Here is the solution I came up with. It is based on this diagram:

## Math background

My solution uses "trigonometry", which is a method for calculating the length of one side of a triangle from the length of another side and the angles of the triangle. This is advanced math which I would expect to be taught maybe in 9th or 10th grade. I do not expect someone in 5th grade to know trigonometry. Also I cannot explain every detail of trigonometry, because I would have to write a lot and I do not think I have the teaching skills to make it clear. I would recommend you to look at for example this video to learn about the method:

https://www.youtube.com/watch?v=5tp74g4N8EY

You could also ask your teacher for more information, or research about it on the internet on your own.

## Step 1: Calculating the angles

We can do this without trigonometry.

First, we see there is a "pentagon" (5-sided polygon) in the middle. I want to know the inner angle of a corner in this "pentagon". I call this angle `X`

:

How can we calculate the angle `X`

? We first remember that the sum of the inner angles in a triangle is `180°`

. We see that we can divide a 5-sides polygon into `5-2`

triangles like this:

The sum of the inner angle of each of these `5-2`

triangles is `180°`

. So for the whole 5-sided polygon, the sum of the inner angles is `180° * (5-2)`

. Since all angles have the same size, each angle is `180°*(5-2) / 5 = 108°`

. So we have `X = 108°`

.

The angle on the other side is the same as `X`

. This allows us the calculate the angle between the two `X`

. I will call this angle `Y`

:

Since a full circle is `360°`

, we know that `360° = 2*X + 2*Y`

. Therefore, `Y = (360° - 2*X) / 2`

. We know that `X = 108°`

, so we get `Y = 72°`

.

Next, we see there is a triangle containing the `Y`

angle. I want to know the angle `Z`

at the other corner of the triangle:

The inner angles of a triangle sum up to `180°*(3-2) = 180°`

. Therefore, we know that `180° = 2*Y + Z`

, so `Z = 180° - 2*Y`

. We know that `Y = 72°`

, so we get `Z = 36°`

.

We will use the angle `Z`

a lot. You can see that every corner of the green star has angle `Z`

. The blue star is the same as the green star except it is rotated, so all blue corners also have angle `Z`

. The corners of the red star are twice as wide as the corners of the green and blue stars, so the corners of the red star have the angle `2*Z`

.

## Step 2: Calculating the lengths

First, we observe that all outer corners are on a circle. We call the radius of this circle `R`

. We do not have to calculate `R`

. Instead, we can take any value we want for `R`

. We will always get the same shape but in different sizes. We could call `R`

a "parameter" of the shape.

Given some value for `R`

, I want to know the following lengths:

## Calculating `A`

:

We start with `A`

. We can see the following triangle:

The long side of the triangle is our radius `R`

. The other side has length `A/2`

and we do not care about the third side. The angle in the right-most corner is `Z/2`

(with `Z = 36°`

being the angle we calculated in the previous section). The angle `S`

is a right-angle, so `S = 90°`

. We can calculate the third angle `T`

because we know that the inner angles of a triangle sum up to `180°`

. Therefore, `180° = S + Z/2 + T`

. Solving for `T`

, we get `T = 180° - S - Z/2 = 180° - 90° - 36°/2 = 72°`

.

Next, we use trigonometry to calculate `A/2`

. Trigonometry teaches us that `A/2 = R * sin(T)`

. Putting in the formula for `T`

, we get `A/2 = R * sin(72°)`

. Solving for `A`

, we get `A = 2*R*sin(72°)`

.

If you pick some value for `R`

, for example `R = 100`

, you can now calculate `A`

with this formula. You would need a calculator for `sin(72°)`

, because it would be extremely difficult to calculate this in your head. Putting `sin(72)`

into my calculator gives me `0.951056516`

. So for our choice `R = 100`

, we know that `A = 2 * R * sin(72°) = 2 * 100 * 0.951056516 = 190.211303259`

.

## Calculating `B`

:

We use the same technique to find a formula for `B`

. We see the following triangle:

So the bottom side is the length of our radius `R`

. The right side is `B/2`

. We do not care about the third side. The right-most angle is three times `Z/2`

. The angle `S`

is a right-angle, so we have `S = 90°`

. We can calculate the remaining angle `T`

with `180° = S + T + 3*Z/2`

. Solving for `T`

, we get `T = 180° - S - 3*Z/2 = 180° - 90° - 3*36°/2 = 36°`

. Ok so `T = Z`

, we could have also seen this from the picture, but now we have calculated it anyways.

