A cluster of literals in a boolean expression forms a minterm or a maxterm only, if there are all literals (variables of the given function or their negation) included in it.

**A minterm is a product of all literals of a function, a maxterm is a sum of all literals of a function.**

In a K-map a minterm or a maxterm marks out only one cell. In a truth table a maxterm or a minterm matches only one row.

The following truth-table corresponds to the given function:

```
index | a | b | c || f(a,b,c) | term matching the row/K-map cell
-------|---|---|---||----------|----------------------------------
0 | 0 | 0 | 0 || 1 | minterm: m0 = (¬a⋅¬b⋅¬c)
1 | 0 | 0 | 1 || 1 | minterm: m1 = (¬a⋅¬b⋅c)
2 | 0 | 1 | 0 || 1 | minterm: m2 = (¬a⋅b⋅¬c)
3 | 0 | 1 | 1 || 1 | minterm: m3 = (¬a⋅b⋅c)
-------|---|---|---||----------|----------------------------------
4 | 1 | 0 | 0 || 1 | minterm: m4 = (a⋅¬b⋅¬c)
5 | 1 | 0 | 1 || 0 | MAXTERM: M5 = (¬a + b + ¬c)
6 | 1 | 1 | 0 || 1 | minterm: m6 = (a⋅b⋅¬c)
7 | 1 | 1 | 1 || 1 | minterm: m7 = (a⋅b⋅c)
```

There is only one maxterm present in the truth table (and your K-map) and the only maxterm determining the function's output as logical 0. It is a valid product-of-maxterms expression, even if there is only one. It is also the same boolean expression as the original one, so that is a valid product-of-maxterms expression too.

**However, this is ***not* a valid sum of minterms, because there is none:

```
f(a,b,c) = ∏(5) = M5 = (¬a + b + ¬c)
```

**For the original expression to be also the sum of minterms, it would need to mark out every single ***true/one* cell in your K-map separately like this:

```
f(a,b,c) = ∑(0,1,2,3,4,6,7) = m0 + m1 + m2 + m3 + m4 + m6 + m7 =
= (¬a⋅¬b⋅¬c)+(¬a⋅¬b⋅c)+(¬a⋅b⋅¬c)+(¬a⋅b⋅c)+(a⋅¬b⋅¬c)+(a⋅b⋅¬c)+(a⋅b⋅c)
```

**As you can see, even if these two boolean expressions are equivalent to each other, the original one (on the left side of the equation) is not written as the sum-of-minterms expression (on the right side of the equation).**

```
(¬a+b+¬c) = (¬a⋅¬b⋅¬c)+(¬a⋅¬b⋅c)+(¬a⋅b⋅¬c)+(¬a⋅b⋅c)+(a⋅¬b⋅¬c)+(a⋅b⋅¬c)+(a⋅b⋅c)
```

*Just any* product is *not* a minterm, so the original expression could be in the form of both the product of sum and the sum of products, but not the valid sum-of-minterms.

```
f(a,b,c) = (¬a + b + ¬c) = (¬a) + (b) + (¬c)
```

In the picture (created using latex) you can see the expression – it is the same in it's minimal DNF and minimal CNF – and the sum of minterms equivalent to it.