Free NEET Mock Tests for Kinematics One Dimensional Motion

• Syllabus: A frame of reference, Motion in a straight line; Position-time graph, speed and velocity. Uniform and non uniform motion, average speed and instantaneous velocity. Uniformly accelerated motion, velocity-time and position-time graphs, for uniformly accelerated motion (graphical treatment).

A brief overview on "Kinematics-One-Dimensional Motion"

• "One-Dimensional Motion" is a fundamental concept in physics that deals with the motion of objects along a single straight line. In this chapter, we explore the basic principles of motion, including concepts such as displacement, velocity, acceleration, and the equations of motion. Understanding one-dimensional motion is essential as it forms the foundation for studying more complex motion in multiple dimensions. Through practical examples and real-world applications, we delve into the kinematics of objects moving in a straight line, allowing us to analyze and predict their behavior with accuracy and precision.
• Rest: Rest in physics refers to the state of an object when it is stationary or not changing its position with respect to its surroundings. An object at rest has zero velocity and does not undergo any displacement over time.
• Motion: Motion in physics refers to the change in position of an object with respect to its surroundings over time. An object in motion has non-zero velocity and undergoes displacement as time progresses.
• What is frame of reference?

  A frame of reference is a coordinate system used to describe the position, motion, and properties of objects relative to a specific point or observer. It serves as a reference point for measuring and analyzing the motion of objects. Here are key points about frames of reference:

• ⬥ Definition: A frame of reference is a set of axes (such as x, y, and z axes) and a fixed origin (point of reference) that define the spatial coordinates for locating objects and describing their motion.
• ⬥ Role in Physics: Frames of reference are essential in physics for studying motion and interactions between objects. They provide a standardized way to quantify and analyze the behavior of objects in space and time.
• Translation and rotation: Translation and rotation are two fundamental types of motion that describe how objects move in space. Here's a brief explanation of translation and rotation:
• ⬥ Translation: Translation refers to the motion of an object where every point on the object moves in a straight line with the same distance, direction, and speed. In translation, the object as a whole changes its position without changing its orientation or shape. Example: A car moving along a straight road experiences translational motion.
• ⬥ Rotation: Rotation refers to the motion of an object where points on the object move along circular paths around a fixed axis or point. In rotation, the object maintains its position in space but changes its orientation or shape as it rotates around the axis. Example: A wheel spinning on its axis experiences rotational motion.
• What is displacement?

  Displacement in physics refers to the change in position of an object relative to its starting point or reference point. It is a vector quantity, which means it has both magnitude (the distance between the initial and final positions) and direction (the straight line joining the initial and final positions).

• Key points about displacement:
• ⬥ Vector Quantity: Displacement is represented by an arrow indicating the direction and distance of the movement from the initial position to the final position.
• ⬥ Magnitude: The magnitude of displacement is the shortest distance between the initial and final positions, measured along a straight line.
• ⬥ Direction: The direction of displacement is the straight line joining the initial and final positions, indicated by the orientation of the displacement vector.
• ⬥ Units: Displacement is typically measured in units such as meters (m), centimeters (cm), kilometers (km), etc., depending on the scale of the movement.
• ⬥ Importance: Displacement is a fundamental concept in kinematics and dynamics, providing information about how far and in which direction an object has moved.
• For example, if an object initially located at point A moves to point B, the displacement vector would point from A to B, indicating the distance and direction of the object's movement. Displacement is a key parameter used in analyzing motion, calculating velocities, accelerations, and other kinematic quantities.

• What is speed?

  Speed in physics is a scalar quantity that measures how fast an object is moving or the rate at which an object covers distance. It is defined as the distance traveled by an object per unit of time. Here are key points about speed:

• ⬥ Is speed a vector quantity?

  Speed is a scalar quantity because it only has magnitude (numerical value) and does not have a specific direction associated with it. It is expressed in units such as meters per second (m/s), kilometers per hour (km/h), miles per hour (mph), etc.

• ⬥ Types of Speed:

  ⬥ Instantaneous Speed: The speed of an object at a specific instant in time.

  ⬥ Average Speed: The total distance traveled divided by the total time taken.

• What is velocity?

  Velocity in physics is a vector quantity that describes both the speed and direction of an object's motion. It is defined as the rate of change of an object's position with respect to time. Here are key points about velocity:

• ⬥ Vector Quantity: Velocity is a vector quantity because it has both magnitude (speed) and direction. The magnitude of velocity represents the speed of the object, while the direction indicates the object's motion.
• ⬥ Types of Velocity:

  ⬥ Instantaneous Velocity: The velocity of an object at a specific instant in time, determined by its instantaneous position and direction.

