Geometry in the coordinate plane: circles, tangents

Algebra • Graphs

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What is the tangent line equation in point-gradient form at (x1, y1) when y1 ≠ 0?

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y - y1 = (-x1 / y1)(x - x1)

Key concepts

What you'll likely be quizzed about

Equation of a circle with centre at the origin

A circle with centre at the origin (0,0) and radius r satisfies x^2 + y^2 = r^2. The variables x and y represent coordinates of any point on the circumference. The radius r is a non-negative constant and appears as r^2 on the right-hand side, so the equation defines all points at distance r from the origin. A point (x, y) lies on the circle if and only if x^2 + y^2 equals r^2. If the equation does not simplify to a positive r^2, the expression does not represent a real circle centred at the origin. Translation of the centre produces different standard forms, but the origin-centred form remains x^2 + y^2 = r^2.

Equation of a tangent to a circle at a given point

A tangent to a circle at a point is a straight line that touches the circle at exactly one point and is perpendicular to the radius at the point of contact. For the circle x^2 + y^2 = r^2 and a point (x1, y1) on the circle, the radius from the origin to (x1, y1) has gradient y1/x1 when x1 ≠ 0. The tangent gradient equals the negative reciprocal, giving m_t = -x1/y1 when y1 ≠ 0. The tangent line can be written as y - y1 = (-x1/y1)(x - x1) when y1 ≠ 0. A robust algebraic form of the tangent avoids division by zero: x x1 + y y1 = r^2. Substitution of (x, y) yields a linear equation. That form handles special cases: when y1 = 0, the tangent becomes x = x1; when x1 = 0, the tangent becomes y = y1. The line x x1 + y y1 = r^2 follows from differentiating or from the perpendicularity (dot product) relation between radius and tangent direction.

Coordinates and sign rules in the four quadrants

The plane divides into four quadrants by the x- and y-axes. Quadrant I contains points with x > 0 and y > 0. Quadrant II contains points with x < 0 and y > 0. Quadrant III contains points with x < 0 and y < 0. Quadrant IV contains points with x > 0 and y < 0. Points on the axes have one coordinate equal to zero and may serve as special cases in gradient and tangent calculations. Distance from the origin uses the formula sqrt(x^2 + y^2) regardless of quadrant, because squaring removes sign. Midpoint and gradient formulae operate across quadrants without modification, but gradient signs reflect quadrant position: a line between points in different quadrants may have positive or negative gradient depending on the relative coordinates.

Key notes

Important points to keep in mind

Equation x^2 + y^2 = r^2 defines all points at distance r from the origin.

Tangent at (x1,y1) is perpendicular to the radius from the origin to (x1,y1).

Use x x1 + y y1 = r^2 for a tangent equation that avoids division by zero.

If y1 = 0, the tangent is vertical: x = x1.

If x1 = 0, the tangent is horizontal: y = y1.

Quadrant signs: I (+,+), II (-,+), III (-,-), IV (+,-).

Distance formula sqrt(x^2 + y^2) ignores coordinate signs.

Check that candidate tangent point satisfies the circle equation before deriving the tangent.

Solve circle-line intersections by substitution and examine the discriminant for tangency.

Gradient formula requires non-zero denominator; handle vertical lines separately.