Systems of Linear and Quadratic Equations
📌 What is a Linear-Quadratic System?
A linear-quadratic system consists of one linear equation and one quadratic equation. Common combinations include:
- A straight line and a parabola
- A straight line and a circle
- A straight line and an ellipse
🎯 Number of Solutions
A linear-quadratic system can have:
- 0 solutions - The graphs don't intersect
- 1 solution - The line is tangent to the curve
- 2 solutions - The line intersects the curve at two points
Method 1: Solving by Graphing (Parabolas)
Steps:
- Identify the graph of each equation (line, parabola, circle)
- Graph the first equation on a coordinate plane
- Graph the second equation on the same plane
- Locate the points of intersection
- Verify solutions by substituting into both equations
📝 Example:
Solve the system:
\( y = x^2 - 4 \) (parabola)
\( y = 2x - 1 \) (line)
Graph both equations and find where they intersect. The intersection points are the solutions.
Method 2: Solving Algebraically (Substitution)
Steps for Parabolas:
- Solve the linear equation for one variable (usually \(y\))
- Substitute this expression into the quadratic equation
- Simplify to get a quadratic equation in one variable
- Solve using factoring, quadratic formula, or completing the square
- Find corresponding \(y\)-values by substituting \(x\)-values into the linear equation
- Write solutions as ordered pairs \((x, y)\)
📝 Example:
Solve the system:
\( y = x^2 - 6x + 3 \)
\( y = -2x + 3 \)
Step 1: The linear equation is already solved for \(y\)
Step 2: Substitute: \( -2x + 3 = x^2 - 6x + 3 \)
Step 3: Simplify: \( 0 = x^2 - 4x \)
Step 4: Factor: \( 0 = x(x - 4) \), so \( x = 0 \) or \( x = 4 \)
Step 5: Find \(y\) values:
- When \( x = 0 \): \( y = -2(0) + 3 = 3 \)
- When \( x = 4 \): \( y = -2(4) + 3 = -5 \)
Solutions: \((0, 3)\) and \((4, -5)\)
Method 3: Solving with Circles
Key Formulas:
Standard form of a circle:
\( (x - h)^2 + (y - k)^2 = r^2 \)
Where \((h, k)\) is the center and \(r\) is the radius
General form of a circle:
\( x^2 + y^2 + Dx + Ey + F = 0 \)
Steps:
- Solve the linear equation for \(y\) (or \(x\))
- Substitute into the circle equation
- Expand and simplify to get a quadratic equation
- Solve for the variable
- Substitute back to find the other coordinate
- Check your solutions in both equations
📝 Example:
Solve the system:
\( x^2 + y^2 = 9 \) (circle with center \((0,0)\), radius \(3\))
\( y = x - 3 \) (line)
Step 1: Linear equation is solved for \(y\)
Step 2: Substitute: \( x^2 + (x - 3)^2 = 9 \)
Step 3: Expand: \( x^2 + x^2 - 6x + 9 = 9 \)
Step 4: Simplify: \( 2x^2 - 6x = 0 \)
Step 5: Factor: \( 2x(x - 3) = 0 \), so \( x = 0 \) or \( x = 3 \)
Step 6: Find \(y\) values:
- When \( x = 0 \): \( y = 0 - 3 = -3 \)
- When \( x = 3 \): \( y = 3 - 3 = 0 \)
Solutions: \((0, -3)\) and \((3, 0)\)
Method 4: Solving Nonlinear Systems (Elimination)
When to Use Elimination:
Elimination works best when both variables are squared in both equations, such as:
- Two circles
- A circle and a hyperbola
- A circle and an ellipse
Steps:
- Write both equations in standard form
- Multiply one or both equations to make coefficients of one variable opposites
- Add the equations to eliminate one variable
- Solve for the remaining variable
- Substitute each solution into one original equation
- Solve for the other variable
- Write all solutions as ordered pairs
📝 Example:
Solve the system:
\( x^2 + y^2 = 7 \) (circle)
\( x^2 - y^2 = 1 \) (hyperbola)
Step 1: Both equations are in standard form
Step 2: Notice \(y^2\) has opposite coefficients already
Step 3: Add equations: \( 2x^2 = 8 \)
Step 4: Solve: \( x^2 = 4 \), so \( x = \pm 2 \)
Step 5: Substitute \(x = 2\) and \(x = -2\) into first equation:
\( 4 + y^2 = 7 \)
\( y^2 = 3 \)
\( y = \pm \sqrt{3} \)
Solutions: \((2, \sqrt{3})\), \((2, -\sqrt{3})\), \((-2, \sqrt{3})\), \((-2, -\sqrt{3})\)
⚡ Quick Tips
- Substitution is easiest when one equation is linear
- Elimination works best when both variables are squared
- Always check your solutions in both original equations
- Use the discriminant \(b^2 - 4ac\) to determine if real solutions exist
- If discriminant \(< 0\), there are no real solutions
- Graphing helps visualize the number of solutions
📚 Important Formulas
Quadratic Formula:
\( x = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a} \)
Standard Form of Parabola:
\( y = ax^2 + bx + c \) or \( x = ay^2 + by + c \)
Standard Form of Circle:
\( (x - h)^2 + (y - k)^2 = r^2 \)
Distance Formula:
\( d = \sqrt{(x_2 - x_1)^2 + (y_2 - y_1)^2} \)