# How do I draw this shape in Turtle? [closed]

I got a challenge in a learning group today to draw this shape in python turtle library.

I cannot figure out a way to express the geometrical solution to find the angles to turn and the size of the line I need.

Can you please tell me how to draw the first polygon alone? I already know how to make the pattern.

I am in fifth grade. So please give me a solution that I can understand.

• Welcome to StackOverflow, Tes. Can you clarify what you mean by "drawing the first polygon alone"? Are you asking how to draw for example this part i.imgur.com/H2wX19n.png or this part i.imgur.com/KcdEpON.png or another part? May 15, 2020 at 19:48
• You can find some information in Wikipedia on this kite polygon shape. May 15, 2020 at 21:07

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:

## 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`.

## 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

full_circle_in_degrees = 360

def sin_from_degrees(angle_in_degrees):

def tan_from_degrees(angle_in_degrees):
``````

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 ###########################################

full_circle_in_degrees = 360

def sin_from_degrees(angle_in_degrees):

def tan_from_degrees(angle_in_degrees):

# 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 ###########################################

Z = get_Z()
return 2 * radius * sin_from_degrees(90 - Z/2)

Z = get_Z()
return 2 * radius * sin_from_degrees(90 - 3*Z/2)

Z = get_Z()

Z = get_Z()

Z = get_Z()
return 2 * radius * sin_from_degrees(90 - Z)

Z = get_Z()

Z = get_Z()

return (A - E - 2*H) / 2

return F - 2*G

# Functions to draw the stars ##################################################

def back_to_center():
penup()
goto(0, 0)
pendown()

penup()
pendown()

Z = get_Z()

left(180)
right(Z/2)

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()

pencolor('green')

pencolor('blue')

Z = get_Z()
left(Z)

pencolor('red')

Z = get_Z()

penup()
pendown()

left(180)
right(Z)

for i in range(0,10):
pendown()
forward(G)

penup()
forward(J)

pendown()
forward(G)

left(180)
right(2*Z)

back_to_center()

done()
``````

Output:

• Please tell me, how can I post a turtle animation like you did?
– Red
May 19, 2020 at 16:52
• I didn't find an automatic way to do it (there probably is), so I used a screen-recording program (simplescreenrecorder on Linux) to record an mp4 of the window and then converted the mp4 to gif using ffmpeg. May 19, 2020 at 16:59
• @AnnZen, if you use a Mac, then see Make an animated GIF from Python turtle using Preview on OSX but be warned that the latest OSX breaks some of the steps since this was a useful thing to be able to do. May 21, 2020 at 16:56
• Thanks, but I don't use mac.
– Red
May 21, 2020 at 17:02

Here's a different solution. It's based on a kite polygon where the upper portion is a pair of 3-4-5 right triangles and the lower portion is a pair of 8-15-17 right triangles:

``````from turtle import Screen, Turtle

KITES = 10

def kite(t):
t.right(37)
t.forward(100)
t.right(81)
t.forward(170)

t.right(124)

t.forward(170)
t.right(81)
t.forward(100)
t.right(37)

turtle = Turtle()
turtle.penup()

for _ in range(KITES):
turtle.pendown()

kite(turtle)

turtle.penup()

turtle.hideturtle()

screen = Screen()
screen.exitonclick()
``````

(Yes, I'm obsessed with this puzzle.) I was sufficiently impressed by the brevity of @AnnZen's solution, I decided to see if I could come up with an even shorter one. The only unique structure in this polygon is the side of the kite:

So the problem becomes drawing ten of these in a circular fashion, and then reversing the code to draw them again in the opposite direction:

``````from turtle import *

for _ in range(2):
for _ in range(10):
fd(105)
lt(90)
fd(76.5)
pu()
bk(153)
rt(54)
pd()

lt(72)
lt, rt = rt, lt

done()
``````

# My Short code:

``````from turtle import *
for f, t in [(0,-72),(71,108),(71,0)]*10+[(29,90),(73,72),(73,90),(29,72)]*10:fd(f),rt(t)
``````
• Ann, my eyeballing of this nifty solution suggests that if you change your second array to instead be `[(28.9, 90), (72.6, 72), (72.6, 90), (28.9, 72)]` you'll get a cleaner result. May 19, 2020 at 22:01
• Cool, if you eyeballed it. Did you really?
– Red
May 19, 2020 at 22:34
• Yes, I broke it into two loops for the two arrays, lifted the pen and instead printed dots on each iteration, two colors for the two loops. Then I could see where the subset of dots from the two loops that should overlap didn't, and by how much. Tweaking individual numbers up and down, I was able to get them to align. I rarely "do the math". May 20, 2020 at 16:09

# Here's the solution:

``````import turtle
#turtle.tracer(0)
a = turtle.Turtle()
for _ in range(10):
a.forward(100)
a.right(90)
a.forward(73)
a.right(72)
a.forward(73)
a.backward(73)
a.right(108)
a.forward(73)
a.right(90)
a.penup()
a.forward(100)
a.pendown()
a.forward(100)
a.right(108)
#turtle.update()
``````

• Your solution is much shorter than mine :) Did you calculate the values by hand? May 16, 2020 at 15:51
• Yes, measured some angles and did some calculations.
– Red
May 16, 2020 at 15:54
• Your three step sequence: `a.left(180); a.forward(73); a.left(72)` can be shortened to the two step sequence: `a.backward(73); a.right(108)` and the turn: `a.left(252)` can also be written: `a.right(108)` May 17, 2020 at 2:48
• You're right, I didn't realize it, thanks.
– Red
May 17, 2020 at 3:55

Let's look at a yet another approach to drawing this shape. We'll start with the same diagram as @f9c69e9781fa194211448473495534

Using a ruler (1" = 100px) and protractor on the OP's original image, we can approximate this diagram with very simple code:

``````from turtle import Screen, Turtle

turtle = Turtle()
turtle.hideturtle()
turtle.penup()  # center on the screen
turtle.setposition(-170, -125)
turtle.pendown()

for _ in range(10):
turtle.forward(340)
turtle.left(126)
turtle.forward(400)
turtle.left(126)

screen = Screen()
screen.exitonclick()
``````

This is equivalent to drawing with a pencil and not lifting it nor overdrawing (backing up) on any line.

To make the shape we want pop out, we divide the two lines that we draw above into segments that are thinner and thicker. The first line breaks into three segments and the second into five:

To do this, we simply break the `forward()` calls in our loop into wide and narrow segments:

``````for _ in range(10):
turtle.width(4)
turtle.forward(105)
turtle.width(1)
turtle.forward(130)
turtle.width(4)
turtle.forward(105)

turtle.left(126)

turtle.width(1)
turtle.forward(76.5)
turtle.width(4)
turtle.forward(76.5)
turtle.width(1)
turtle.forward(94)
turtle.width(4)
turtle.forward(76.5)
turtle.width(1)
turtle.forward(76.5)

turtle.left(126)
``````

Finally, we replace the thickness changes with lifting and lowering the pen:

Which is simply a matter of replacing the `width()` calls with `penup()` and `pendown()`:

``````for _ in range(10):
turtle.pendown()
turtle.forward(105)
turtle.penup()
turtle.forward(130)
turtle.pendown()
turtle.forward(105)

turtle.left(126)

turtle.penup()
turtle.forward(76.5)
turtle.pendown()
turtle.forward(76.5)
turtle.penup()
turtle.forward(94)
turtle.pendown()
turtle.forward(76.5)
turtle.penup()
turtle.forward(76.5)

turtle.left(126)
``````