A perpendicular line It is one that forms an angle of 90º with respect to another line, curve or surface. Note that when two lines are perpendicular and are on the same plane, when they intersect they form four identical angles, each one of 90º.
If one of the angles is not 90º, the lines are said to be oblique. Perpendicular lines are common in design, architecture and construction, for example the network of pipes in the following image.
The orientation of the perpendicular lines can be diverse, such as those shown below:
Regardless of the position, the lines perpendicular to each other are recognized by identifying the angle between them as 90º, with the help of the protractor.
Note that unlike parallel lines in the plane, which never intersect, perpendicular lines always do so at a point P, called foot of one of the lines over the other. Therefore two perpendicular lines are also blotters.
Any line has infinite perpendiculars to it, since just by moving segment AB to the left or right over segment CD, we will have new perpendiculars with another foot.
However, the perpendicular that passes just through the midpoint of a segment is called bisector of said segment.
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Perpendicular lines are common in the urban landscape. In the following image (figure 3), only a few of the many perpendicular lines that can be seen in the simple facade of this building and its elements such as doors, ducts, steps and more have been highlighted:
The good thing is that three lines perpendicular to each other help us to establish the location of points and objects in space. They are the coordinate axes identified as X axis, Axis y Y z axis, clearly visible in the corner of a rectangular room like the one below:
In the panoramic view of the city, on the right, the perpendicularity between the skyscraper and the ground is also noticeable. The first, we would say, is found along the z axis, while the ground is a plane, which in this case is the plane xy.
If the ground constitutes the plane xy, the skyscraper is also perpendicular to any avenue or street, which guarantees its stability, since a sloping structure is unstable.
And on the streets, wherever there are rectangular corners, there are perpendicular lines. Many avenues and streets have a perpendicular layout, as long as the terrain and geographical features allow it..
To express abbreviated perpendicularity between lines, segments or vectors, the symbol ⊥ is used. For example, if the line L1 is perpendicular to the line Ltwo, we wrote:
L1 ⊥ Ltwo
- In the design the perpendicular lines are very present, since many common objects are based on squares and rectangles. These quadrilaterals are characterized by having internal angles of 90º, because their sides are parallel two by two:
- The fields in which different sports are practiced are demarcated by numerous squares and rectangles. These in turn contain perpendicular lines.
- Two of the segments that make up a right triangle are perpendicular to each other. These are called legs, while the remaining line is called hypotenuse.
- The lines of the electric field vector are perpendicular to the surface of a conductor in electrostatic equilibrium.
- For a charged conductor, the equipotential lines and surfaces are always perpendicular to those of the electric field.
- In piping or conduit systems used to transport different kinds of fluids, such as gas shown in Figure 1, right-angle elbows are common. Therefore they form perpendicular lines, such is the case of a boiler room:
Draw two perpendicular lines using a ruler and compass.
It is very simple to do, following these steps:
-The first line is drawn, called AB (black).
-Above (or below if you prefer) AB mark point P, through which the perpendicular will pass. If P is just above (or below) the middle of AB, this perpendicular is the bisector of segment AB.
-With the compass centered on P, draw a circle that cuts AB at two points, called A 'and B' (red).
-The compass is opened at A'P, it is centered on A 'and a circle is drawn that passes through P (green).
-Repeat the previous step, but now opening the measure the length of the segment B'P (green). Both arcs of circumference intersect at point Q below P and of course at the latter.
-The points P and Q are joined with the ruler and the perpendicular line (blue) is ready.
-Finally, all auxiliary constructions must be carefully erased, leaving only the perpendicular ones..
Two lines L1 and Ltwo are perpendicular if their respective slopes m1 and mtwo meet this relationship:
m1 = -1 / mtwo
Given the line y = 5x - 2, find a line perpendicular to it and that passes through the point (-1, 3).
-First, find the slope of the perpendicular line m⊥, as indicated in the statement. The slope of the original line is m = 5, the coefficient that accompanies “x”. Then:
m⊥= -1/5
-Then the equation of the perpendicular line is constructed and⊥, substituting the previously found value:
Y⊥= -1 / 5x + b
-Next, the value of b is determined, with the help of the point given by the statement, (-1,3), since the perpendicular line must pass through it:
y = 3
x = -1
Substituting:
3 = -1/5 (-1) + b
Solve for the value of b:
b = 3- (1/5) = 14/5
-Finally the definitive equation is constructed:
Y⊥= -1 / 5x + 14/5
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