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14.6: Solving Equations Symbolically

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One of the most useful features of the Symbolic Math Toolbox is the solve function. It can solve many algebraic equations exactly.

Solving One Equation

To solve an equation, first create the symbolic variable and then use solve. Notice that the equation uses ==, not =. In MATLAB, one equal sign assigns a value. Two equal signs represent equality.

Example \(\PageIndex{1}\)

syms x
solution = solve(2*x^2 + x == 6)
numbers = double(solution)

Solution

solution =

    -2
    3/2

numbers =

    -2.0000
    1.5000

This equation is quadratic, so it may have two solutions. MATLAB returns the symbolic solutions, and double converts them to numeric values.

Caution

Common mistake: Do not write solve(2*x^2 + x = 6). A single equal sign is for assignment. Use == inside equations.

Solving for a Specific Variable

If an equation contains more than one symbolic variable, MATLAB may need to know which variable you want to solve for.

Example \(\PageIndex{2}\)

syms x y
expr = 3*x + 2*y == 12;
sol_x = solve(expr, x)
sol_y = solve(expr, y)

Solution


sol_x =

4 - (2*y)/3


sol_y =

6 - (3*x)/2

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Example \(\PageIndex{1}\)

Solution

Caution

Example \(\PageIndex{2}\)

Solution