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14.7: Solving Systems of Equations

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The solve function can also solve systems of equations. This is another way to solve systems of linear equations, like the ones we solved using matrices and the backslash operator in the Linear Algebra chapter.

Solving a Linear System

Consider the following 3 by 3 system:

\(4*x1 - 2*x2 + x3 = 7\)

\(x1 + x2 + 5*x3 = 10\)

\(-2*x1 + 3*x2 - x3 = 2\)

We can solve this system symbolically using solve.

syms x1 x2 x3
expr1 = 4*x1 - 2*x2 + x3 == 7;
expr2 = x1 + x2 + 5*x3 == 10;
expr3 = -2*x1 + 3*x2 - x3 == 2;

solution = solve(expr1, expr2, expr3)

x1_solution = solution.x1
x2_solution = solution.x2
x3_solution = solution.x3

numeric_solution = double([solution.x1 solution.x2 solution.x3])

The result is returned as a structure. Each field of the structure stores the solution for one unknown variable. We use dot notation, such as solution.x1, to access each result:

solution =

struct with fields:

    x1: 124/41
    x2: 121/41
    x3: 33/41


x1_solution =

    124/41


x2_solution =

    121/41


x3_solution =

    33/41


numeric_solution =

    3.0244 2.9512 0.8049

Note

For purely numeric linear systems, solving Ax = b is usually faster and more appropriate. Symbolic solve is helpful when exact symbolic answers are needed or when the equations are not purely numeric.

Solving a Nonlinear System

Symbolic solve is not limited to linear equations. It can also solve many nonlinear systems.

For example, consider the following system:

\(x^2 + y^2 = 25\)

\(y = x + 1\)

syms x y
eq1 = x^2 + y^2 == 25;
eq2 = y == x + 1;
sol = solve(eq1, eq2, x, y)

x= double(sol.x)
double(sol.y)

This example finds the intersection points of a circle and a line. Since the line may cross the circle at more than one point, the solution can contain more than one value for x and y.

sol =

struct with fields:

    x: [2×1 sym]
    y: [2×1 sym]


x =

    -4
    3


y =

    -3
    4

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