The supplied code does not allow you to choose the symbol or list of symbols for the variables that are put in the logic operation. It instead just constructs a list of variables of the form `{A[1],...,A[n]}`

.

A minimal modification of the code to allow for a user supplied list of variables (and some basic argument checking) is something like

```
TruthTable[op_, n_Integer?Positive, symbs_List] := Module[{
l = Flatten[Outer[List, Sequence @@ Table[{True, False}, {n}]], n - 1]},
DisplayForm[GridBox[Prepend[Append[#, op @@ #] & /@ l,
Append[symbs, op @@ symbs]], RowLines -> True,
ColumnLines -> True]]] /; Length[symbs] == n
TruthTable[op_, n_Integer?Positive, symb_String: "A"] :=
TruthTable[op, n, Array[Symbol[symb], n]]
```

The first definition will print the truth table for any given list of variables (can be any expression, but simple symbols or strings look the most sensible). The second definition works exactly like the original code you supplied if given two arguments, the optional third argument is the string from which to construct the symbol used in the truth table.

Then the nand truth table can be printed as

```
TruthTable[Not[And[#1, #2]] &, 2, {P, Q}]
```

It looks slightly better in `TraditionalForm`

```
TruthTable[Not[And[#1, #2]] &, 2, {P, Q}] // TraditionalForm
```

Or even neater if you use the built-in `Nand`

operator (which is just a pretty form of `Not[And[##]]&`

)

```
TruthTable[Nand, 3, {P, Q, R}] // TraditionalForm
```

On reflection, the integer argument `n`

in the `TruthTable`

function might be a little redundant if you're supplying an explicit list of variables. I leave it as an exercise to the reader to modify the function so that it works without it... :)