DP IB Maths: AA HL

Revision Notes

5.9.5 Modelling with Volumes of Revolution

Test Yourself

The volume of the solid of revolution formed by rotating an area through 2 straight pi radians around the x-axis is V equals straight pi integral subscript a superscript b y squared space d x, and for the y-axis is V equals straight pi integral subscript a superscript b x squared space d y. These are both given in the formula booklet.

Adding & Subtracting Volumes

When would volumes of revolution need to be added or subtracted?

  • The ‘curve’ boundary of an area may consist of more than one function of x
    • For example
      • the ‘curve’ boundary from x equals 0 to x equals 3 is y equals f left parenthesis x right parenthesis
      • the ‘curve’ boundary from x equals 3 to x equals 6 is y equals g left parenthesis x right parenthesis
    • So the total volume would be V equals straight pi integral subscript 0 superscript 3 open square brackets f left parenthesis x right parenthesis close square brackets squared space d x plus straight pi integral subscript 3 superscript 6 open square brackets g left parenthesis x right parenthesis close square brackets squared space d x
  • The solid of revolution may have a ‘hole’ in it
    • e.g. a ‘toilet roll’ shape would be the difference of two cylindrical volumes

How do I know whether to add or subtract volumes of revolution?

  • When the area to be rotated around the x-axis has more than one function defining its boundary it can be trickier to tell whether to add or subtract volumes of revolution
    • It will depend on the nature of the functions and their points of intersection
    • With help from a GDC, sketch the graph of the functions and highlight the area required

How do I solve problems involving adding or subtracting volumes of revolution?

  • Visualising the solid created becomes increasingly useful (but also trickier) for shapes generated by separate volumes of revolution
    • Continue trying to sketch the functions and their solids of revolution to help
STEP 1
Identify the functions left parenthesis y equals f left parenthesis x right parenthesis comma space y equals g left parenthesis x right parenthesis comma space... right parenthesis involved in generating the volume
Determine whether the separate volumes will need to be added or subtracted
Identify the limits for each volume involved
Sketching the graphs of y equals f left parenthesis x right parenthesis and y equals g left parenthesis x right parenthesis, or using a GDC to do so, is helpful, especially when the limits are not given directly in the question

STEP 2
Square y for all functions left parenthesis open square brackets f left parenthesis x right parenthesis close square brackets squared comma space open square brackets g left parenthesis x right parenthesis close square brackets squared comma space... right parenthesis
This step is not essential if a GDC can be used to calculate integrals and an exact answer is not required.

STEP 3
Use the appropriate volume of revolution formula for each part, evaluate the definite integral and add or subtract as necessary

The answer may be required in exact form

Exam Tip

  • A sketch of the graph, limits, etc is always helpful, whether one has been given in the question or not
    • Use your GDC where possible

Worked example

Find the volume of revolution of the solid formed by rotating the region enclosed by the positive coordinate axes and the graphs of y equals 2 to the power of x and y equals 4 minus 2 to the power of x by 2 straight pi radians around the x-axis.  Give your answer to three significant figures.

5-9-5-ib-hl-aa-only-we1-soltn

Modelling with Volumes of Revolution

What is meant by modelling volumes of revolution?

  • Many everyday objects such as buckets, beakers, vases and lamp shades can be modelled as a solid of revolution
  • The volume of revolution of the solid can then be calculated
  • An object that would usually stand upright can be modelled horizontally so its volume of revolution can be found


What modelling assumptions are there with volumes of revolution?

  • The solids formed are usually the main shape of the body of the object
    • For example, the handle on a bucket would not be included
  • The thickness of the solid is negligible relative to the size of the object
    • thickness will depend on the purpose of the object and the material it is made from

How do I solve modelling problems with volumes of revolution?

  • Visualising and sketching the solid formed can help with starting problems
  • Familiarity with applying the volume of revolution fomulae
    • around the x-axis: V equals integral subscript a superscript b y squared space d x
    • around the y-axis: V equals integral subscript a superscript b x squared space d y
  • The volume of revolution may involve adding or subtracting partial volumes
  • Questions may ask related questions in context
    • g. A question about a bucket may ask about its capacity
      • this would be measured in litres
      • so a conversion of units may be required
      • (100 cm3 = 1 litre)

Exam Tip

  • Remember to answer questions directly
    • In modelling scenarios, interpretation is often needed after finding the 'final answer'
  • Modelling questions often ask about assumptions, criticisms and/or improvements
  • Examples
    • it is assumed the thickness of the material an object is made from is negligible
    • a 'smooth' curve may not be a good model if the item is being made from a rough material 
    • other things may significantly reduce the volume found and impact conclusions
      • e.g.  Stones, plants and decorations placed in an aquarium will reduce the volume of water needed to fill it - and hence the number/size/type of fish it can accommodate may be impacted  

Worked example

The diagram below shows the region R, which is bounded by the function y equals square root of x minus 1 end root, the lines x equals 2 and x equals 10, and the x-axis.

Dimensions are in centimetres.

5-9-5-ib-hl-aa-only-we2-qu-graph

A mathematical model for a miniature vase is produced by rotating the region R through 2π radians around the x-axis.

Find the volume of the miniature vase, giving your answer in litres to three significant figures.

5-9-5-ib-hl-aa-only-we2-soltn-

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Paul

Author: Paul

Paul has taught mathematics for 20 years and has been an examiner for Edexcel for over a decade. GCSE, A level, pure, mechanics, statistics, discrete – if it’s in a Maths exam, Paul will know about it. Paul is a passionate fan of clear and colourful notes with fascinating diagrams – one of the many reasons he is excited to be a member of the SME team.