Using trigonometry, we know that `B/2 = R * sin(T)`

, so we get the formula `B = 2 * R * sin(36°)`

to calculate `B`

for some choice of `R`

.

## Calculating `C`

:

We see the following triangle:

So the bottom side has length `A/2`

and the top side has length `B`

. We already have formulas for both of these sides. The third side is `C`

, for which we want to find a formula. The right-most angle is `Z`

. The angle `S`

is a right-angle, so `S = 90°`

. The top-most angle is three times `Z/2`

.

Using trigonometry, we get `C = sin(Z) * B`

.

## Calculating `D`

:

We see the following triangle:

We already have a formula for `C`

. We want to find a formula for `D`

. The top-most angle is `Z/2`

(I could not fit the text into the triangle). The bottom-left angle `S`

is a right-angle.

Using trigonometry, we know that `D = tan(Z/2) * C`

. The `tan`

function is similar to the `sin`

from the previous formulas. You can again put it into your calculator to compute the value, so for `Z = 36°`

, I can put `tan(36/2)`

into my calculator and it gives me `0.324919696`

.

## Calculating `E`

:

Ok this is easy, `E = 2*D`

.

Halfway done already!

## Calculating `F`

:

This is similar to `A`

and `B`

:

We want to find a formula for `F`

. The top side has length `F/2`

. The bottom side has the length of our radius `R`

. The right-most corner has angle `Z`

. `S`

is a right-angle. We can calculate `T = 180° - S - Z = 180° - 90° - Z = 90° - Z`

.

Using trigonometry, we get `F/2 = R * sin(T)`

. Putting in the formula for `T`

gives us `F/2 = R*sin(90° - Z)`

. Solving for `F`

gives us `F = 2*R*sin(90°-Z)`

.

## Calculating `G`

:

We see the following triangle:

The top side has length `F`

, we already know a formula for it. The right side has length `G`

, we want to find a formula for it. We do not care about the bottom side. The left-most corner has angle `Z/2`

. The right-most corner has angle `2*Z`

. The bottom corner has angle `S`

, which is a right-angle, so `S = 90°`

. It was not immediately obvious to me that the red line and the green line are perfectly perpendicular to each other so that `S`

really is a right-angle, but you can verify this by using the formula for the inner angles of a triangle, which gives you `180° = Z/2 + 2*Z + S`

. Solving for `S`

gives us `S = 180° - Z/2 - 2*Z`

. Using `Z = 36°`

, we get `S = 180° - 36°/2 - 2* 36° = 90°`

.

Using trigonometry, we get `G = F * sin(Z/2)`

.

## Calculating `H`

:

We see the following triangle:

The right side has length `G`

, we already have formula for that. The bottom side has length `H`

, we want to find a formula for that. We do not care about the third side. The top corner has angle `Z`

, the bottom-right corner has angle `S`

. We already know that `S`

is a right-angle from the last section.

Using trigonometry, we get `H = G * tan(Z)`

.

## Calculating `I`

:

This is easy, `I`

is on the same line as `A`

. We can see that `A`

can be divided into `A = I + H + E + H + I`

. We can simplify this to `A = 2*I + 2*H + E`

. Solving for `I`

gives us `I = (A - 2*H - E)/2`

.

## Calculating `J`

:

Again this is easy, `J`

is on the same line as `F`

. We can see that `F`

can be divided into `F = G + J + G`

. We can simplify that to `F = 2*G + J`

. Solving for `J`

gives us `J = F - 2*G`

.

## Writing the Python program

We now have formulas for all the lines we were interested in! We can now put these into a Python program to draw the picture.

