2-Point Perspective Drawing Tutorial
In this step-by-step lesson we are going to create a simple "2 Point Perspective" view drawing
of our test subject example, working from both plan (overhead) and elevation view (side view
or profile) reference Fig 1. This type of illustration angle is referred to as a "3/4 Perspective"
or an "Angular Perspective" view. The green dots in all of the following perspective grid
diagrams identify the lines to be drawn as shown in each visual example. This type of
perspective grid is best done using vector drawing software such as Adobe Illustrator, where
you can easily drag a single anchor-point on each line drawn, rotating it from the other fixed
anchor-point to create a "projection line" from the fixed point.
The first line to draw will be the horizontal Picture Plane line shown in Fig. 2. By placing the
vertical line (green dot) off-center (to the right) between the two vanishing points we will
ultimately see more of the left side of the subject than the right side. Typically, you want
about the same amount showing on both the left and right side of the object if it is roughly
square (like a laser printer), and a little more showing on the long side of a rectangular object
such as a car or ship.
We will place the lower right corner of our Plan View diagram on the horizontal Picture Plane
line and rotate it clockwise Fig. 3 while keeping it in contact with the picture plane. The
choice of a 30 degree angle for our plan-view diagram is totally arbitrary, but this positioning
provides a good final angle for a typical 3/4 view drawing.
The ultimate angle chosen, and the wide-angle or narrow (telephoto) angle of view should
balance factors such as the best aesthetics for the subject matter being illustrated, and the
necessary technical information (highlighted features) to be conveyed. The subject always
dictates the best observing angle chosen. In
In Fig. 4 we will locate the Station Point which will be located directly below to leading edge
(lower corner) of the diagonal plan-view. Measure the horizontal width of our Plan View (X)
and double it. Extend a vertical line from the corner that touches the Picture Plane downward.
At two times "X" we will locate the Station Point.
Draw lines for the Horizon and Ground Line Fig. 5. The location of these lines are infinitely
variable, but their location will ultimately determine how high or low the viewer is in relation
to the subject. The location of the Ground Line in relation to the Horizon Line will determine
how far above or below "eye level" the object will be viewed. The lower the ground line, the
higher the viewer is in relation to the subject.
If the ground line was located directly on top of the horizon line the viewer (or camera) would
literally be at ground level. The location of the Horizon Line will depend on whether you
want to view the object from above eye-level or below eye-level.
Draw 2 lines from the Station Point (SP) that are parallel to the bottom edges of the Plan
View Fig 6. The lines should intersect with the Picture Plane (points a & b). Next draw
vertical lines from points a & b to the Horizon Line. The point where these vertical lines
intersect the Horizon Line is where the left and right vanishing points (LVP & RVP) will be
located. The location of the vanishing points will determine how sever the perspective is. The
further away they are in relation to the subject, the more "telephoto" the view will be. If the
vanishing points are closer to the subject the view will be more like a wide-angle lens.
The last part of our preliminary layout will be to place the Side Elevation view from Fig. 1
onto the Ground Line, with the furthest left edge aligning with the left vanishing point. Project
a horizontal line (orange dashed line b) from the top of the Elevation View to the vertical Line
of Sight (LS) Fig. 7, below.
We are now ready to start projecting our blue lines to and from the left and right (LVP &
RVP) vanishing points. Referring to Fig. 8, draw lines from both vanishing points to the top
(uppermost surface) and bottom (lowest, ground level surface) reference points of our subject
(points a & b).
To locate each of the vertical lines on our subject, draw lines upward beginning at the Station
Point and intersecting with the left and right corners (a & b) on the plan view diagram Fig. 9.
At the point where these vertical lines intersect the Picture Plane (c & d), draw vertical lines
downward (orange dashed lines) to intersect with the left and right vanishing point's blue
projection lines (green dots).
Using the same procedure as shown in Fig. 9, start constructing all of the smaller features on
the subject as shown in both the Plan View and the Elevation View (a & c) in Fig. 10. Once
located, project these horizontally towards the left and right vanishing points using our blue
projection lines. Then connect each parallel and/or perpendicular intersecting point with a
vertical line to complete the vertical shape. Continue repeating this process through Fig. 11
until all vertical and horizontal surfaces have been completed.
The last step is to darken the object's construction lines, remove all of the blue projection
lines, and add weight ("stroke weight" in Adobe Illustrator) to all of the exterior and outside
edge lines of the object, to increase the readability and visual appeal of the drawing Fig. 12.
In the line drawing examples below, the complex technical illustration shown in Fig. 14 was
created using a very basic 2-point perspective grid (Fig. 13) as a starting point, then fleshing-
out all of the machine's exterior details and constructing all of the internal mechanical
information. The master 2-point perspective grid shown in Fig. 13 was used for all of the
information shown in Fig. 14.
