Intro to Motion in 2D: Position & Displacement: Videos & Practice Problems

Understanding motion in a two-dimensional plane, often referred to as motion at an angle, is essential for solving various physics problems. Unlike one-dimensional motion, which is confined to either the x-axis (horizontal) or the y-axis (vertical), two-dimensional motion allows for movement in both directions simultaneously. This concept can be visualized by considering a scenario where an object moves from point A to point C at an angle θ, rather than following a straight path along just one axis.

In two-dimensional motion, the movement can be decomposed into two separate one-dimensional motions. For instance, if you were to move from point A to point B and then from point B to point C, you would effectively be combining these two motions. This approach leads to the formation of triangles, which are fundamental in vector analysis.

To analyze motion in two dimensions, it is crucial to break down the movement into its x and y components. This involves applying the principles of average velocity and uniformly accelerated motion (UAM) equations alongside vector equations. By utilizing these combinations, you can effectively solve problems involving two-dimensional motion, treating them as a series of interconnected triangles. This method not only simplifies the analysis but also enhances your understanding of how different motion components interact.

In two-dimensional motion, position and displacement are represented as vectors, which can be visualized as arrows pointing from the origin to a specific point in a coordinate system. The position vector, denoted as \(\vec{r}\), is defined by its coordinates \((x, y)\), indicating where an object is located in the plane. For example, a position vector might be represented as \(\vec{r}_A\) at a distance of 3.6 units at an angle of 33.7 degrees from the origin.

To analyze these vectors, we can decompose them into their x and y components using trigonometric functions. The equations for the components are given by:

\(x = r \cos(\theta)\) and \(y = r \sin(\theta)\).

For instance, if \(\vec{r}_A\) is 3.6 units at 33.7 degrees, the x-component would be calculated as:

\(x_A = 3.6 \cos(33.7^\circ) \approx 3\) and \(y_A = 3.6 \sin(33.7^\circ) \approx 2\).

Similarly, for another position vector \(\vec{r}_B\) with a magnitude of 8.49 units at 45 degrees, the components would be:

\(x_B = 8.49 \cos(45^\circ) \approx 6\) and \(y_B = 8.49 \sin(45^\circ) \approx 6\).

Displacement, on the other hand, is defined as the shortest path between two points, represented as \(\Delta \vec{r}\). It is calculated as the change in position, which can be expressed as:

\(\Delta x = x_B - x_A\) and \(\Delta y = y_B - y_A\).

Using the previous example, if \(x_A = 3\) and \(x_B = 6\), then:

\(\Delta x = 6 - 3 = 3\) and \(\Delta y = 6 - 2 = 4\).

The magnitude of the displacement can be found using the Pythagorean theorem:

\(|\Delta \vec{r}| = \sqrt{(\Delta x)^2 + (\Delta y)^2}\).

Substituting the values gives:

\(|\Delta \vec{r}| = \sqrt{3^2 + 4^2} = 5\) meters.

The direction of the displacement is determined using the inverse tangent function:

\(\theta = \tan^{-1}\left(\frac{|\Delta y|}{|\Delta x|}\right)\).

In this case, it results in:

\(\theta = \tan^{-1}\left(\frac{4}{3}\right) \approx 53^\circ\).

In summary, understanding two-dimensional vectors involves breaking them down into their components and applying trigonometric relationships, while displacement is calculated as the change in position, utilizing both the Pythagorean theorem and inverse tangent for magnitude and direction, respectively.

In this problem, we are tasked with determining the final position vector after a series of movements starting from an initial position. The initial position is given as a vector with a magnitude of 6.2 units at an angle of 25 degrees below the x-axis. This means that the vector points into the fourth quadrant of the coordinate system. To visualize this, we can represent the initial position vector as R_A.

Next, we travel a distance of 9.9 units at an angle of 78 degrees above the positive x-axis, which we will label as R_AB. Finally, we move 2 meters in the negative x direction, represented as R_BC. Our goal is to find the magnitude and direction of the final position vector R_C.

To solve this, we first break down each vector into its x and y components. The components of a vector can be calculated using the following equations:

x = r * cos(θ)

y = r * sin(θ)

For the initial position vector R_A:

x_A = 6.2 * cos(25°) = 5.62

y_A = 6.2 * sin(25°) = -2.62 (negative because it is below the x-axis)

For the displacement vector R_AB:

x_AB = 9.9 * cos(78°) = 2.06

y_AB = 9.9 * sin(78°) = 9.68

For the displacement vector R_BC (which only affects the x-component):

x_BC = -2

y_BC = 0

Now, we can compile these components into a table to sum them up:

Adding the x-components:

x_C = 5.62 + 2.06 - 2 = 5.68

Adding the y-components:

y_C = -2.62 + 9.68 + 0 = 7.06

Now that we have the components of the final position vector R_C, we can calculate its magnitude using the Pythagorean theorem:

|R_C| = √(x_C² + y_C²) = √(5.68² + 7.06²) = 9.06

To find the direction of the vector, we use the inverse tangent function:

θ_C = tan^-1(y_C / x_C) = tan^-1(7.06 / 5.68) = 51.2°

Thus, the final position vector R_C has a magnitude of 9.06 units and is directed at an angle of 51.2 degrees above the positive x-axis.