A spy detective game is one of my favorite games in my childhood. And I think you are not an exception who never play this game. In my childhood age, I always imagined how detectives decode secret messages? And I was always curious to know about it.

When I grow up, I am able to find out the method to decode the message. *What is that? *Well, it is one of the applications of linear algebra called *Cryptography*. Below, I have explained the exciting applications of linear algebra in detail. So, let’s move to the details of one more concept of mathematics.

**What is linear algebra?**

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It is a branch of ** mathematics **that includes vector spaces, infinite dimensions, and linear mapping among the spaces—the system of linear equations used for this kind of investigation.

The linear algebra equations are represented with the help of the formalism of vectors and matrices. Moreover, linear algebra is necessary for both applied and pure mathematics.

Key Point:Linear algebra relates to linear combinations. It means you can use arithmetic on the numbers’ column that is known as arrays and vectors of the numbers termed as matrices. These matrices are created for new arrays and columns of the numbers. |

** Let’s take an example of it**; the abstract algebra method is used for relaxing the vector space’s axioms. The functional analysis use for the infinite-dimensional vector space’s version.

On the other hand, linear algebra helps in providing the linear systems’ solution for differential equations.

There are several techniques of linear algebra that are used for *physics, computer science, analytic geometry, natural science, computer animation, and social science (particularly in economics). *

Being a well-developed theory, linear algebra is used for non-linear mathematics models approximated by linear details.

**What are the applications of linear algebra?**

**Cryptography**

It is the study of decoding and encoding of the secret messages. Using electronic transactions and communications, solid encryption methods can be applied. Those methods involve modular arithmetic to decode/encode the messages. And the simpler encoding methods apply using the concept of matrix transformation.

I mentioned above that the linear algebra concept is used to decode the secret message (a cryptography method).

**Let’s understand it with an example.**

Assign the specific number to each alphabetical letter to encode the short secret messages.

Then, the sequence of the number of each text should be organized in the square matrix form (taken as A).

*[**Note:** if the letters’ number is lower than the number of the element, then fill the matrix with the zero elements.]*

Assume a nonsingular square matrix as B. To encode the message, multiply matrix A with matrix B ** (i.e., matrix A * matrix B)**. Assume the matrix B as:

B = |

Here is the text ”** BILA KOCKA**” (a white cat) change into matrix A:

and to encode the text, apply:

Z = BA = |

Now, multiply the matrix Z to B inverse to decode the message:

As matrix multiplication is not commutative, it must maintain the matrices with the exact product value. If you multiply the Z and B inverse matrix in the opposite order, you will obtain:

Now, the secret message was ** “CERNY PSIK”** (a variety of black dogs).

**Game theory**

It is another one of the applications of linear algebra, which is a mathematical study that describes the number of possible options. The players make these options during the game playing. As per the psychologists, the social interaction theory is used to consider the player’s options against other players in the competition.

Although game theory focuses on cards, board games, and other competitive games, it also applies to the military strategy used in the wars.

**Let’s understand it with an example.**

➢ *Rock, Paper, Scissors *

It is one of the simple examples of the* Zero-sum game*. A payoff matrix is used similarly to that of Prisoner’s Dilemma’s payoff.

*How?*

Suppose you need to count the two players’ scores over several games. A point is added to the player with every win, and a point is subtracted with each loss. For tie, the point is neither substracted nor added to the score.

Then the payoff matrix will look as:

This matrix is similar to that of a skew-symmetric matrix. This implies that the game is symmetrical.

If a player wins, the other one will lose. If both tie, then the players will not get and detect the point.

It is what the zero-sum game is.

*[Each positive option will result in a reward, and a negative option will lead to opposition.]*

**Are there any other applications of linear algebra?**

*Yes, there is!*

Besides the above-mentioned applications of linear algebra, the concept is also used in:

Networks and graphs for analyzing networks. |

Matrices in the field of engineering, like a springs line. |

The simplex optimization method for linear programming. |

Linear algebra for probability and statistics like least squares for regression. |

Fourier Series used in signal processing using various functions. |

Chemistry and physics for equilibrium temperature distributions. |

Leontief’s economics models describe the interrelations between outputs, prices, and demands in the economic systems. |

Computed tomography that uses for constructing a human body’s cross-sectional view using X-ray scans. |

Genetics to look at the concept behind dominant and recessive traits. |

Anything that includes data fitting or differential equations. |

An interesting thing about linear algebra: Linear algebra is the type of mathematics that is also used by the famous scientist He used it in the theory of relativity, particularly tensor calculus and tensors. Moreover, he introduced the concepts of linear algebra notations to physics. Those notations are called Albert Einstein. or Einstein summation convention Einstein notation. |

**Conclusion**

Linear algebra basically is the study of the planes and lines, mapping, and vector spaces, which are needed for linear transformations. Therefore, it is necessary to know what are the applications of linear algebra. Above I have explained those applications. Understand them deeply and try to use the concept of linear algebra in real life.

In case you are not able to solve or understand the concept of linear algebra, comment in the below section. I will help you in the best possible way that will definitely be going to help you in the long run. and also get the algebra homework help and math algebra homework help from our experts.

*“So, keep enhancing your knowledge with statanalytica blogs.”*

**Frequently Asked Questions**

**Where is linear algebra used in real life?**

Linear algebra can be utilized nearly in all compute-intensive work and tasks. It can also be used efficiently to solve any nonlinear or linear equations.

**What are the benefits of linear algebra?**

Linear Algebra enables you to understand the basic linear systems with the use of vectors and matrices. Moreover, Linear Algebra provides you several tools to prove the key theorems for a particular purely computational reason.

**How is linear algebra used in statistics?**

Linear algebra use in any application, which deals with multiple random variables at a particular time. But it has been seen that linear algebra is mostly used in multivariable statistics course(s).