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Chapter 11: Problem 63

Find the dot product of each pair of vectors. $$\langle 2,-3\rangle,\langle 6,5\rangle$$

Short Answer

Expert verified
The dot product is -3.

Step by step solution

01

Identify the vectors

We are given two vectors: \( \langle 2, -3 \rangle \) and \( \langle 6, 5 \rangle \). The first vector is represented as \( \mathbf{a} = \langle 2, -3 \rangle \) and the second vector as \( \mathbf{b} = \langle 6, 5 \rangle \).
02

Apply the dot product formula

The dot product of two vectors \( \mathbf{a} = \langle a_1, a_2 \rangle \) and \( \mathbf{b} = \langle b_1, b_2 \rangle \) is calculated by the formula: \( \mathbf{a} \cdot \mathbf{b} = a_1 \times b_1 + a_2 \times b_2 \). For these vectors, let \( a_1 = 2 \), \( a_2 = -3 \), \( b_1 = 6 \), and \( b_2 = 5 \).
03

Calculate the product of corresponding components

First, compute the product of the first components: \( a_1 \times b_1 = 2 \times 6 = 12 \). Then, compute the product of the second components: \( a_2 \times b_2 = -3 \times 5 = -15 \).
04

Sum these products

Add the products from Step 3 to get the dot product: \( 12 + (-15) = 12 - 15 = -3 \).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Vectors
Vectors are fundamental objects in mathematics that hold both magnitude and direction. They are commonly represented in a coordinate system, such as the two-dimensional plane, where a vector is displayed as an arrow pointing from an initial point to a terminal point. In this representation, a vector is expressed in component form, like \( \langle a_1, a_2 \rangle \), where \( a_1 \) and \( a_2 \) are the horizontal and vertical components, respectively. For example, consider a vector \( \langle 2, -3 \rangle \):
  • \( a_1 = 2 \) represents the movement along the x-axis.
  • \( a_2 = -3 \) represents movement along the y-axis, emphasizing direction with a negative sign.

Vectors are foundational in fields like physics and engineering, where they describe forces, velocities, and other quantities.
Vector Multiplication
Vector multiplication can occur in different ways, but one of the most common is the dot product. This type of multiplication results in a scalar, or single number, hence the term scalar product is also used. The dot product is vital for calculating projections and understanding the relationship between vectors, especially in determining angles and verifying orthogonality. In our exercise with vectors \( \langle 2, -3 \rangle \) and \( \langle 6, 5 \rangle \):
  • We multiply the corresponding components for each vector.
  • The operation involves a simple multiplication following the order of the given components.

This method allows us to move from the geometric intuition of vectors to a more numerical and analytical perspective.
Dot Product Formula
The dot product formula is a staple in vector mathematics. This computation was shown in our exercise as: \( \mathbf{a} \cdot \mathbf{b} = a_1 \times b_1 + a_2 \times b_2 \). It's a sum of products from paired vector components. In simpler terms:
  • Multiply the first components of each vector.
  • Multiply the second components.
  • Add these products to obtain the dot product.

For the vectors given, this results in \( 2 \times 6 + (-3) \times 5 = 12 - 15 = -3 \). The dot product gives insight into the directional alignment of the vectors. If the dot product is zero, vectors are perpendicular.
Mathematical Calculations
Mathematical calculations are procedures or operations that involve numbers and symbols to determine quantities. They are critical in understanding concepts like the dot product. In our context, calculations involve:
  • Accurate multiplication of components from each vector.
  • Adding those results to find a single scalar value.
  • Attention to signs and arithmetic rules, as seen in \( 12 - 15 = -3 \).

These operations highlight the precision necessary in mathematics to achieve correct and meaningful results. Mastering calculations in dot products helps form a solid base for more advanced topics in vector algebra and linear transformations.

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Most popular questions from this chapter

Do the following. (a) Determine the parametric equations that model the path of the projectile. (b) Determine the rectangular equation that models the path of the projectile. (c) Determine the time the projectile is in flight and the horizontal distance covered. A model rocket is launched from the ground with a velocity of 48 feet per second at an angle of \(60^{\circ}\) with respect to the ground.

For each equation, find an equivalent equation in rectangular coordinates. Then graph the result. $$r=\frac{3}{4 \cos \theta-\sin \theta}$$

Radio stations sometimes do not broadcast in all directions with the same intensity. To avoid interference with an existing station to the north, a new station may be licensed to broadcast only east and west. To create an east- west signal, two radio towers are used, as illustrated in the figure. (IMAGE CAN'T COPY). Locations where the radio signal is received correspond to the interior of the lemniscate..$$r^{2}=40,000 \cos 2 \theta$$.Where the polar axis (or positive \(x\) -axis) points east. (A) Graph $$r^{2}=40.000 \cos 2 \theta$$. For \(0^{\circ} \leq \theta \leq 180^{\circ},\) with units in miles. Assuming that the radio towers are located near the pole, use the graph to describe the regions where the signal can be received and where the signal cannot be received. (B) Suppose a radio signal pattern is given by $$r^{2}=22,500 \sin 2 \theta$$ for \(0^{\circ} \leq \theta \leq 180^{\circ} .\) Graph this pattem and interpret the results.

Graph each pair of parametric equations for \(0 \leq t \leq 2 \pi\) in the window \([0,6.6]\) by \([0,4.1] .\) Identify the letter of the alphabet that is being graphed. $$\begin{aligned} &x_{1}=2+0.8 \cos 0.85 t, \quad y_{1}=2+\sin 0.85 t\\\ &x_{2}=1.2+\frac{t}{1.3 \pi}, \quad y_{2}=2 \end{aligned}$$

Graph each pair of parametric equations. $$x=\cos ^{5} t, y=\sin ^{5} t ; 0 \leq t \leq 2 \pi$$
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