Examples of quadratic equation in the following topics:
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- The standard form of a quadratic equation is useful for completing the square, which is used to graph the equation.
- This form of quadratic equation is known as the "standard form" for graphing parabolas in algebra; from this equation, it is simple to determine the x-intercepts (y = 0) of the parabola, a process known as "solving" the quadratic equation.
- Completing the square may be used to solve any quadratic equation.
- This can be applied to any quadratic equation.
- Graph with the quadratic equation .
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- Quadratic equations are second order polynomials, and have the form $f(x)=ax^2+bx+c$.
- A quadratic equation is a specific case of a quadratic function, with the function set equal to zero:
- When all constants are known, a quadratic equation can be solved as to find a solution of $x$.
- Quadratic equations are different than linear functions in a few key ways.
- is known as factored form, where $x_1$ and $x_2$ are the zeros, or roots, of the equation.
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- The zeros of a quadratic equation can be found by solving the quadratic formula.
- The quadratic formula is one tool that can be used to find the roots of a quadratic equation.
- where the values of $a$, $b$, and $c$ are the values of the coefficients in the quadratic equation:
- The quadratic formula can always be used to find the roots of a quadratic equation, regardless of whether the roots are real or complex, whole numbers or fractions, and so on.
- We can now substitute these values into the quadratic equation and simplify:
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- Completing the square is a method for solving quadratic equations, and involves putting the quadratic in the form $0=a(x-h)^2 + k$.
- Along with factoring and using the quadratic formula, completing the square is a common method for solving quadratic equations.
- Once completing the square has been performed, the quadratic is easy to solve; because there is only one place where the variable $x$ is squared, the $(x-h)^2$ term can be isolated on one side of the equation, and then the square root of both sides can be taken.
- This quadratic is not a perfect square.
- Solve for the zeros of a quadratic function by completing the square
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- We can factor quadratic equations of the form $ax^2 + bx + c$ by first finding the factors of the constant $c$.
- The factored form of a quadratic equation takes the general form:
- To factor this, we have to arrange the quadratic equation in order of largest exponent value to smallest exponent value.
- This leads to the equation:
- Employ techniques to see whether a general quadratic equation can be factored
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- Two kinds of equations are linear and quadratic.
- A quadratic equation is a univariate polynomial equation of the second degree.
- A general quadratic equation can be written in the form:
- Examples of graphed quadratic equations can be seen below.
- Recognize the various forms in which linear and quadratic equations can be written
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- Many equations with no odd-degree terms can be reduced to quadratics and solved with the same methods as quadratics.
- If a substitution can be made such that the higher order polynomial takes the form of a quadratic, any method for solving a quadratic equation can be applied.
- With substitution, we were able to reduce a higher order polynomial into a quadratic equation.
- It is important to realize that
the same kind of substitution can be done for any equation in quadratic form, not just quartics.
- Use the quadratic formula to solve any equation in quadratic form
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- A quadratic equation of the form $ax^2+bx+c=0$ can sometimes be solved by factoring the quadratic expression.
- Factoring is useful to help solve an equation of the form:
- For example, if you wanted to solve the equation $x^2-7x+12=0$, if you could realize that the quadratic factors as $(x-3)(x-4)$.
- We attempt to factor the quadratic.
- Use the factors of a quadratic equation to solve it without using the quadratic formula
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- Recall how the roots of quadratic functions can be found algebraically, using the quadratic formula $(x=\frac{-b \pm \sqrt {b^2-4ac}}{2a})$.
- Consider the quadratic function that is graphed below.
- Recall that the quadratic equation sets the quadratic expression equal to zero instead of $f(x)$:
- For the given equation, we have the following coefficients: $a = 1$, $b = -1$, and $c = -2$.
- Recognize that the solutions to a quadratic equation represent where the graph of the equation crosses the x-axis
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- where $a$, $b$ and $c$are the constants ($a$ must be non-zero) from a quadratic polynomial.
- If ${\Delta}$ is equal to zero, the square root in the quadratic formula is zero:
- Since adding zero and subtracting zero in the quadratic equation lead to the same outcome, there is only one distinct root of the quadratic function.
- Graph of a polynomial with the quadratic function $ f(x) = x^2 - x - 2$.
- Explain how and why the discriminant can be used to find the number of real roots of a quadratic equation