherwise you're out of luck.  The symbol for the XOR gate is shown by added a curved line to the OR gate symbol.




The ladder logic to implement an XOR gate is a little more complex than the others. 




How useful is the XOR logic?  You probably use the XOR gate everyday without thinking about it if you have a room with a light that works off two switches.  If both switches are in the same position then the light will be off.  Therefore just flipping one switch will turn the light on.  In the PLC program this can be extremely useful for programming alternating actions or gray codes.

Ok, there is one more logic gate but I promise it is the last one.  It makes sense that there is a XNOR gate which is the combination of the NOT and XOR logic.  It simply inverts the output of the XOR function.


Input A
Input B 
 Output
 0
 0
 1
1
 0
 0
 0
 1
 0
 1
 1
 1


The symbol for the XNOR gate is shown below along with it's ladder logic equivalent.






While these terms and symbols may seem a bit esoteric for the PLC beginner they are important in the long run.  A good grasp of these essentials will make PLC programming easier, simplier and save memory.  


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