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Vector Applications

Vector Applications

Vectors are incredibly useful for modeling real-world situations where quantities have both a magnitude (size) and a direction. The most common applications of vectors in physics and mathematics involve forces, velocities, and navigation.

Resolving Vectors into Components

Often, you will know the magnitude and direction of a single vector, but you need to know its horizontal and vertical effects. This is called resolving a vector into its components.

If a vector vโƒ—\vec{v} has a magnitude โˆฃโˆฃvโƒ—โˆฃโˆฃ||\vec{v}|| and makes an angle ฮธ\theta with the horizontal, its components are: vx=โˆฃโˆฃvโƒ—โˆฃโˆฃcosโก(ฮธ)v_x = ||\vec{v}|| \cos(\theta) vy=โˆฃโˆฃvโƒ—โˆฃโˆฃsinโก(ฮธ)v_y = ||\vec{v}|| \sin(\theta)

Example: A 100-lb force acts at an angle of 30โˆ˜30^\circ from the horizontal. Find the horizontal and vertical components.

  • Horizontal force: Fx=100cosโก(30โˆ˜)=100(32)=503F_x = 100 \cos(30^\circ) = 100 \left(\frac{\sqrt{3}}{2}\right) = 50\sqrt{3} lbs.
  • Vertical force: Fy=100sinโก(30โˆ˜)=100(12)=50F_y = 100 \sin(30^\circ) = 100 \left(\frac{1}{2}\right) = 50 lbs.

Resultant Vectors

When multiple forces or motions act on an object simultaneously, their combined effect is called the resultant vector. You can find the resultant by adding the individual vectors together.

Example: A boat heads east at 20 mph while the current flows north at 5 mph. Find the resultant speed and direction.

  1. Write the vectors: The boat's velocity is Bโƒ—=โŸจ20,0โŸฉ\vec{B} = \langle 20, 0 \rangle and the current's velocity is Cโƒ—=โŸจ0,5โŸฉ\vec{C} = \langle 0, 5 \rangle.
  2. Add them: The resultant velocity Rโƒ—=Bโƒ—+Cโƒ—=โŸจ20,5โŸฉ\vec{R} = \vec{B} + \vec{C} = \langle 20, 5 \rangle.
  3. Find the speed (magnitude): โˆฃโˆฃRโƒ—โˆฃโˆฃ=202+52=400+25=425โ‰ˆ20.6ย mph||\vec{R}|| = \sqrt{20^2 + 5^2} = \sqrt{400 + 25} = \sqrt{425} \approx 20.6 \text{ mph}
  4. Find the direction: Use the tangent function to find the angle. tanโก(ฮธ)=520=0.25\tan(\theta) = \frac{5}{20} = 0.25 ฮธ=tanโกโˆ’1(0.25)โ‰ˆ14.04โˆ˜\theta = \tan^{-1}(0.25) \approx 14.04^\circ The boat is traveling at approximately 20.6 mph at an angle of 14.04โˆ˜14.04^\circ north of east.

Equilibrium

An object is in a state of equilibrium when the sum of all forces (the resultant vector) acting on it is zero. If you have several forces acting on an object and it isn't moving, you know that their vector sum must equal โŸจ0,0โŸฉ\langle 0, 0 \rangle. This principle is widely used to calculate unknown tensions in cables or structural supports.