Invariant Points & Lines (Edexcel A Level Further Maths: Core Pure)

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Invariant Points

What is an invariant point?

When applying transformations to a shape or collection of points, there may be some points that stay in their original position; these are known as invariant points

How can I find invariant points?

If the point given by position vector $x; (\begin{matrix} x \\ y \end{matrix})$ , is invariant under transformation $T; (\begin{matrix} a & b \\ c & d \end{matrix})$ then we can say that $Tx = x$
- $(\begin{matrix} a & b \\ c & d \end{matrix}) (\begin{matrix} x \\ y \end{matrix}) = (\begin{matrix} x \\ y \end{matrix})$
This will create a system of simultaneous equations which can be solved to find the invariant point
- $(\begin{matrix} a x + b y \\ c x + d y \end{matrix}) = (\begin{matrix} x \\ y \end{matrix})$
  - $(a - 1) x + b y = 0$
  - $c x + (d - 1) y = 0$
The origin (0,0) is always invariant under a linear transformation

Exam Tip

Where the question allows, use your calculator to help solve the simultaneous equations
Test your found invariant point by multiplying it by the transformation matrix, and making sure you still end up with the same point (invariant)

Worked example

Find any invariant points under the transformation given by

T = (\begin{matrix} 4 & 2 \\ - 2 & 6 \end{matrix})

2-2-3-edx-a-fm-we1-soltn

A Line of Invariant Points

What is a line of invariant points?

If every point on a line is mapped to itself under a particular transformation, then it is a line of invariant points
- For example, a line of reflection is a line of invariant points

How can I find a line of invariant points?

Use the same strategy as for finding a single invariant point:
- If the point given by position vector $x; (\begin{matrix} x \\ y \end{matrix})$ , is invariant under transformation $T; (\begin{matrix} a & b \\ c & d \end{matrix})$ then we can say that $Tx = x$
  - $(\begin{matrix} a & b \\ c & d \end{matrix}) (\begin{matrix} x \\ y \end{matrix}) = (\begin{matrix} x \\ y \end{matrix})$
- This will create a system of simultaneous equations which can be solved to find the invariant point(s)
  - $(\begin{matrix} a x + b y \\ c x + d y \end{matrix}) = (\begin{matrix} x \\ y \end{matrix})$
  - $(a - 1) x + b y = 0$
  - $c x + (d - 1) y = 0$
If there is a line of invariant points, rather than solving to find a single solution (a point), the two equations will be able to simplify to the same equation
- This means that there are infinitely many solutions, and therefore infinitely many invariant points
  - A line contains infinitely many points
- Your solution will be the equation of the invariant line e.g. y=3x

Exam Tip

It may not always be obvious that the two equations reduce to the same thing (they could be an awkward multiple of each other)
Use your calculator’s simultaneous equation solver; it will tell you that there are infinitely many solutions

Worked example

Find the equation of the line of invariant points under the transformation given by $T = (\begin{matrix} 7 & - 2 \\ 6 & - 1 \end{matrix})$ 2-2-3-edx-a-fm-we2-soltn

Invariant Lines

What’s the difference between a line of invariant points and an invariant line?

If every point on a line is mapped to itself under a particular transformation, then it is a line of invariant points
- Every single point on the line must stay in the same place

With an invariant line however, every point on the line must simply map to another point on the same line

We are only concerned with the overall line; not the individual points

edexcel-al-fm-cp-2-2-3-invariant-lines

How do I find an invariant line?

We can use a similar strategy to finding invariant points, with two slight changes
- Use $y = m x + c$ to write the original position vector as $(\begin{matrix} x \\ m x + c \end{matrix})$
- Write the transformed position vector as $(\begin{matrix} x' \\ m x' + c \end{matrix})$ using the same idea
  - Notice that the values of m and c will be the same, but different x and y coordinates
  - This because it is a different point, on the same line

For an invariant line under transformation $T; (\begin{matrix} a & b \\ c & d \end{matrix})$ we can write
- $(\begin{matrix} a & b \\ c & d \end{matrix}) (\begin{matrix} x \\ m x + c \end{matrix}) = (\begin{matrix} x' \\ m x' + c \end{matrix})$
This will create a system of simultaneous equations which can be solved to find the invariant line(s)
- $a x + b (m x + c) = x'$
- $c x + d (m x + c) = m x^{'} + c$
- The first equation can be substituted into the second to give an equation in terms of the variable x and the constants m and c
- This equation can then be solved to find the values of m and c by equating the coefficients of x, and then equating the constant terms
  - There may be multiple solutions for m and c if there are multiple invariant lines

Worked example

Find the equation of any invariant lines under the transformation $T = (\begin{matrix} 2 & - 1 \\ - 3 & 0 \end{matrix})$

2-2-3-edx-a-fm-we3-soltn

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Invariant Points & Lines (Edexcel A Level Further Maths: Core Pure)

Revision Note

What is an invariant point?

How can I find invariant points?

What is a line of invariant points?

How can I find a line of invariant points?

What’s the difference between a line of invariant points and an invariant line?

How do I find an invariant line?

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Author: Jamie W