As everyone else has said, Linear Programming is a way to solve optimization problems, in which the terms are linear.

It might help to understand what types of problems LP's solve

One example where I've used Linear Programming is building a restaurant schedule. In a restaurant you have skill sets:

- Cooks
- Servers
- Dishwashers
- Hosts
- Bussers
- Manager
etc

And you have employees, each with one or more skill sets. Each employee also has a specific availability. For example, Bob can't work Sunday mornings because he's a pastor at a local church. Employees also have an associated cost. Bob might be $10.50/hr while Suzy is $5.15/hr. Finally Employees might have minimum guaranteed hours. Since Bob has been an employee for 15 years, the boss says he'll always get at least 35 hours.

The restaurant itself has demands. For example it has 3 shifts: Morning, Afternoon, and Night, and each of these shifts has a set of staffing requirements: We need 1 cook, 1 server, 1 manager in the morning, 3 cooks, 2 servers, 2 hosts, 2 managers in the afternoon, and 4 cooks, 4 servers, 3 hosts, 2 managers, 2 bussers in the evening. Each shift will have a duration, and you can figure out the cost of each shift by multiplying the duration by the employee's hourly wage.

Finally we have state and federal laws, and some basic "business" rules: No employee can work more than 8-hours without going into overtime. No employee can be scheduled for less than 2 hours (because it would suck to make a 30 minute commute for a 2 hour shift), employees can't work two overlapping shifts, etc.

Now given all these requirements, give me a schedule that has meets all requirements, and produces the lowest labor cost.

This is an example of a linear programming optimization problem.

A linear program typically consists of:

An objective function, variables, variable bounds, and constraints.

Since we want to minimize cost, our objective function is going to involve shifts that employees work, and the associated costs (shift duration * wage).

The variables in this case, are the shifts that each employee can work.

The bounds on these variables integers between 0 and 1, because either an employee is working the shift (1), or the employee is not working the shift (0). This, by the way, is a special program, called a Binary Integer Program or BIP for short, because all the variables are integers (no fractional values) and all values are either 0 or 1.

The constraints are equality/inequality constraints based on the requirements above.

For example, if Bob and Suzy can both work as cooks in the morning, then `Bob_Morning_Cook1_Shift + Suzy_Morning_Cook1_Shift = 1`

, with `Bob_Morning_Cook_Shift = {0,1}`

and `Suzy_Morning_Cook_Shift = {0,1}`

due to the bounds mentioned above. These three pieces of information specify that at most only a single employee can be assigned as the first morning cook.

So once you've defined all the constraints that model your problem, you can begin to solve the problem. If a solution can be found (and depending on the constraints the problem may be infeasible), it will give you the employee assignments that produce the lowest weekly labor cost.