![]() ![]() In the first column, we eliminated y from equations 1 & 2, resulting in equation A.In the second column, we eliminated y from equations 2 & 3, resulting in equation B. Then eliminate the same variable from another set of two equations. To do so, we eliminate one of the variables from two of the equations. This becomes our new #2Įliminate One VariableWe have rewritten our three equations as follows:Now, to solve, we need to first get two equations with two variables. Remove Fractions and DecimalsWe can eliminate the fraction in #1 by multiplying both sides of the equation by 4.This is our new version of #1We can eliminate the decimals in #2 by multiplying both sides of the equation by 100.Note that all terms have a common factor of 5 So, Let’s divide both sides by 5, so we have smaller numbers to work with. If we eliminate the fractions and decimals, the equations will be easier to work with. Put equations in Standard FormRewriting Equation 3 into standard form:Add y to both sizesAdd 6z to both sidesOur 3 equations are now:But, note that equations #1 contains a fraction, and #2 contains decimals. We need to get the y and z terms to the left side of the equation. ![]() Note that equation #3 is not in standard form. all variables are on the left side of the equation. Result will be a second equation in two variables.Solve the new system of two equations.Using the solution for the two variables, substitute the values into one of the original equations to solve for the third variable.Check the solution set in the remaining two original equations.Įxample system of three equationsExample: solve for x, y and zFirst, we need to ensure that all equations are in standard form, i.e. Result will be a new equation with two variables.Eliminate the same variable using another set of two equations. Steps to solving a system of equations in 3 VariablesEnsure that the equations are in standard form: Ax + By + Cz = DRemove any decimals or fractions from the equations.Eliminate one of the variables using two of the three equations. Independent, Dependent and Inconsistent EquationsSystems of three equations in three variables follow the same characteristics of systems of equations in two variablesIndependent equations have one solution Dependent equations have an infinite number of solutionsInconsistent equations have no solutionSolving a system of equations in three variables involves a few more steps, but is essentially the same process as for systems of two equations in two variables. Will review the submission and either publish your submission or provide feedback.Solving Systems of Linear equations with 3 VariablesTo solve for three variables, we need a system of three independent equations. You can help us out by revising, improving and updatingĪfter you claim an answer you’ll have 24 hours to send in a draft. Use the first equation:Ĭombine like terms on the left side of the equation: ![]() Substitute the values for $y$ and $z$ we just found into one of the original equations to solve for $x$. Subtract $1$ from each side of the equation:ĭivide both sides of the equation by $3$ to solve for $z$: Substitute this value for $y$ into the sixth equation to solve for $z$: Multiply equation $4$ by $-1$:Ĭombine equations $5$ and $6$ to eliminate the $z$ variable:ĭivide both sides by $4$ to solve for $y$: Modify equation $4$ such that one variable is the same in equations $4$ and $5$ but differs in sign. Substitute this expression for $x$ into both equations $1$ and $2$: Subtract $2z$ from both sides of the equation: The first step is to isolate the $x$ variable in equation $3$. ![]()
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