Surface Area of Pyramids, Cones, and Spheres
Find the slant height first. Always. Then apply the formula. Composite solids hide faces at the join — list what is exposed before calculating anything.
Practise this lesson
Three printable worksheets that build from foundations to mastery — or build your own from any module’s questions.
A party hat is a cone with no base. A beach ball is a sphere. An Egyptian pyramid has a square base and triangular sides.
Before learning any formula — what do you think would be the hardest surface to calculate the area of, and why?
Three new solids — each requiring slant height $\ell$ in the formula. The number one rule: find slant height before applying any formula.
Square pyramid: one square base + four identical triangular faces. $\text{SA} = b^2 + 2b\ell$. Cone: circular base + curved surface. $\text{SA} = \pi r\ell + \pi r^2$. Sphere: one continuous surface. $\text{SA} = 4\pi r^2$.
Key facts
- SA formulas for square pyramids, cones ($\pi r\ell + \pi r^2$), and spheres ($4\pi r^2$)
- How slant height relates to vertical height via Pythagoras
- How to handle composite solids with hidden faces
Concepts
- Why slant height $\ell \neq$ vertical height $h$ — and why using $h$ in the formula gives a wrong answer
- Why a hemisphere SA $= 3\pi r^2$ (not $2\pi r^2$) — the flat face must be included
- Why hidden faces at composite joins must be excluded from SA
Skills
- Find slant height using Pythagoras before every cone or pyramid SA calculation
- Calculate SA of any cone, pyramid, sphere, or hemisphere
- List exposed faces of composite solids and calculate total SA correctly
This distinction is the source of more marks lost in this topic than anything else. Before any formula — know which height you have and which you need.
Vertical height $h$
Straight line from apex to centre of base — perpendicular to base. Inside the solid — not visible on the surface. Used in volume formulas.
Slant height $\ell$
Distance along the face — from midpoint of a base edge (pyramid) or base circle (cone) to apex. On the surface — the face you would paint. Used in surface area formulas.
Finding Slant Height with Pythagoras:
The right-angled triangle inside the solid has: vertical height $h$ as one leg, half the base dimension as the other leg, and slant height $\ell$ as the hypotenuse.
Surface Area of a Square Pyramid
$$\text{SA} = b^2 + 2b\ell$$
One square base ($b^2$) + four identical triangular lateral faces (each $\frac{1}{2}b\ell$, giving $4 \times \frac{1}{2}b\ell = 2b\ell$ total).
If the pyramid has no base (open at the bottom — like a tent or roof frame): $\text{SA} = 2b\ell$ (lateral faces only).
Surface Area of a Cone
$$\text{SA} = \pi r\ell + \pi r^2$$
Curved lateral surface ($\pi r\ell$) + circular base ($\pi r^2$). Factored: $\text{SA} = \pi r(\ell + r)$. Open cone (no base): $\text{SA} = \pi r\ell$.
Surface Area of a Sphere and Hemisphere
$$\text{SA}_\text{sphere} = 4\pi r^2$$
One of the most elegant results in geometry: the total surface area of a sphere equals exactly four circles of the same radius laid flat.
A hemisphere has two surfaces: curved outer dome $\frac{1}{2} \times 4\pi r^2 = 2\pi r^2$ plus flat circular base $\pi r^2$.
$$\text{SA}_\text{hemisphere} = 2\pi r^2 + \pi r^2 = 3\pi r^2$$
Composite Solids — Hidden Faces at Joins
When two solids are joined, the faces at the join become internal. They are hidden from the outside and are not part of the surface area.
At any join between two solids, the joined faces are not included in the total SA. List which faces are exposed on the outer surface — then calculate only those.
What to write in your book
- Slant height $\ell$ is on the surface; vertical height $h$ is inside the solid. SA formulas always use $\ell$.
- Cone: $\ell = \sqrt{r^2 + h^2}$. Pyramid: $\ell = \sqrt{h^2 + (b/2)^2}$. Find $\ell$ first — every time.
- Square pyramid: $\text{SA} = b^2 + 2b\ell$ (base + 4 triangular faces).
- Sphere: $4\pi r^2$. Hemisphere: $3\pi r^2$ (do NOT forget the flat base $\pi r^2$).
