While it's true that adding a third "state" would add flexibility in some situations, the implementation of this would not necessarily be better than the current.
Take for example one of the most simple, yet crucial portions of a computer, a logic gate. A logic gates job is to read the inputs and create an output based on those inputs. Let's take for example a 1.2V processor, where a "1" is 1.2V and 0V is a "0". Considering computers are not perfect machines, it calls for the need to have a threshold of values. So it makes sense that 0-600mV will constitute a "0" and 600mV to 1.2V will constitute a "1". This is a pretty big threshold and should almost never have an incorrect output.
Now, let's consider adding another state. It goes that 0V-400mV would constitue a "0", 400mV-800mV a "1" and 800mV to 1.2V a "2". This clearly reduces the threshold, thereby increasing the chance of error. To then offset this increased in error chance, better components would need to be used to ensure that the voltage is read correctly and also better components would hopefully reduce electrical noise which will cause an increase in accuracy.
So not only will the cost be increased, but you will also need a mechanism to create a 600mV bus (for the "1" option) which will have an error range of +-200mV.
In this simple example, you can see that adding a third state would increase the complexity of a simple logic gate by quite a bit. I am sure there are many reasons why this has not been implemented, but this is just one example.
A similar question was asked here.