One way to achieve this is to define your own matrix *wrapper*. The wrapper approach has the advantage that you can overload as many built-in functions as you like without impacting any other functionality.

Let's start by defining a wrapper called `myMatrix`

that displays itself using `MatrixForm`

:

```
Format[myMatrix[m_]] ^:= MatrixForm[m]
```

Next, we'll overload the `Times`

operator when it acts on `myMatrix`

:

```
myMatrix[m1_] myMatrix[m2_] ^:= myMatrix[Inner[And, m1, m2, Or]]
```

Note that both definitions use `^:=`

to attach the rules to `myMatrix`

as up-values. This is crucial to ensure that the regular built-in definitions are otherwise unaffected.

Armed with these definitions, we can now achieve the desired goal. To demonstrate, let's define two matrices:

```
m1 = myMatrix[Array[Subscript[a, Row[{##}]]&, {2, 2}]]
```

```
m2 = myMatrix[Array[Subscript[b, Row[{##}]]&, {2, 2}]]
```

The requested "explicitly viewable form" can now be generated thus:

```
Row[{m1, m2}] == m1 m2
```

... or, if you prefer to reference `Times`

explicitly on the left-hand side of the equation:

```
With[{m1 = m1, m2 = m2}, HoldForm[m1 m2] == m1 m2]
```

Next, we'll assign random boolean values to each of the matrix elements:

```
Evaluate[First /@ {m1, m2}] = RandomInteger[1, {2, 2, 2}];
```

... and then generate the explicitly viewable form once again with the assignments in place:

```
With[{m1 = m1, m2 = m2}, HoldForm[m1 m2] == m1 m2]
```