### Introduction

In lesson #1 we have introduced the concept of *geometry* above an art work. We have been describing the *Euclidean* geometry as the most common geometry used in art.

In lesson #2 we have bypass the *Euclidean* geometry and introduce a new one: the *spherical* geometry which gives more FOV power to the artist.

in lesson #3 we have introduce the notion of *E.G.G* (Equirectangular Geodesical Grid) and we have shown how to refer a point P through its *latitude* and *longitude* angles. Since the E.G.G it is just a piece of paper (with ratio 2:1) Lesson #3 shifts from Cartesian coordinates (x,y,z) to spherical coordinates (latitude,longitude). This is a disruptive understanding of the space thus it changes the way our mind works when we are drawing. Instead of indexing visual information through its length, height and deepness (that is Cartesian space) we are referring the same point with two angles. So, when the next time you will draw from observation, I would like you to consider these two angles. Say your drawing a table just in front of you, this table is then located at a range of [-10º,+10º] in longitudes and a range of [+5º,0º] in latitudes ranges. It get some time to integrate this new habit, but, we are already getting paid by posting! So the new revolution also spreads to different activities in life 🙂

In this lesson, we are going to focus on how objects are printed in the E.G.G when we are close to them or they are located just in front of our head. I will show you a powerful technique that will make you love the poles equirectangular *distortion*.

So, let’s start, this class is going to be very very practical!

### Understanding distortion

I guess this is not the first time you see this projection of the Earth:

*Equirectangular projection*(source) licence: JPL Image Policy

Let’s call our mathematician inside us :

*The Poles singularity*(source)(Licence:public domain image)

*longitude*of the North Pole?

- 10º! -one says
- 0º ! -another answer

Come on! we are in *steemit* this is not FB! so please, use your brains!

*any*

*only*by its Latitude.

Remember, in Lesson 3 6 vanishing points where announced, and 2 of them were not a point but a line:

from lesson 3:

[…] We have 6 vanishing points in our Egg.

- Front, just in the middle
- Right, at 90º from the front
- Left at -90º from the front
- Back vanishing point which is half on the left side and half on the right side
- Finally, up and down. See those to thick lines next to the border of the Egg? Those are up and down vanishing points.

So, when we project both North and South poles in the equirectangular file we obtain lines instead of vanishing point.

### Block and triumph!

In this section, we are going to describe a powerful technique to deal with this particular distortion.

We are going to sketch different boxes in our E.G.G file. If you want to try with your own boxes, you can download a clean Egg file here.

For each sample, I have typed the VR link in order to compare between VR support (that is, inside the sphere) and Egg supports.

(feel free to register in veer.tv until our development guys enable us a viewer in steemit.com)

Now, plot 4 points in your egg file and connect them following the geodesic grid lines, this should build the table plane. Complete with another 2 points to give same deepness to the box. You should obtain a box like this:

*Illustration by Author*

Next, imagine you are sitting in your desk, very close to the table so that the ends of the table make 180º, that is , you should turn left and right your head to see the borders. When you turn left your head, tipically you may turn 90º so, plot two points under the -90º vanishing point. Do the same when you turn right- You have to obtain the funny figure in the bottom of the E.G.G

*Illustration by Author*

No, click on the link below to really see how is the desk when it comes to the sphere. You can recognize it? 🙂VR Support

You can also plot boxes in the orientation you like into the Egg. The process is always the same, plot the points and then connect them through a geodesic line. This remains me a book a read long time ago: *Point and Line To Plane* from Wassily Kandinsky. This Russian painter used to say that a good drawing ends when there are no irrelevant points or lines. I think I have to go visit his grave and make him an advise: Lines? what lines? G-E-O-D-E-S-I-C-S man, G-E-O-D-E-S-I-C-S !! (you can ask your fellow math and he will show you that a geodesic is *also* a straight line).

*Illustration by Author*

VR SupportFinally, let’s draw something on the top of our heads: Always the same principle, plot points and connect them with the geodesics.

*Illustration by Author*

VR Support

### Conclusions

In this lesson, we have explained the singularity of the poles in the equirectangular projection and we have practiced with a very easy technique to draw boxes in our Egg file.

Now, you have all the background to practice and make your owns 360º or panoramic degrees.

More to come in next lessons, I have not decided yet the content of Lesson 5, but, for sure, I have to talk about 3 point persepective and how does in work in the Egg, I could also talk about _ spherical anamorphic_ grid, which is a kind of grid more an more popular in some Koreans cartoonist. We’ll see.

*360º*fun!

2D Shapes: It is easy to draw perfect shapes with our collection of 2D shapes and the line and curve tool. Use the control circles to manipulate the curvature to your desired angle. You can also click Make 3D to turn the shape into a layer with additional rotation options.