Mirrors, lenses, refracting surfaces — one formula each, and every one of them is written in the same convention. Learn to read a diagram as signed coordinates and you never again memorise "real is minus, virtual is plus": the algebra does it for you. Drag the point below and watch its sign flip.
Put the origin at the pole P (the mirror's vertex, or a lens's optical centre). Point the +x axis along the incident light. Now every distance is just a coordinate — with a sign baked in. Which way the light travels is your choice: send it either way and watch only the signs change, never the distances.
{{ axSentence }}
A sign convention is a choice of reference, not a law of nature. Walk to the other side of the table and the same experiment sends its light the opposite way. Every length you'd read off a ruler is identical — but +x now points the other way, so every sign flips. That is all the signs on u, v and f ever encode: which side of the pole a thing sits on, relative to the light — never its raw distance.
{{ rule.body }}
{{ q.body }}
Send in a beam parallel to the axis. Where it focuses decides the sign. A concave mirror focuses the light in front — against the incident direction — so f is negative. A convex mirror only appears to focus behind it, along the incident direction — so f is positive.
{{ focalNote }}
Object 30 cm in front, focal length 20 cm concave. Put in the signs — u = −30, f = −20 — and solve the mirror equation.
This gives v = −60 cm. The minus sign tells you the image is real and in front — you never had to decide that yourself. Magnification m = −v/u = −(−60)/(−30) = −2: inverted, twice as tall.
Six one-tap questions. Don't compute anything — just read the geometry and name the sign. {{ quizSolved }}/6 right.