In simple terms
A friendly intro before the formal notes — no formulas yet.
Curve Whispering: Slopes, Perpendiculars and Bends
The first derivative tells you the steepness of a curve at any point — that is the gradient of the tangent line, and its sign tells you whether the curve is rising or falling. The second derivative tells you how the curve is bending: curving upwards like a smile (concave up) or downwards like a frown (concave down).
Imagine a rollercoaster. The direction your cart points at any instant is the tangent. A support beam drilled into the ground at right angles to the track is the normal. Whether the track is scooping upwards into a peak or dishing downwards into a valley is set by the second derivative, and a point of inflection is the brief instant where the bend switches over — the transition from a dip to a hill.
- 1
Differentiate to get , the formula for the gradient of the tangent at any point .
- 2
For the gradient at a specific point , substitute to get ; the normal gradient is .
- 3
Use the point–gradient form for the line, remembering to find first.
- 4
Solve for stationary points, then use the sign of to classify them and to describe concavity.
Explore the concept
Use the live diagram, PhET or GeoGebra sim, and synced steps — play it, drag controls, or tap a step.
Step 1
Differentiate to get , the formula for the gradient of the tangent at any point .
Key formulas
Tap any symbol to reveal exactly what it means and its units.
Full topic notes
Formal explanation with the rigour you need for the exam.
The gradient of a curve at a point
The gradient of a straight line is constant, but the gradient of a curve changes from point to point. The derivative is precisely the rule that returns the gradient at each . So to find how steep the curve is at the point where , you differentiate once to get and then substitute: the gradient there is . This single value is the gradient of the tangent line at that point — the straight line that just touches the curve and heads in the same direction as the curve at that instant.
Tangents: the line that just touches
A tangent to a curve at a point is the straight line through that point whose gradient equals the derivative there. Finding its equation is a fixed three-step routine, and the step students most often drop is the very first one — the -coordinate of the point.
To find the tangent to at the point where :
- Find , so the point is .
- Differentiate and evaluate the gradient .
- Use the point–gradient form .
Normals: the perpendicular partner
The normal to a curve at a point is the line perpendicular to the tangent there. Because perpendicular lines have gradients whose product is , once you know the tangent gradient the normal gradient follows immediately as . The point is the same ; only the gradient changes.
Perpendicular gradients are negative reciprocals: , and .
Normal gradient at : , used with the same point .
A horizontal tangent (gradient ) has a VERTICAL normal — write , since is undefined.
A vertical tangent (undefined gradient) has a horizontal normal .
Increasing and decreasing functions
The sign of the first derivative tells you the direction of the curve. Where the gradient is positive and the function is increasing (rising left to right); where the function is decreasing. To find the intervals, differentiate, then solve the inequality or . The boundaries between increasing and decreasing behaviour are exactly the points where .
Increasing: — the curve rises as increases.
Decreasing: — the curve falls as increases.
It is the SIGN of that matters, not its magnitude; a tiny positive gradient still means increasing.
The changeover between increasing and decreasing happens where — a stationary point.
Stationary points and classifying them
A stationary point is a point where : the tangent is momentarily horizontal. There are three kinds — a local maximum (the curve turns from rising to falling), a local minimum (falling to rising), and a horizontal point of inflection (the curve levels off but keeps going the same way). To find them, solve ; to classify them, examine how the curve behaves around each point using either the first- or the second-derivative test.
Local maximum: and the gradient changes from to ; equivalently .
Local minimum: and the gradient changes from to ; equivalently .
Horizontal point of inflection: and the gradient does NOT change sign (e.g. to ); here and changes sign.
The second derivative, concavity and the second-derivative test
Differentiating the derivative gives the second derivative , also written . Where describes the slope, describes how the slope is changing — the concavity of the curve. If the gradient is increasing and the curve is concave up (a cup); if the gradient is decreasing and the curve is concave down (a frown). This gives the fast second-derivative test for a stationary point : substitute into . A positive value means a minimum, a negative value means a maximum, and a zero value means the test is inconclusive — you must then fall back on the sign of either side.
Concave up: — the curve lies above its tangents; a stationary point here is a minimum.
Concave down: — the curve lies below its tangents; a stationary point here is a maximum.
