You could have specified the exact characteristics of your particular problem along with limits for different variables and the overall characteristics of the input.

Without this, I assume you use this definition:

You want to minimize the total tardiness in a single machine scheduling problem with n independent jobs, each having its processing time and due date.

What you want to do is to pick up a subset of the jobs so that they do not overlap (single machine available) and you can also pick the order in which you do them, keeping the due dates.

I guess the first step to do is to sort by the due dates, it seems that there is no benefit of sorting them in some different way.

Next what is left is to pick the subset. Here is where the dynamic programming comes to help. I'll try to describe the state and recursive relation.

**State:**

```
[current time][current job] = maximum number of jobs done
```

**Relation:**

You either process the current job and call

```
f(current time + processing_time_of[current job],current job +1)
```

or you skip the process and call

```
f(current time,current job +1)
```

finally you take the minimum of those 2 values returned by those calls and store it in state

```
[current time][current job]
```

And you start the recursion at time 0 and job 0.

By the way, greedy seems to be doing pretty well, check this out:

http://www.springerlink.com/content/f780526553631475/