Check if a quadratic expression ax² + bx + c is a perfect square trinomial. Get factored form, discriminant, vertex, roots, and step-by-step verification.
A perfect square trinomial (PST) is a special quadratic expression of the form ax² + bx + c that can be written as the square of a binomial. In other words, the trinomial factors neatly into (px + q)² or (px − q)². This happens when and only when the discriminant b² − 4ac equals zero, meaning the quadratic has a double root.
Recognizing perfect square trinomials is a fundamental algebra skill used throughout mathematics — from simplifying expressions and solving equations to completing the square and analyzing parabolas. The condition b² = 4ac provides a quick numerical check: compute b², compute 4ac, and see if they match.
This calculator takes coefficients a, b, and c and instantly tells you whether the expression is a PST. If it is, you get the fully factored binomial form. Either way, the tool reports the discriminant, vertex coordinates, roots, axis of symmetry, and Vieta's formula results. A step-by-step verification walks you through the algebra, and a reference table shows the most common PST patterns so you can spot them on sight. Preset examples let you explore classic cases like x² + 6x + 9 = (x + 3)² with a single click. Whether you're studying for an algebra exam or double-checking homework, this calculator makes perfect-square-trinomial identification effortless.
Perfect Square Trinomial problems often require several dependent steps, and a small arithmetic slip can propagate through every derived value. This calculator is tailored to that workflow: you enter coefficient a (x² term), coefficient b (x term), coefficient c (constant), and it returns perfect square trinomial?, factored form, discriminant (b²−4ac), vertex in one consistent pass. It is useful for homework checks, worksheet generation, tutoring walkthroughs, and fast field/design estimates where you need reliable geometry results without rebuilding the full derivation each time.
A trinomial ax² + bx + c is a perfect square trinomial if and only if b² − 4ac = 0. When true, ax² + bx + c = (√a · x + sign(b)·√c)², assuming a > 0 and c ≥ 0.
Result: Yes — factored form (x + 3)²
b² = 36, 4ac = 4 × 1 × 9 = 36. Since b² = 4ac, the expression x² + 6x + 9 is a perfect square trinomial equal to (x + 3)².
This perfect square trinomial tool links the entered values (coefficient a (x² term), coefficient b (x term), coefficient c (constant), show step-by-step) to the target geometry relationships used in class and practice problems. Instead of solving each intermediate step manually, you can validate setup and arithmetic quickly while still tracing which measurements drive the final result.
Formula focus: the calculator formula
Perfect Square Trinomial shows up in school geometry, technical drafting, construction layout checks, and early engineering design estimates. When values are changed repeatedly, the calculator helps you compare scenarios quickly and see how sensitive the shape is to each dimension.
Start with the primary outputs (perfect square trinomial?, factored form, discriminant (b²−4ac), vertex) and then use the remaining cards/tables to confirm consistency with your diagram. Keep units consistent across inputs, and round only at the end if your assignment or project specifies a fixed precision.
It is a quadratic expression ax² + bx + c that equals the square of a binomial, such as (x + 3)² = x² + 6x + 9. Use this as a practical reminder before finalizing the result.
Compute b² and 4ac. If they are equal (b² − 4ac = 0), the trinomial is a perfect square.
No. For ax² + bx + c to be a square of real numbers, both a and c must be non-negative.
The single repeated root is x = −b/(2a). For x² + 6x + 9, the double root is x = −3.
Yes. b² = 144 and 4ac = 4 × 4 × 9 = 144. It factors as (2x + 3)².
Completing the square adds a constant to make any quadratic into a PST, enabling direct factoring into vertex form. Keep this note short and outcome-focused for reuse.