- Composite solids: list faces as exposed or hidden. Anything at the join is hidden — do not include it.
Did you get this? True or false: the slant height $\ell$ and vertical height $h$ of a cone are equal.
Worked examples · 3 in a row, reveal as you go
A square pyramid has base side 8 cm and vertical height 3 cm. Find the total surface area.
$\ell^2 = h^2 + (b/2)^2 = 3^2 + 4^2 = 9 + 16 = 25$
$\ell = 5\text{ cm}$
$\text{SA} = b^2 + 2b\ell = 8^2 + 2(8)(5)$
A cone has base radius 5 cm and vertical height 12 cm. Find the total surface area correct to 2 decimal places.
$\ell^2 = r^2 + h^2 = 5^2 + 12^2 = 25 + 144 = 169$
$\ell = 13\text{ cm}$
$\text{SA} = \pi r\ell + \pi r^2 = \pi(5)(13) + \pi(5^2)$
$= 65\pi + 25\pi = 90\pi$
$\text{SA} = 282.74\text{ cm}^2$
(a) Find the SA of a sphere with radius 6 cm. (b) Find the total SA of the resulting hemisphere. (c) A cone (radius 4 cm, vertical height 3 cm) sits on a cylinder (radius 4 cm, height 6 cm). Find total SA correct to 2 decimal places.
Curved: $72\pi$ Flat base: $36\pi$
Total: $72\pi + 36\pi = 108\pi = 339.29\text{ cm}^2$
Cone $\ell$: $\ell^2 = 4^2+3^2 = 25$, $\ell = 5$
Cylinder curved: $2\pi(4)(6) = 48\pi$
Cylinder base: $\pi(16) = 16\pi$
Cone curved: $\pi(4)(5) = 20\pi$
Total: $84\pi = 263.89\text{ cm}^2$
What to write in your book
- For every cone or pyramid where $\ell$ is not given: write "Step 1: find $\ell$ using Pythagoras" — this earns a mark regardless of subsequent errors.
- Hemisphere = half sphere dome $+$ flat circle base $= 2\pi r^2 + \pi r^2 = 3\pi r^2$.
- Composite solid: write "Exposed faces:" and list them before any calculation. Mark hidden faces explicitly.
- Using vertical height $h$ in place of slant height $\ell$ in SA formulas is the most common 0-mark error in this topic.
Quick check: A hemisphere has radius 5 cm. Its total SA is:
Common errors · the 3 traps that cost marks
What to write in your book
- Misconception to fix: capacity and volume are related — 1 litre = 1000 cm³ = 1 dm³.
- Cone SA has $\ell$ (slant) not $h$ (vertical) — these are NEVER equal unless the cone is degenerate.
- Hemisphere: always 3 surfaces to check — curved dome (yes), flat circle (yes), nothing else.
Fill the gap: A square pyramid has base side 10 cm and vertical height 12 cm. Slant height: $\ell^2 = 12^2 +$ $^2 = 144 + 25 = 169$, so $\ell =$ cm. Total SA $= 100 + 2(10)(13) =$ cm².
Quick-fire practice · 11 calculations
Square pyramid: base side 6 cm, vertical height 4 cm. Find total SA.
Square pyramid: base side 10 m, slant height 13 m. Find total SA.
Square pyramid: base side 8 cm, vertical height 3 cm. Find lateral SA only (no base).
Cone: $r = 3$ cm, vertical height 4 cm. Find total SA to 2 decimal places.
Cone: $r = 6$ m, slant height 10 m. Find total SA to 2 decimal places.
Cone: $r = 5$ cm, vertical height 12 cm. Find curved surface area only to 2 decimal places.
Find SA of a sphere with $r = 9$ cm to 2 decimal places.
Find SA of a sphere with diameter 14 m to 2 decimal places.
Find total SA of a hemisphere with $r = 7$ cm to 2 decimal places.
A cone ($r = 5$ cm, vertical height 12 cm) sits on top of a cylinder ($r = 5$ cm, height 8 cm). Find total SA to 2 decimal places.
A hemisphere ($r = 4$ cm) sits on top of a cylinder ($r = 4$ cm, height 10 cm). Find total SA to 2 decimal places.