In this example, we used 2-point perspective because the machine was around 6 feet tall and
the horizon line was just above the uppermost vertical point of the subject. By using this angle
of view, all of the vertical lines are nearly perpendicular (90º) to the horizon. If the viewing
location was any higher (looking down on the subject), or much lower (near ground level,
looking upward towards the subject), we would utilize a 3-point perspective grid with a third
(vertical) vanishing point above or below the subject.
By learning and following this basic set of fundamental principles you can create 3D
perspective illustrations of any subject, regardless of complexity.
Any technical illustration is only as good as its weakest element. Perhaps the most important
(and often overlooked) element of any illustration is the ellipse. When an ellipse is executed
correctly it disappears into the overall illustration, but when an ellipse is drawn incorrectly, it
is glaringly obvious. Even the uninitiated eye can spot an incorrectly drawn ellipse, although
they may not be able to identify or articulate why the illustration is amiss. As you will see in
the latter portion of this tutorial, it will not be sufficient to simply "squeeze" to circle into an
ellipse, then rotate it onto a vertical or horizontal plane, as this does not properly address the
receding aspects of that plane.
In this lesson we are going to learn the principles of drawing a circle as a vector ellipse in a 1
point Perspective and 2 Point Perspective view, using Adobe Illustrator. For this tutorial it is
important to use vector drawing software such as Adobe Illustrator or CorelDRAW. In this
case, we will be using Illustrator's Free Transform tool to distort the shape and "aspect ratio"
or "ellipse ratio" of the circle to make it appear to be in perspective.
Basics of Drawing an Ellipse in Illustrator
We will start out by drawing a perfectly round circle with a 90 degree (1:1) width to height
ratio Fig. 1, using Adobe Illustrator's 'Ellipse Tool' (L). Our circle is positioned inside a
square box (blue line) with equal height and width, created using Illustrator's 'Rectangle Tool'
(M). The major axis of the circle is represented by a magenta vertical line and there are green
bullet points at each intersection of the major axis to the outer edge of the circle. Adobe
Illustrator Tip: Hold the 'Shift' key while dragging, to constrain the 'Rectangle Tool' and
'Ellipse Tool' to a perfect circle and/or square.
In Fig. 2 the minor axis of the circle is represented by a magenta horizontal line and again
there are green bullet points at each intersection of the major axis to the outer edge of the
circle. The major axis and the minor of the circle intersect at the center point of the circle and
are at a 90 degree angle to each other as shown in Fig. 3.
In Fig. 4, 5, & 6 we have rotated the major axis by 20 degrees (clockwise) and we have
changed the ratio between the major and minor axis. The left ellipse (fatter ellipse) now has a
40 degree (1:1.55) width to height ratio and the right ellipse (skinnier ellipse) has a 20 degree
(1:2.92) ratio. As in the examples above, we have marked the intersecting points between the
outer diameter of the circle and the major and minor axis points.
Drawing a 1-Point Perspective Ellipse
We will now begin to construct an ellipse in 1 point perspective. We will start by drawing
diagonal lines that intersect with all four corners of the blue box that surrounds our circle. In
Fig. 7 these intersection points are marked with green bullet points. If we were to simply
decrease the width of the minor axis in relation to the major axis we would create an isometric
image of our circle Fig. 8. A true isometric ellipse is approximately 35 degrees with a ratio of
1:1.75. An isometric image has no perspective and all parallel straight lines are at the same
angle. For more information on isometric vs. perspective drawing go to the: 2 Point
Perspective Drawing Tutorial.
In Fig. 9 we have created an artificial 3 dimensional environment with a "1 point Perspective
Grid." This means that there is only one vanishing point along the horizon line. In this
example, our horizon line is also our minor axis. You will notice that the major axis is not
aligned to the center point of the ellipse as it was in our isometric ellipse in Fig 8. The new
major axis is now aligned to the perspective center point marked with a green bullet point and
the left and right side of the circle are very different in size and shape. These are the distinct
characteristics of a "Perspective Ellipse".
The next step will be to divide a receding plane into equally divided increments. Starting in
the upper left corner (A) of our boxed ellipse (Fig. 10), we will draw a diagonal line (solid
blue) until it intersects the mid-point (B) of the boxed ellipse along the horizon and minor axis
line. Continue the diagonal (solid blue) line until it intersects with the lower vanishing point
line (C). From that point we will draw a vertical line upward until it intersects the upper
vanishing point line. This will now define a square that is the same "size" as our first square
containing the circle (now an ellipse).
