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Introduction to Points, Vectors, And Functions - At A Glance:

Imagine we are walking down the street after a tasty supper. We look to our left, and we sight a minotaur ambling down the street with a cup of joe in hand. Distracted, we trip over an overgrown root breaking through the sidewalk. Clumsy us. We land on our backs, only to see, of all things, a griffin flying high overhead. We squint, wondering if our lunch was poisoned, and try to make sense of what we've seen.

Of course, like any studious scholars, we run home and look up what we saw on Shmoop, and we realize that the Minotaur is a harmless half man, half bull, while the griffin is an eagle/lion hybrid out for a post-evening joy flight. It clicks: we saw single, harmless creatures each composed of two animals.

Turns out this is a good way to think about vectors. They are mathematical objects composed of two, easily recognizable parts, magnitude and direction.

Sample Problem

Velocity is a vector, since it has magnitude, or the speed, and direction. "60 miles per hour due east" is a velocity.

Sample Problem

Speed is not a vector. It has magnitude but doesn't include a direction. "60 miles per hour" is a speed, not a velocity.

Most of the vectors that show up in calculus are two-dimensional (2-D). Much like these mythologically astounding sightings, a 2-D vector is like a mutant point. We write a point on the x,y-plane as an ordered pair of coordinates (x,y).
We write a 2-D vector as an ordered pair of components

(notice the pointy brackets instead of parentheses).

We can visualize a 2-D vector as a line segment with an arrow on one end:

The end of the line segment with the arrow is called the head of the vector. The other end is called the tail.

The head end shows which way the vector is going. Like animals and arrows, vectors travel head first.

The components x and y of the vector are like the Δ x and Δ y we use when discussing slope. To get from the tail to the head of the vector , we go over by x and up by y:


When visualizing a 2-D vector as a line segment with its tail at the origin,

  • the magnitude of the vector is the length of the line segment:
  • the direction of the vector is the counterclockwise angle between the positive x-axis and the line segment:

We'll go into more depth about magnitude and direction shortly.

For any point P in the xy-plane, we find a corresponding vector by drawing an arrow with its tail at the origin and its head at P.

For any 2-D vector whose tail is at the origin, we find a corresponding point by drawing a dot at the head of the vector:

We can also say, "there's a one-to-one correspondence between 2-D vectors and points in the xy-plane."

Unless there's a good reason not to, we usually assume a vector has its tail at the origin.

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