Odd one out: Three of these statements about pyramids, cones, and spheres are correct. Which one is wrong?
Match each solid to its surface area formula:
Earlier you predicted which solid would be hardest to calculate the area of. Look back at your initial response.
Most students guess the sphere is hardest — but $4\pi r^2$ is actually the simplest formula in this lesson. The cone is harder because you must find slant height first before applying $\pi r\ell + \pi r^2$. The pyramid has a similar hidden step. The sphere is pure elegance.
Pick your answer, then rate your confidence — that tells the system what to drill next. Each retry pulls a fresh mix from the bank.
SA 4. A square pyramid has a base side of 10 cm and vertical height of 12 cm.
(a) Find the slant height. (1 mark)
(b) Find the total SA. (2 marks)
SA 5. A cone has base diameter 16 cm and vertical height 15 cm.
(a) Find the slant height. (1 mark)
(b) Find the total SA correct to 2 decimal places. (2 marks)
SA 6. A decorative ornament has a hemisphere (radius 3 cm) sitting on top of a cylinder (radius 3 cm, height 7 cm).
(a) Find the curved SA of the hemisphere. (1 mark)
(b) Find the exposed SA of the cylinder (top hidden, base included). (2 marks)
(c) Find the total SA correct to 2 decimal places. (1 mark)
Comprehensive answers (click to reveal)
Drill 1: $\ell = \sqrt{16+9} = 5$ cm; $\text{SA} = 36 + 60 = \mathbf{96\text{ cm}^2}$
Drill 2: $\text{SA} = 100 + 2(10)(13) = 100 + 260 = \mathbf{360\text{ m}^2}$
Drill 3: $\ell = \sqrt{9+16} = 5$ cm; Lateral SA $= 2(8)(5) = \mathbf{80\text{ cm}^2}$
Drill 4: $\ell = 5$ cm; $\text{SA} = 15\pi + 9\pi = 24\pi = \mathbf{75.40\text{ cm}^2}$
Drill 5: $\text{SA} = 60\pi + 36\pi = 96\pi = \mathbf{301.59\text{ m}^2}$
Drill 6: $\ell = 13$ cm; Curved $= \pi(5)(13) = 65\pi = \mathbf{204.20\text{ cm}^2}$
Drill 7: $4\pi(81) = 324\pi = \mathbf{1017.88\text{ cm}^2}$
Drill 8: $r = 7$; $4\pi(49) = 196\pi = \mathbf{615.75\text{ m}^2}$
Drill 9: $3\pi(49) = 147\pi = \mathbf{461.81\text{ cm}^2}$
Drill 10: $\ell = 13$; $2\pi(5)(8) + \pi(25) + \pi(5)(13) = 80\pi + 25\pi + 65\pi = 170\pi = \mathbf{534.07\text{ cm}^2}$
Drill 11: $2\pi(4)(10) + \pi(16) + 2\pi(16) = 80\pi + 16\pi + 32\pi = 128\pi = \mathbf{402.12\text{ cm}^2}$
SA 4(a): $\ell^2 = 144 + 25 = 169$; $\ell = \mathbf{13\text{ cm}}$
SA 4(b): $\text{SA} = 100 + 2(10)(13) = 100 + 260 = \mathbf{360\text{ cm}^2}$
SA 5(a): $r = 8$; $\ell^2 = 64 + 225 = 289$; $\ell = \mathbf{17\text{ cm}}$
SA 5(b): $136\pi + 64\pi = 200\pi = \mathbf{628.32\text{ cm}^2}$
SA 6(a): $2\pi(9) = 18\pi\text{ cm}^2$
SA 6(b): $2\pi(3)(7) + \pi(9) = 42\pi + 9\pi = 51\pi\text{ cm}^2$
SA 6(c): $18\pi + 51\pi = 69\pi = \mathbf{216.77\text{ cm}^2}$
Defend your ship by blasting the correct answers for Surface Area of Pyramids, Cones, and Spheres. Scores count toward the Asteroid Blaster leaderboard.
⚔ Enter the arenaClimb platforms by answering SA of pyramids, cones and spheres questions. Pool: lesson 8.
Mark lesson as complete
Tick when you've finished the practice and review.