Python gives you helper functions for computing `sin`

and `tan`

. They are contained in the `math`

module. So you would add `import math`

to the top of your program, and then you can use `math.sin(...)`

and `math.tan(...)`

in your program. However, there is one problem: These Python functions do not use degrees to measure angles. Instead they use a different unit called "radians". Fortunately, it is easy to convert between degrees and radians: In degrees a full circle is `360°`

. In radians, a full circle is `2*pi`

, where `pi`

is a special constant that is approximately `3.14159265359...`

. Therefore, we can convert an angle that is measured in degrees into an angle that is measured in radians, by dividing the angle by `360°`

and then multiplying it by `2*pi`

. We can write the following helper functions in Python:

```
import math
def degree_to_radians(angle_in_degrees):
full_circle_in_degrees = 360
full_circle_in_radians = 2 * math.pi
angle_in_radians = angle_in_degrees / full_circle_in_degrees * full_circle_in_radians
return angle_in_radians
def sin_from_degrees(angle_in_degrees):
angle_in_radians = degree_to_radians(angle_in_degrees)
return math.sin(angle_in_radians)
def tan_from_degrees(angle_in_degrees):
angle_in_radians = degree_to_radians(angle_in_degrees)
return math.tan(angle_in_radians)
```

We can now use our functions `sin_from_degrees`

and `tan_from_degrees`

to compute `sin`

and `tan`

from angles measured in degrees.

Putting it all together:

```
from turtle import *
import math
# Functions to calculate sin and tan ###########################################
def degree_to_radians(angle_in_degrees):
full_circle_in_degrees = 360
full_circle_in_radians = 2 * math.pi
angle_in_radians = angle_in_degrees / full_circle_in_degrees * full_circle_in_radians
return angle_in_radians
def sin_from_degrees(angle_in_degrees):
angle_in_radians = degree_to_radians(angle_in_degrees)
return math.sin(angle_in_radians)
def tan_from_degrees(angle_in_degrees):
angle_in_radians = degree_to_radians(angle_in_degrees)
return math.tan(angle_in_radians)
# Functions to calculate the angles ############################################
def get_X():
num_corners = 5
return (num_corners-2)*180 / num_corners
def get_Y():
return (360 - 2*get_X()) / 2
def get_Z():
return 180 - 2*get_Y()
# Functions to calculate the lengths ###########################################
def get_A(radius):
Z = get_Z()
return 2 * radius * sin_from_degrees(90 - Z/2)
def get_B(radius):
Z = get_Z()
return 2 * radius * sin_from_degrees(90 - 3*Z/2)
def get_C(radius):
Z = get_Z()
return sin_from_degrees(Z) * get_B(radius)
def get_D(radius):
Z = get_Z()
return tan_from_degrees(Z/2) * get_C(radius)
def get_E(radius):
return 2 * get_D(radius)
def get_F(radius):
Z = get_Z()
return 2 * radius * sin_from_degrees(90 - Z)
def get_G(radius):
Z = get_Z()
return get_F(radius) * sin_from_degrees(Z/2)
def get_H(radius):
Z = get_Z()
return get_G(radius) * tan_from_degrees(Z)
def get_I(radius):
A = get_A(radius)
E = get_E(radius)
H = get_H(radius)
return (A - E - 2*H) / 2
def get_J(radius):
F = get_F(radius)
G = get_G(radius)
return F - 2*G
# Functions to draw the stars ##################################################
def back_to_center():
penup()
goto(0, 0)
setheading(0)
pendown()
def draw_small_star(radius):
penup()
forward(radius)
pendown()
Z = get_Z()
left(180)
right(Z/2)
E = get_E(radius)
H = get_H(radius)
I = get_I(radius)
for i in range(0,5):
penup()
forward(I)
pendown()
forward(H)
penup()
forward(E)
pendown()
forward(H)
penup()
forward(I)
left(180)
right(Z)
back_to_center()
def draw_green_star(radius):
pencolor('green')
draw_small_star(radius)
def draw_blue_star(radius):
pencolor('blue')
Z = get_Z()
left(Z)
draw_small_star(radius)
def draw_red_star(radius):
pencolor('red')
Z = get_Z()
penup()
forward(radius)
pendown()
left(180)
right(Z)
G = get_G(radius)
J = get_J(radius)
for i in range(0,10):
pendown()
forward(G)
penup()
forward(J)
pendown()
forward(G)
left(180)
right(2*Z)
back_to_center()
def draw_shape(radius):
draw_green_star(radius)
draw_blue_star(radius)
draw_red_star(radius)
radius = 400
draw_shape(radius)
done()
```

Output: