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Solving linear equations can be a little tedious—but it doesn’t have to be! With Cramer’s rule, you can solve for 3 separate variables at the same time without solving the entire system of equations. After you find the matrices, you can use simple multiplication, addition, and subtraction to solve for x, y, and z.
Steps
Question 3 of 5:
How do you find the determinants using Cramer’s rule?
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Find the determinants by categorizing the x, y, and z values. The determinants are the coefficients in your equations, or the numbers multiplied by the variable. For example, let’s use the equations: . To use Cramer’s rule, set up your determinants, or numbers, in a 3 x 3 matrix, or a small box. In the equations above, the box would look like this: . The numbers are all of the values from each of the 3 equations. [3] X Research source
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2Replace the x-column values with the answer column values. Now it’s time to determine what is. To do that, take your box and replace the x column (the one furthest on the left) with the answers from your original 3 equations. So, . This is your coefficient determinant, or the numbers you’ll use to solve for the x variable. [4] X Research source
- Repeat this for y and z to find Dy and Dz. For instance, in the equations above, and .
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Question 4 of 5:
How do you solve 3 equations using Cramer’s rule?
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Expand the determinants by rewriting the first 2 columns. In order to use Cramer’s rule, you need to turn your 3 x 3 determinants into a 5 x 3 grid. For example, if you’re working with , add and on the end to create . [5] X Research source
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2Multiply along the downward and upward diagonals. In order to use Cramer’s rule, you have to simplify your 5 x 3 grid using multiplication. Take a look at your expanded box of determinants. Go through and multiply along the downward diagonals, and write the numbers below the box to keep track of them. Then, go through and multiply along the upward diagonals, writing your answers above the box. [6] X Research source
- For instance, in the box above, the downward diagonals are: .
- The upward diagonals are: .
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3Add the downward diagonals and subtract the upward diagonals. Cramer’s rule states that we can use our multiplied numbers to find the variable that we need. In our example above, the equation would look like: . Therefore, . [7] X Research source
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4Plug the numbers into the Cramer’s rule equation. Go through and do the steps above for and . Then, plug your answers into the equation to solve all three. [8] X Research source
- Working with our example above, we can expand the Dx, Dy, and Dz variables in the same way. Once you multiply across the upward and downward diagonals, you’ll get: , , .
- Plugging the answers into Cramer’s rule, our equation looks like this: .
- Solve the equation to get: .
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QuestionWhat do you do If you have variables multiplied together?Community AnswerIf you have more than one variable, that's a non-linear equation, and it will require factoring.
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Tips
- Write out your equations by hand to give yourself a helpful visual while using Cramer’s rule.Thanks
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References
- ↑ https://www.purplemath.com/modules/cramers.htm
- ↑ http://www.mesacc.edu/~scotz47781/mat150/notes/cramers_rule/Cramers_Rule_3_by_3_Notes.pdf
- ↑ https://www.purplemath.com/modules/cramers.htm
- ↑ https://www.purplemath.com/modules/cramers.htm
- ↑ http://www.mesacc.edu/~scotz47781/mat150/notes/cramers_rule/Cramers_Rule_3_by_3_Notes.pdf
- ↑ https://www.purplemath.com/modules/determs2.htm
- ↑ https://www.math.utah.edu/~gustafso/determinants.pdf
- ↑ https://www.math.utah.edu/~gustafso/determinants.pdf
- ↑ https://www.purplemath.com/modules/cramers.htm
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