Exceptions are useful in a variety of circumstances.
First, there are some functions where the cost of calculating the pre-condition is so high it is better to just do the calculation and abort with an exception if it is found the pre-condition is not met. For example, you cannot invert a singular matrix, however to calculate if it is singular you calculate the determinant which is very expensive: it may have to be done inside the function anyhow, so just "have a try" at inverting the matrix and report an error if you can't by throwing an exception. This is basically an exception as negative pre-condition usage.
Then there are other cases where your code is already complex and passing error information up the call chain is difficult. This is partly because C and C++ have broken data structure models: there are other, better ways, but C++ doesn't support them (such as using monads in Haskell). This use is basically I couldn't be bothered to do it right so I'll throw an exception: its not the right way but it's practical.
Then there is the main use of exceptions: to report when external pre-conditions or invariants, such as sufficient resources like memory or disk space, are not available. In this case you will usually terminate the program, or a major subsection of it, and the exception is a good way of transmitting information about the problem. C++ Exceptions were designed for reporting errors which prevent the program continuing.
The exception handling model used in most modern languages including C++ is known to be broken. It is vastly too powerful. Theoreticians have now developed better models than the completely open "throw anything" and "maybe and maybe not catch it" model. In addition using type information to classify exceptions wasn't a very good idea.
So the best thing you can do is throw exceptions sparingly, when there's an actual error, and when there's no other way to deal with it and catch exceptions as close to the throw point as possible.