Repeat the process outlined in the preceding paragraph until you have five equally divided
square spaces (Fig. 11). Now form a second ellipse in the last (5th) space. You will notice that
not only has the vertical size of the ellipse diminished as we recede towards the vanishing
point, but the width and ellipse ratio has changed as well. Our first ellipse (foreground left) is
30 degrees with a ratio of 1:2 and our second ellipse (background right) is 20 degrees with a
ratio of 1:2.92. This phenomenon is due to the fact that the viewer is at a steeper angle of view
when looking an object that is in close proximity as opposed to an object of the same size that
is farther away (Fig. 12) and therefor, viewed at a shallower angle. The "picture plane" in Fig
12 represents the observer's perception of perspective.
In the physical world, the "picture plane" in Fig. 12 represents the observer's perception of
perspective as interpreted by the lens of the eye. In the world of illustration, the "picture
plane" is actually the flat surface of the paper or computer screen, and the perception of 3
dimensional depth or perspective is an illusion.
2 Point Perspective Ellipses
Now we will create a 2 point perspective grid (Fig. 12) using the same principles that were
used in Fig. 9 through 11. Start with a horizon line and create both a left and right vanishing
point. From the right vanishing point (RVP) we will project our ellipse centerline as well as
an upper and lower vanishing point line. Create your equally spaced divisions just as you did
in Fig 10.
From the left vanishing point (LVP), project your minor axis line until it intersects the center
point of the first (foreground) box and beyond. Now draw your vertical major axis line so that
it intersects with the center point of the ellipse box (green bullet point). Keep in mind that
even though the major axis line should always be at a 90 degree angle to the minor axis line,
we ill place less importance on it when constructing a 2 point perspective ellipse..
Now that our perspective grid is constructed we will start to fill in the foreground and
background ellipse. In our foreground ellipse box (Fig. 14) you can see that if we were to
simply take a 30 degree ellipse (roughly the correct ratio) generated by the Ellipse Tool (L) in
Adobe Illustrator and rotate it so that the major and minor axes line up (green ellipse) it does
not look correct. Even if the green ellipse touches all for sides of the ellipse box, it does not
touch them in the correct locations (see Fig. 15). As mentioned in the preceding paragraph,
this is why we will not rely on the major axis to construct our 2 point perspective ellipse.
In Fig. 15 we see that the points at which our green ellipse intersects the blue box (red arrows)
are in the wrong locations. A correct ellipse should intersect with the blue box at the four
center points indicated by the green bullet points. Additionally, our green ellipse in Fig 15
does not intersect with the diagonal blue lines in our box template.
The solution for this problem is to use our vanishing points to construct a smaller box of the
exact same proportions (equal width-to-height ratio) within our main template box Fig. 16.
This smaller box will identify the correct intersecting points that our ellipse must make
contact with (Fig. 16). Keep in mind that the Ellipse Tool (L) in Adobe Illustrator is not
capable of creating this type of ellipse. But do not despair, there is an easy way of doing this
using a quick workaround solution which will be covered in the following sections.
Note: The point of the inner square shown in Fig 16 is to show how an isometric ellipse
(using Illustrator's Ellipse Tool) will not meet the requirements of a true perspective ellipse. It
is not the "size" of the inner square that matters, but the fact that all four of its corners are
capable of touching the ellipse. If this does not, or can not happen (as in Fig 15), you do not
have a true perspective ellipse.
Our last example in Fig. 17 shows a comparison between an Adobe Illustrator "Ellipse Tool"
generated ellipse (dashed green line) and a modified and corrected ellipse (solid black line).
Now we will remove our constraint grid boxes (blue lines) and evaluate the overall
appearance of the corrected ellipse (Fig. 18). This is where things get a bit tricky. As you can
see, our ellipse still does not "look" correct. Remember that our goal is to "deceive" the
viewer into perceiving a 3 dimensional object while looking at a flat 2 dimensional image.
This is where the "fudge factor" comes into play. There are complicated mathematical
equations that can solve some of these issues, but in the real world of commercial illustration,
deadlines provide insufficient time for using this method to complete the illustration. A quick
and easy solution (Fig. 19) is to rotate the "corrected" ellipse enough to split the difference
between our corrected ellipse (dashed red line) and the Adobe Illustrator Ellipse Tool
isometric ellipse (dashed green line).
Our final example in Fig. 20 (above) shows a compromise between technical accuracy and
visual trickery. Once incorporated into the overall illustration, you will find that this technique
produces very natural looking ellipses that blend nicely with the perspective of the object they
belong to.
All of the principles covered in this ellipse tutorial were utilized to create this line drawing of
a linear accelerator shown in the screenshot above. By learning and following this basic set of
drawing fundamentals you can create perspective illustrations of any subject, regardless of the
level of complexity.