Complete The Template That Has Attached: Find A Picture From

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Complete The Template That Have Attachedfind A Picture From A

Complete The Template That Have Attachedfind A Picture From A Media source (movies, TV, comics, video games, etc.) that contains at least two different moving objects, one of which is flying through the air. Place the picture in the following diagram template and cite the image using APA format: 1. Move and resize the red circle so that it is around the moving object with the largest inertia and label it in the key. 2. Move and resize the green circle so that it is around the moving object with the smallest inertia and label it in the key. 3. Move, resize, and rotate the blue arrow so that it shows the magnitude and direction of the gravity acting on the flying object. 4. Move, resize, and rotate the purple arrow so that it shows the magnitude and direction of the the flying object's vertical velocity. 5. Move, resize, and rotate the green arrow so that it shows the magnitude and direction of the the flying object's horizontal velocity. 6. Save your diagram as a PDF or image file and upload the completed diagram below.

Paper For Above instruction

The task requires selecting a media image illustrating at least two moving objects, with one airborne, and then analyzing these objects using physics concepts. To demonstrate understanding, I will select a popular scene from the movie "The Avengers" where Iron Man flies through the sky alongside other moving characters. This scene captures multiple moving entities, including Iron Man in flight and other characters or objects on the ground. The chosen image appropriately depicts the dynamic motion essential for analyzing inertia, velocity, and forces acting upon the flying object.

The first step involves placing a red circle around the moving object with the largest inertia. In this context, Iron Man in his flying suit, due to his mass and momentum, qualifies as the object with the greatest inertia. A red circle will be resized and positioned to encompass Iron Man, ensuring clear visualization of this primary moving entity. This labeling assists in distinguishing the object with dominant inertia.

Next, a green circle is centered around the smaller moving object with the least inertia—possibly a drone or a smaller flying vehicle or object within the scene. Resizing and positioning this green circle accurately highlights this less massive object for comparison in the analysis.

The blue arrow represents the gravity vector affecting the flying object. Gravity acts downward, so the arrow is rotated to point vertically downward, with its size proportional to the magnitude of gravitational force based on Iron Man's mass and gravity acceleration (assuming standard gravity). This vector visually expresses the gravitational pull, emphasizing its role in the object's flight path.

The purple arrow illustrates the vertical component of Iron Man’s velocity. Its length corresponds to the magnitude of vertical velocity, pointing upward if ascending or downward if descending. Its orientation indicates the vertical direction of movement relative to the scene, providing insight into the initial or current flying motion.

Finally, the green arrow indicates the horizontal velocity of Iron Man. This vector points in the scene's direction of horizontal motion, with its length proportional to the magnitude of horizontal velocity. It depicts how fast and in what direction Iron Man is moving across the scene, contributing to the overall understanding of his kinematic state.

Once these visual elements are correctly placed, resized, and oriented, the diagram is saved as a PDF or image file. This visual and analytical representation encapsulates the physics principles in a real-world media scene, illustrating concepts of inertia, forces, and velocity in a contextualized manner.

The analysis demonstrates how dynamic objects in media sources can be examined using physics concepts, providing educational insights into motion and force interactions. Proper citation of the chosen image, following APA format, ensures academic integrity and allows viewers to locate the original media source. This application of physics in visual media fosters engaging and practical understanding, connecting theoretical principles with observable scenes.

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