Second-derivative test: at , min, max, inconclusive.
Points of inflection
A point of inflection is where the concavity changes — from concave up to concave down, or vice versa. For this the second derivative must be zero AND change sign. Solving finds the candidate; you then confirm the sign of actually flips across it. In the example above, at ; for , (concave down) and for , (concave up), so the concavity changes and is a point of inflection.
When asked to find a point of inflection it is not enough to solve — you must justify the change of concavity. Show that the sign of differs just before and just after the point (a small sign table is ideal), or note that there. Marks are routinely lost for stopping at without the sign-change justification.
Common mistakes examiners penalise
Using the tangent gradient as the normal gradient — the normal gradient is , the negative reciprocal, not itself.
Forgetting the -coordinate — a tangent or normal at needs the point ; substitute into the ORIGINAL , not into .
Solving instead of for stationary points — stationary points come from the derivative being zero, not the function.
Confusing the sign of with the sign of — means increasing (direction); means concave up (bend). They are independent.
Misreading the second-derivative test — is a MINIMUM and is a MAXIMUM (concave up holds a low point). When the test is inconclusive, so do not declare an inflection without checking the sign change.
Claiming a point of inflection from alone — you must show changes sign; has but a minimum, not an inflection.
Trying to compute for a normal at a horizontal tangent — the normal is vertical, so write .
Model answer — marked the way our engine marks it
On Paper 1 the marks are analytic: each is tied to a specific line of working — a method mark (M) or an accuracy mark (A) — and the A-marks are dependent, meaning they are only awarded when the method they rest on is present. Follow-through (FT) means a correct method built on a wrong earlier value can still score the later marks, and 'in-symbolic-work' (ISW) means once you have a correct answer, a subsequent tidy-up slip is ignored. Equivalent forms are accepted. But that protection only exists if your method is written down. Study how each mark below is earned by a specific line.
Where this leads
Reading a curve through its derivatives is the engine behind optimisation, where you maximise or minimise a real quantity by finding and classifying a stationary point, and behind curve sketching, where increasing/decreasing intervals, turning points, concavity and inflections combine into a full picture of a graph. The same and reappear in kinematics as velocity and acceleration. Master the habit — point first, then gradient, then classify with , and always justify a sign change — and the applications that follow become variations on a method you already own.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
Find the equation of the tangent to the curve at the point where . [5]
- 1
1. Find the -coordinate. Substitute into the ORIGINAL function. , so the point of tangency is . (A1)
Find the equation of the normal to the curve at the point where . [5]
- 1
1. Find the point. , so the point is . (A1)
Consider . Find and classify the stationary points, and find the interval on which the graph is concave down. [7]
- 1
1. Differentiate and solve . . (M1) Setting : , so or . (A1)
Find the equation of the tangent to at the point where . [5]
- 1
Model answer — full working.
How it all connects
The big idea sits in the middle — tap a linked idea to explore the link.
Tap a linked idea to see how it connects back to the main topic — that connection is what examiners reward.
Glossary
Try to recall each definition before you reveal it.
Quick check
Answer in your head first — then tap to check. No pressure.
Revision flashcards
Flip the card. Test yourself before the exam.
Gradient of a curve at a point
The gradient of at is the value of the derivative there, . It equals the gradient of the tangent line at that point.
Key takeaways
Review these before you close the topic — retrieval beats re-reading.
- ✓
Perpendicular gradients are negative reciprocals: , and .
- ✓
Normal gradient at : , used with the same point .
- ✓
A horizontal tangent (gradient ) has a VERTICAL normal — write , since is undefined.
- ✓
A vertical tangent (undefined gradient) has a horizontal normal .
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Get a Paper 1 tangent-and-normal question marked with full working
Get a Paper 1 tangent-and-normal question marked with full working
Extra simulations & links
PhET, GeoGebra and other curated tools — open in a new tab.
Frequently asked
Checkpoint
One marked question is worth ten re-reads — close the loop before you move on.
Reading it isn’t knowing it — prove it.
Before you move on: do Get a Paper 1 tangent-and-normal question marked with full working on paper, snap a photo, and get examiner-style feedback on exactly where you win and lose marks.