Let's have a look at the definition of a product first:

A product of objects `a`

and `b`

is the object `c`

equipped with morphisms `p :: c -> a`

and `q :: c -> b`

exist, such that for any other object `c'`

(with morphisms `p' :: c' -> a`

and `q' :: c' -> b`

), there exists a morphism `m :: c' -> c`

such that `p' = p . m`

and `q' = q . m`

.

Remember that a morphism in a poset basically describes the relationship "less than or equal to".

Now the product `c`

between two objects `a`

and `b`

must be an object less than or equal to both `a`

and `b`

. As an example, lets choose `a`

as `e`

and `b`

as `g`

from your graph:

```
b e -- this one is a
↗ ⤭ ↘
a → c f → h
↘ ⤭ ↗
d g -- this one is b
```

Trivially, the first object that comes to mind which is **always** less than or equal to any other object is the smallest object, in this case `a`

.

Now is `a`

a valid candidate for the product of `e`

and `g`

? Let's check the definition of product:

Is there a morphism from `a`

to `e`

? Yes, this exists and can be written as `pₐ = ce . ac`

(read as: "first the arrow from a to c, then the arrow from c to e").

Is there a morhism from `a`

to `g`

? Yes, this exists too and can be written as `qₐ = cg . ac`

.

So far so good, the only question left is whether this is the 'best' candidate in the sense that no other object exists such that we can construct a unique isomorphism between `a`

and the other candidate?

Looking at the graph, we can see that the object `c`

also fulfills the required criteria, with `p = ce`

and `q = cg`

.

All that is left to do is rank these two objects according to the above definition. We see that there exists a morphism from `a`

to `c`

. This means `c`

has to be the best candidate since we now can define the morphism `m = ac`

such that `pₐ = p . m = ce . ac`

and `qₐ = q . m = cg . ac`

.

So, a product of two objects in a poset is actually the greatest object which is both smaller than both (also called the greatest lower bound). It is worth noting that in a total ordering, this corresponds to the function `min(a, b)`

, since every object must be relateable to any other object (Wolfram call this trichotomy law).

Analog to the product definition, the coproduct corresponds to the smallest object greater than or equal to both `a`

and `b`

. In a total ordering, this corresponds to the maximum of both objects. You can work this one out for yourself.