Find the orthocenter of a triangle from three vertex coordinates. Compare orthocenter, centroid, circumcenter, and incenter positions with area and Euler line analysis.
The orthocenter is one of the four classical triangle centers and is defined as the point where all three altitudes of a triangle intersect. An altitude is a perpendicular line drawn from a vertex to the opposite side (or its extension). Understanding the orthocenter and its relationship to other triangle centers—the centroid, circumcenter, and incenter—is foundational in coordinate geometry and analytic geometry.
For an acute triangle, the orthocenter lies inside the triangle. For a right triangle, it coincides with the vertex at the right angle. For an obtuse triangle, the orthocenter falls outside the triangle entirely. This behavior makes the orthocenter particularly interesting for studying triangle classification.
The Euler line is a remarkable geometric result: the orthocenter (H), centroid (G), and circumcenter (O) of any non-equilateral triangle are collinear, and the centroid divides the segment HO in a 2:1 ratio. This calculator computes all four classical centers, the nine-point center, side lengths, angles, area, perimeter, and Euler line distance so you can explore these relationships interactively.
Whether you are a student working through a coordinate geometry assignment, a teacher preparing visual demonstrations, or an engineer verifying triangle properties, this tool provides comprehensive triangle center analysis from just three pairs of coordinates.
Orthocenter 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 a x, a y, b x, and it returns orthocenter, centroid, circumcenter, incenter 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.
Orthocenter H = 3G − 2O, where G is the centroid ((x₁+x₂+x₃)/3, (y₁+y₂+y₃)/3) and O is the circumcenter. Circumcenter is found by solving perpendicular bisector equations. Area = |x₁(y₂−y₃) + x₂(y₃−y₁) + x₃(y₁−y₂)| / 2.
Result: Orthocenter = (0, 0)
For a right triangle with the right angle at vertex A (0,0), the orthocenter coincides with the vertex at the right angle. The centroid is at (1, 1.333), circumcenter at (1.5, 2), and incenter at (1, 1).
This orthocenter tool links the entered values (a x, a y, b x, b y) 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
Orthocenter 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 (orthocenter, centroid, circumcenter, incenter) 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.
The orthocenter is the point where all three altitudes of a triangle meet. An altitude is a perpendicular segment from a vertex to the opposite side.
Yes. For obtuse triangles, the orthocenter lies outside the triangle. For acute triangles it is inside, and for right triangles it is at the right-angle vertex.
The Euler line is a straight line that passes through the orthocenter, centroid, and circumcenter of any non-equilateral triangle. The centroid divides the segment from the orthocenter to the circumcenter in a 2:1 ratio.
The centroid is where the three medians meet and always lies inside the triangle. The orthocenter is where the three altitudes meet and can be inside or outside depending on the triangle type.
Find the slopes of two sides, compute the negative reciprocal for each altitude slope, write line equations through the opposite vertices, and solve the system to find the intersection point. Use this as a practical reminder before finalizing the result.
The nine-point center is the center of the nine-point circle, which passes through the midpoints of the sides, feet of the altitudes, and midpoints of segments from vertices to orthocenter. It is the midpoint of the orthocenter and circumcenter.
Every non-degenerate triangle (three non-collinear points) has exactly one orthocenter. A degenerate triangle (collinear points) does not have an orthocenter.