Two Dimensional Motion (1 of 4) An Explanation

Step by Step Science

16 Aug 201509:07

Summary

TLDRThis video offers a qualitative exploration of two-dimensional projectile motion, explaining how objects follow a parabolic path when launched at an angle with an initial velocity. It delves into the independent motions in the x and y directions, emphasizing the role of gravity as the only unbalanced force affecting the object's trajectory. The script clarifies that while there is no acceleration in the x-direction due to balanced forces, the y-direction experiences constant acceleration due to gravity, leading to changes in the object's velocity. The video aims to demystify the physics behind projectile motion, providing a fundamental understanding of the forces and motions involved.

Takeaways

🚀 The video discusses two-dimensional projectile motion, where an object is launched at an angle above the horizon with an initial velocity, following a parabolic path.
🔍 The parabolic path is due to the object's simultaneous motion in the X and Y directions, which are independent of each other.
🧲 The only force acting on the object during its flight is gravity, which acts vertically downward, causing changes in the object's motion.
🔄 In the X direction, there are no forces acting on the object once it is in the air, resulting in a constant velocity due to balanced forces.
🌟 The initial velocity in the X direction can be calculated and remains constant throughout the object's trajectory.
📉 In the Y direction, the unbalanced force of gravity causes the object to accelerate downwards, resulting in a changing velocity.
🌐 The object's motion in the Y direction is akin to free fall, with a constant acceleration equal to the acceleration due to gravity (approximately -9.81 m/s²).
📊 The video script includes a table illustrating the constant velocity in the X direction and the changing velocity in the Y direction over time.
⏱ The initial velocity in the Y direction is given as an example, showing how the velocity changes over time due to acceleration.
🔢 The script explains that the velocity in the Y direction decreases as the object ascends and increases as it descends, reaching zero at the peak of its trajectory.
👍 The video concludes by encouraging viewers to subscribe, like, and comment if they found the explanation helpful.

Q & A

What is the main focus of the video script?
-The video script focuses on providing a qualitative description of two-dimensional projectile motion, explaining why an object follows a parabolic path when projected at an angle above the horizon.
Why does the object follow a parabolic path?
-The object follows a parabolic path because it is moving simultaneously in the X and Y directions, with each motion being independent of the other and influenced by different forces.
What are the two independent motions happening in two-dimensional projectile motion?
-The two independent motions are the horizontal motion in the X direction and the vertical motion in the Y direction.
What is the primary force acting on the object during its projectile motion?
-The primary force acting on the object during its projectile motion is gravity, which acts in the negative Y direction.
Why is there no force acting in the X direction after the object is projected?
-After the object is projected, there is no force acting in the X direction because objects in motion tend to stay in motion in a straight line unless acted upon by an unbalanced force, and in the air, only gravity acts on the object.
What is the effect of balanced forces on the object's acceleration in the X direction?
-When forces are balanced, the acceleration in the X direction is zero, resulting in a constant velocity with no change in speed.
How does the acceleration due to gravity affect the object's motion in the Y direction?
-The acceleration due to gravity causes the object to experience free fall in the Y direction, with an acceleration of -9.81 m/s², leading to a change in velocity as it moves up and then down.
What is the initial velocity in the X direction called, and how is it determined?
-The initial velocity in the X direction is called the initial X velocity (V_ix), and it can be determined from the initial total velocity and the projection angle.
How does the object's velocity change as it moves up in the Y direction?
-As the object moves up in the Y direction, its velocity decreases due to the acceleration caused by gravity, until it reaches the top of its path where the velocity in the Y direction is zero.
What happens to the object's velocity as it comes back down in the Y direction?
-As the object comes back down in the Y direction, its velocity increases in the negative direction due to the acceleration caused by gravity, speeding up as it falls.
What is the significance of the table provided in the script?
-The table in the script provides a timeline of the object's motion, showing how the velocity in the X and Y directions changes over time, given the initial velocities and accelerations.