Think10x.ai Logo

System of Linear Equations Problem: Solve for (x, y) Step-by-Step

Master systems of equations SAT questions with a step-by-step solution, clear explanations, and strategies to solve them faster on the digital SAT.
Think10x.ai graphic featuring a systems of equations SAT problem with a step-by-step solve-for-(x, y) headline and sample question mockup

Question

3x + 4y = -23

2y – x = -19

What is the solution (x,y) to the system of equations above?

(A) (-5,-2)

(B) (3,-8)

(C) (4,-6)

(D) (9,-6)

Quick Answer

The solution is (3, -8). This is one of those systems of equations SAT problems where the fastest path is substitution. The second equation is already nearly solved for x, so rearranging it and plugging it into the first equation collapses two unknowns into one clean step.

Bottom Line

(x, y) = (3, -8)

Rearranging the second equation gives x = 2y + 19. Substituting into the first equation produces a single-variable equation that solves to y = -8, and then x = 3.

How to Solve a System of Linear Equations: Video Walkthrough

We created a step-by-step video walkthrough of this system of equations SAT problem. Watch how we isolate a variable in the simpler equation, substitute into the other, and then back-solve to find both unknowns.

Full Video Transcript

Below is the complete transcript from the video explanation:

  1. Here’s an SAT-style system. Let’s solve it step by step together. We’ll keep the work clear and calm as we go. This is the first equation in the system, and this second equation is the one we’ll rearrange for substitution. Since both equations are linear, substitution is quick.
  2. Let’s solve the second equation for x. From 2y minus x equals negative 19, we get x equals 19 plus 2y. This expression for x is what we’ll plug into the first equation.
  3. Now substitute this expression for x into the first equation. We’ll plug in x equals 19 plus 2y into 3x plus 4y equals negative 23. Distribute the 3. 3 times 19 is 57, and 3 times 2y is 6y. Keep the plus 4y. These are like terms. Combine them to simplify. 6y plus 4y makes 10y. Let’s isolate the y term. Subtract 57 from both sides.
  4. Now divide both sides by 10 to solve for y. Here’s the y-value we’ll use to find x. Great. Plug y equals negative 8 into x equals 19 plus 2y to get x. That’s x equals 19 plus 2 times negative 8. Compute carefully. 2 times negative 8 is negative 16, so x equals 19 minus 16, which is 3. Our solution is the ordered pair (3, negative 8). That matches choice B. Nice work staying organized. Let’s lock it in.

Step-by-Step Explanation

Like most systems of linear equations problems, this one follows a clean four-step method. Each step sets up the next.

Step 1. Choose the Equation to Isolate a Variable

Before doing any algebra, identify which equation and which variable will be easiest to isolate. The second equation, 2y minus x equals negative 19, contains x with a coefficient of negative 1. Moving it requires only one step, which makes it the better starting point. Choosing the simpler equation first is a core strategy for any equation model problem.

  • 2y – x = -19
  • x = 2y + 19

Step 2. Substitute into the Other Equation

Replace x in the first equation with the expression found in Step 1. Every instance of x becomes 2y + 19. This is the defining move in substitution and the reason it works: we trade two unknowns for one.

  • 3x + 4y = -23
  • 3(2y + 19) + 4y = -23
  • 6y + 57 + 4y = -23
  • 10y + 57 = -23
  • 10y = -80
  • y = -8

Step 3. Back-Substitute to Find the Second Variable

With y known, substitute it back into the isolated expression from Step 1 to find x. This is called back-substitution and it closes the loop on the two-variable system.

  • x = 2y + 19
  • x = 2(-8) + 19
  • x = -16 + 19
  • x = 3

Step 4. Verify the Solution in Both Original Equations

Always check the ordered pair in both original equations. A solution that works in only one equation is not a solution to the system.

  • Check equation 1: 3(3) + 4(-8) = 9 – 32 = -23. Correct
  • Check equation 2: 2(-8) – 3 = -16 – 3 = -19. Correct

The solution is (3, -8), which matches choice B. The core insight for any equation of a line word problems situation like this is to look for the variable with the simplest coefficient first. That single choice drives every step that follows.

Frequently Asked Questions

What does it mean to solve a system of equations?

Solving a system of equations means finding the values of the variables that satisfy all equations in the system at the same time. For a two-equation, two-variable system like this one, the solution is an ordered pair (x, y) that makes both equations true simultaneously. In this problem that pair is (3, -8).

When should I use substitution over elimination?

Use substitution when one equation already has a variable with a coefficient of 1 or -1, because isolating it takes only one algebraic step. In this problem, x in the second equation has a coefficient of -1, making substitution the faster choice. Elimination works better when both equations have matching or easily scaled coefficients. Knowing which method to reach for is one of the key skills for systems of equations SAT questions.

Why do we check the answer in both equations?

Checking in both equations confirms the solution is valid for the entire system, not just one equation. Arithmetic errors during substitution can produce a value that satisfies one equation but not the other. A quick verification step catches those errors before they cost you the question.

How do word problems using systems of equations appear on the SAT?

On the SAT, word problems using systems of equations are often presented with the equations already written out, as in this problem, or with a short scenario you must translate into two equations yourself. Either way, the solving method is the same: identify what substitution or elimination step simplifies the system fastest, carry it through carefully, and verify the result. These problems consistently appear in the heart of the algebra section.

What is the general method for word problems on linear equations?

Define your unknowns, set up one equation per relationship given in the problem, then use substitution or elimination to reduce the system to a single-variable equation. Solve for that variable, back-substitute to find the other, and verify both answers in the original equations. That sequence handles any word problems on linear equations you will encounter.

How do equation models connect to real-world problems?

Equation models translate real-world constraints into mathematical language. A system of linear equations can represent anything from pricing and quantities to speeds and distances. The algebraic technique is identical regardless of context: set up the equations, solve the system, and interpret the result in the original scenario. This is exactly why equation models appear so frequently in standardized testing.

How do you tell if a system of linear equations has one solution, no solution, or infinitely many solutions?

A system has one solution when the two lines intersect at a single point, as in this problem. It has no solution when the lines are parallel and never meet, which happens when the equations are inconsistent. It has infinitely many solutions when both equations describe the same line. For any equation of a line word problems context, checking whether the slopes and intercepts match will tell you which case you are dealing with.

Want a Step-by-Step Video for Your Own Question?

The above example’s video explanation was generated using Think10x.ai.

Upload a clear photo of any math problem, including probability, algebra, geometry, or calculus, and our tool will turn it into a narrated, animated explanation in minutes.

👉 Try it at Think10x.ai

Private by default. Captions included. Built for tutors and students.

TABLE OF CONTENT