• ⬥ Average Velocity: The total displacement of an object divided by the total time taken.
• Difference Between Velocity and Speed:

  	Speed	Velocity
  Definition	The rate of motion or distance covered in a specific time period.	The rate of motion of an object in a specific direction, including magnitude and direction.
  Scalar or Vector	Scalar quantity (magnitude only).	Vector quantity (magnitude and direction).
  Example	A car travels at a speed of 60 km/h.	A car travels north at a velocity of 60 km/h.
  Representation	Speed is represented by a single value (e.g., 60 km/h).	Velocity is represented by both magnitude and direction (e.g., 60 km/h north).
  Significance	Important for determining how fast an object is moving.	Important for determining both speed and direction of motion.
  Formula	Speed = Distance / Time	Velocity = Displacement / Time

• Negative Velocity: A negative velocity indicates motion in the opposite direction of the chosen positive direction. It signifies that the object is moving backward or in the opposite sense.
• What is acceleration?Acceleration in physics refers to the rate of change of velocity of an object over time. It is a vector quantity that describes how an object's velocity (both magnitude and direction) changes with respect to time. Here are key points about acceleration:
• ⬥ Vector Quantity: Acceleration is a vector quantity because it has both magnitude (the rate of change of velocity) and direction. It is measured in units such as meters per second squared (m/s²) or kilometers per hour per second (km/h/s).
• Equations of rectilinear motion:

  s = ut + (1/2)at²

• v = u + at

• v² = u² + 2as

• s_n = u + (1/2)a(2a - 1)

  
  

  ⬥ s is the displacement (position) of the object.

  ⬥ u is the initial velocity of the object.

  ⬥ v is the final velocity of the object.

  ⬥ t is the time elapsed.

  ⬥ a is the acceleration of the object.

• Gravitational acceleration:

  ⬥ Definition: Gravitational acceleration is the acceleration experienced by an object when it falls freely under the influence of gravity. It is the rate at which the object's velocity changes due to the gravitational force.

  
  

  ⬥ Constant Value: Near the surface of the Earth, gravitational acceleration is approximately constant and is denoted as g. Its average value is about 9.81m/s²(meters per second squared).

  
  

  ⬥ Direction: Gravitational acceleration always acts downward towards the center of the gravitational body, such as the Earth. This direction is typically considered negative when analyzing motion.

Questions on One-Dimensional Motion

• 1. What is the difference between rest and motion?
• 2. Define displacement and give its SI unit.
• 3. Explain the concept of velocity and its types.
• 4. Calculate the average speed of a car that travels 100 km in 2 hours.
• 5. A train accelerates from rest at 2 m/s² for 10 seconds. Calculate its final velocity.
• 6. Define acceleration and provide its SI unit.
• 7. Explain the graphical representation of motion using velocity-time graphs.
• 8. Derive the equation for displacement using initial velocity, acceleration, and time.
• 9. Calculate the displacement of an object moving with a constant velocity of 5 m/s for 10 seconds.
• 10. Describe the difference between uniform acceleration and non-uniform acceleration.
• 11. A stone is thrown vertically upwards with an initial velocity of 20 m/s. Calculate the time taken for it to reach the highest point.
• 12. What is the significance of the area under a velocity-time graph?
• 13. A car decelerates from 25 m/s to 15 m/s in 5 seconds. Calculate its deceleration.
• 14. Explain the concept of free fall and gravitational acceleration.
• 15. Calculate the time taken by a ball to reach the ground when dropped from a height of 100 meters.
• 16. Derive the equation for final velocity using initial velocity, acceleration, and displacement.
• 17. A rocket accelerates uniformly from 50 m/s to 150 m/s in 10 seconds. Calculate its acceleration.
• 18. Define terminal velocity and its significance in fluid dynamics.
• 19. Explain the concept of projectile motion and its components.
• 20. A stone is thrown horizontally from a cliff with a velocity of 20 m/s. Calculate the time taken for it to hit the ground.
• 21. Discuss the difference between positive and negative acceleration with examples.
• 22. Calculate the distance traveled by a car moving at a constant speed of 60 km/h for 2 hours.
• 23. Define instantaneous speed and instantaneous velocity.
• 24. Discuss the concept of relative motion with suitable examples.
• 25. Calculate the acceleration of a car that changes its velocity from 10 m/s to 30 m/s in 5 seconds.