Linear programing
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The document discusses linear programming (LP) as a mathematical method used for optimal resource allocation in various fields. It covers definitions, applications, advantages, limitations, and types of solutions in LP, alongside specific terminologies like feasible and optimal solutions. Additionally, it touches on duality and sensitivity analysis, which help in understanding the optimization process under varying conditions.
![IMPORTANT DEFINITIONS IN L.P.
Solution:
A set of variables [X1,X2,...,Xn+m] is called a
solution to L.P. Problem if it satisfies its constraints.
Feasible Solution:
A set of variables [X1,X2,...,Xn+m] is called a
feasible solution to L.P. Problem if it satisfies its
constraints as well as non-negativity restrictions.
Optimal Feasible Solution:
The basic feasible solution that optimises the
objective function.
Unbounded Solution:
If the value of the objective function can be
increased or decreased indefinitely, the solution is called
an unbounded solution.](https://image.slidesharecdn.com/linearprograming-111120091922-phpapp02/85/Linear-programing-13-320.jpg)
Linear programing
- 1. LINEAR PROGRAMMING By:- Sankheerth P. Uma Maheshwar Rao Aakansha Bajpai Abhishek Bose Amit Kumar Das Aniruddh Tiwari Ankit Sharma Archana Yadav Arunava Saha Arvind Singh Awinash Chandra Ashok Kumar Komineni
- 2. LINEAR PROGRAMMING What is LP ? The word linear means the relationship which can be represented by a straight line .i.e the relation is of the form ax +by=c. In other words it is used to describe the relationship between two or more variables which are proportional to each other The word “programming” is concerned with the optimal allocation of limited resources. Linear programming is a way to handle certain types of optimization problems Linear programming is a mathematical method for determining a way to achieve the best outcome
- 3. DEFINITION OF LP LP is a mathematical modeling technique useful for the allocation of “scarce or limited’’ resources such as labor, material, machine ,time ,warehouse space ,etc…,to several competing activities such as product ,service ,job, new equipments, projects, etc...on the basis of a given criteria of optimality
- 4. DEFINITION OF LPP A mathematical technique used to obtain an optimum solution in resource allocation problems, such as production planning. It is a mathematical model or technique for efficient and effective utilization of limited recourses to achieve organization objectives (Maximize profits or Minimize cost). When solving a problem using linear programming , the program is put into a number of linear inequalities and then an attempt is made to maximize (or minimize) the inputs
- 5. REQUIREMENTS There must be well defined objective function. There must be a constraint on the amount. There must be alternative course of action. The decision variables should be interrelated and non negative. The resource must be limited in supply.
- 6. ASSUMPTIONS Proportionality Additivity Continuity Certainity Finite Choices
- 7. APPLICATION OF LINEAR PROGRAMMING Business Industrial Military Economic Marketing Distribution
- 8. AREAS OF APPLICATION OF LINEAR PROGRAMMING Industrial Application Product Mix Problem Blending Problems Production Scheduling Problem Assembly Line Balancing Make-Or-Buy Problems Management Applications Media Selection Problems Portfolio Selection Problems Profit Planning Problems Transportation Problems Miscellaneous Applications Diet Problems Agriculture Problems Flight Scheduling Problems Facilities Location Problems
- 9. ADVANTAGES OF L.P. It helps in attaining optimum use of productive factors. It improves the quality of the decisions. It provides better tools for meeting the changing conditions. It highlights the bottleneck in the production process.
- 10. LIMITATION OF L.P. For large problems the computational difficulties are enormous. It may yield fractional value answers to decision variables. It is applicable to only static situation. LP deals with the problems with single objective.
- 11. TYPES OF SOLUTIONS TO L.P. PROBLEM Graphical Method Simplex Method
- 12. FORMS OF L.P. The canonical form Objective function is of maximum type All decision variables are non negetive The Standard Form All variables are non negative The right hand side of each constraint is non negative. All constraints are expressed in equations. Objective function may be of maximization or minimization type.
- 13. IMPORTANT DEFINITIONS IN L.P. Solution: A set of variables [X1,X2,...,Xn+m] is called a solution to L.P. Problem if it satisfies its constraints. Feasible Solution: A set of variables [X1,X2,...,Xn+m] is called a feasible solution to L.P. Problem if it satisfies its constraints as well as non-negativity restrictions. Optimal Feasible Solution: The basic feasible solution that optimises the objective function. Unbounded Solution: If the value of the objective function can be increased or decreased indefinitely, the solution is called an unbounded solution.
- 14. VARIABLES USED IN L.P. Slack Variable Surplus Variable Artificial Variable
- 15. Non-negative variables, Subtracted from the L.H.S of the constraints to change the inequalities to equalities. Added when the inequalities are of the type (>=). Also called as “negative slack”. Slack Variables Non-negative variables, added to the L.H.S of the constraints to change the inequalities to equalities. Added when the inequalities are of the type (<=). Surplus Variables In some L.P problems slack variables cannot provide a solution. These problems are of the types (>=) or (=) . Artificial variables are introduced in these problems to provide a solution. Artificial variables are fictitious and have no physical meaning. Artificial Variables
- 16. DUALITY : For every L.P. problem there is a related unique L.P. problem involving same data which also describes the original problem. The primal programme is rewritten by transposing the rows and columns of the algebraic statement of the problem. The variables of the dual programme are known as “Dual variables or Shadow prices” of the various resources. The optimal solution of the dual problem gives complete information about the optimal solution of the primal problem and vice versa.
- 17. ADVANTAGES : By converting a primal problem into dual , computation becomes easier , as the no. of rows(constraints) reduces in comparison with the no. of columns( variables). Gives additional information as to how the optimal solution changes as a result of the changes in the coefficients . This is the basis for sensitivity analysis. Economic interpretation of dual helps the management in making future decisions. Duality is used to solve L.P. problems in which the initial solution in infeasible.
- 18. SENSITIVITY ANALYSIS : (POST OPTIMALITY TEST) Two situations: In formulation , it is assumed that the parameters such as market demand, equipment capacity, resource consumption, costs, profits etc., do not change but in real time it is not possible. After attaining the optimal solution, one may discover that a wrong value of a cost coefficient was used or a particular variable or constraint was omitted etc.,
- 19. Changes in the parameters of the problem may be discrete or continuous. The study of effect of discrete changes in parameters on the optimal solution is called as “Sensitivity analysis”. The study of effect of continuous changes in parameters on the optimal solution is called as “Parametric Programming.” The objective of the sensitivity analysis is to determine how sensitive is the optimal solution to the changes in the parameters.
- 20. WE THANK YOU FOR YOUR PATIENCE
Editor's Notes
- #5: LPP is the problem of maximizing r minimizing a linear function subjected to finite number of constraints
- #6: -The objective function in case of manufacturing company can be profit, cost, or quantities produced, which is either to be maximised or minimised.-These constraints must be capable of being expressed in inequality.For ex :- Product may be produced by different machines and the problem may be that how much to allocate to each of those machines.
- #15: Certain problems that have at least one constraint which is either or greater than or equal to equal to type cannot be solved by introducing slack or surplus variables, then a third variable called artificial variable is introduced. These values are ficticious and assume no meaning. They take the role of slack variable at the first iteration only to be replaced in the second iteration. Details of it can be understood when we will cover the Big M model.
- #16: Certain problems that have at least one constraint which is either or greater than or equal to equal to type cannot be solved by introducing slack or surplus variables, then a third variable called artificial variable is introduced. These values are ficticious and assume no meaning. They take the role of slack variable at the first iteration only to be replaced in the second iteration. Details of it can be understood when we will cover the Big M model.