Modelling with Trigonometric Functions (DP IB Analysis & Approaches (AA)): Revision Note

Author

Amber

Last updated

3 December 2024

Did this video help you?

Modelling with Trigonometric Functions

What can be modelled with trigonometric functions?

Anything that oscillates (fluctuates periodically) can be modelled using a trigonometric function
- Normally some transformation of the sine or cosine function
Examples include:
- $D (t)$ is the depth of water at a shore t hours after midnight
- $T (d)$ is the temperature of a city d days after the 1st January
- $H (t)$ is vertical height above ground of a person t seconds after entering a Ferris wheel
Notice that the x-axis will not always contain an angle
- In the examples above time or number of days would be on the x-axis
- Depth of the water, temperature or vertical height would be on the y-axis

What are the parameters of trigonometric models?

A trigonometric model could be of the form
- $f (x) = a \sin (b (x - c)) + d$
- $f (x) = a \cos (b (x - c)) + d$
- $f (x) = a \tan (b (x - c)) + d$
The a represents the amplitude of the function
- The bigger the value of a the bigger the range of values of the function
- For the function $a \tan (b (x - c)) + d$ the amplitude is undefined
The b determines the period of the function
- Period $= \frac{360 °}{b} = \frac{2 π}{b}$
- The bigger the value of b the quicker the function repeats a cycle
The c represents the horizontal shift
The d represents the vertical shift
- This is the principal axis

What are possible limitations of a trigonometric model?

The amplitude is the same for each cycle
- In real-life this might not be the case
- The function might get closer to the value of d over time
The period is the same for each cycle
- In real-life this might not be the case
- The time to complete a cycle might change over time

ib-aa-sl-3-5-3-transformations-of-trig-graphs

Examiner Tips and Tricks

The variable in these questions is often t for time.
Read the question carefully to make sure you know what you are being asked to solve.

Worked Example

The water depth, D, in metres, at a port can be modelled by the function

$D (t) = 3 \sin (15 ° (t - 2)) + 12, 0 \leq t < 24$

where t is the elapsed time, in hours, since midnight.

a) Write down the depth of the water at midnight.

aa-sl-3-5-3-modelling-with-trig-functions-we-solution-part-i-png

b) Find the minimum water depth and the number of hours after midnight that this depth occurs.

aa-sl-3-5-3-modelling-with-trig-functions-we-solution-part-ii

c) Calculate how long the water depth is at least 13.5 m each day.

aa-sl-3-5-3-modelling-with-trig-functions-we-solution-part-iii

You've read 0 of your 5 free revision notes this week

Sign up now. It’s free!

Join the 100,000+ Students that ❤️ Save My Exams

the (exam) results speak for themselves:

Test yourself Flashcards

Did this page help you?

Previous:Transformations of Trigonometric FunctionsNext:Simple Identities

Modelling with Trigonometric Functions (DP IB Analysis & Approaches (AA)): Revision Note

Modelling with Trigonometric Functions

What can be modelled with trigonometric functions?

What are the parameters of trigonometric models?

What are possible limitations of a trigonometric model?

You've read 0 of your 5 free revision notes this week

Sign up now. It’s free!

Join the 100,000+ Students that ❤️ Save My Exams

1. Number & Algebra

Number Toolkit

Standard Form

Laws of Indices

Exponentials & Logs

Introduction to Logarithms

Laws of Logarithms

Solving Exponential Equations

Sequences & Series

Language of Sequences & Series

Arithmetic Sequences & Series

Geometric Sequences & Series

Applications of Sequences & Series

Compound Interest & Depreciation

Proof & Reasoning

Proof

Binomial Theorem

Binomial Theorem

2. Functions

Linear Functions & Graphs

Equations of a Straight Line

Quadratic Functions & Graphs

Quadratic Functions

Factorising & Completing the Square

Solving Quadratics

Quadratic Inequalities

Discriminants

Functions Toolkit

Language of Functions

Composite & Inverse Functions

Graphing Functions

Further Functions & Graphs

Reciprocal & Rational Functions

Exponential & Logarithmic Functions

Solving Equations

Modelling with Functions

Transformations of Graphs

Translations of Graphs

Reflections of Graphs

Stretches of Graphs

Composite Transformations of Graphs

3. Geometry & Trigonometry

Geometry Toolkit

Coordinate Geometry

Radian Measure

Arcs & Sectors

Geometry of 3D Shapes

3D Coordinate Geometry

Volume & Surface Area

Trigonometry

Pythagoras & Right-Angled Trigonometry

Non Right-Angled Trigonometry

Applications of Trigonometry & Pythagoras

The Unit Circle & Exact Values

The Unit Circle

Exact Values

Trigonometric Functions & Graphs

Graphs of Trigonometric Functions

Transformations of Trigonometric Functions

Modelling with Trigonometric Functions

Trigonometric Equations & Identities

Simple Identities

Double Angle Formulae

Relationship Between Trigonometric Ratios

Linear Trigonometric Equations

Quadratic Trigonometric Equations

4. Statistics & Probability

Statistics Toolkit

Sampling & Data Collection

Statistical Measures

Frequency Tables

Linear Transformations of Data