Short Questions (120)
Easy Questions (36)
1. Define kinematics.
2. What is meant by rest and motion?
3. How can you define linear motion?
4. What is circular motion?
5. Give one example of random motion.
6. Define translatory motion.
7. What is the difference between linear motion and circular motion?
8. What do you understand by scalars and vectors?
9. What is meant by uniform speed?
10. Define displacement.
11. How is velocity different from speed?
12. What is meant by position in kinematics?
13. What do you understand by acceleration?
14. Define uniform acceleration.
15. What is meant by distance covered?
16. Give the formula for calculating speed.
17. State the formula for velocity.
18. What is meant by average velocity?
19. What are the three types of equations of motion?
20. Define uniform velocity.
21. What is meant by random motion? Give an example.
22. Define rotatory motion with an example.
23. What is vibratory motion? Provide an example.
24. How can distance and displacement be represented on a graph?
25. What is meant by a speed-time graph?
26. What is the SI unit of displacement?
27. Define the term 'motion'.
28. What do you mean by 'object in uniform motion'?
29. Define the first equation of motion.
30. What is the second equation of motion?
31. State the third equation of motion.
32. What do you understand by 'freely falling bodies'?
33. What is meant by ‘object moving with constant speed’?
34. How is a vector quantity represented graphically?
35. Define 'rest'.
36. Give one example of an object in uniform acceleration.
Moderate Questions (48)
1. Differentiate between distance and displacement.
2. What is the difference between speed and velocity?
3. How is motion described in terms of kinematics?
4. Explain the concept of uniform acceleration with an example.
5. How is acceleration calculated?
6. Describe the types of motion with suitable examples.
7. What is the significance of the third equation of motion?
8. Define and differentiate between scalars and vectors with examples.
9. How can you represent the motion of an object on a distance-time graph?
10. What are the key components of a speed-time graph?
11. What is the significance of acceleration in kinematics?
12. Define velocity and explain how it is calculated.
13. What is meant by the term ‘uniform changing speed’?
14. How is acceleration different from velocity?
15. What are the primary terms associated with motion?
16. How are the equations of motion derived?
17. What are the conditions for using the second equation of motion?
18. What do you understand by 'motion of freely falling bodies'?
19. Explain the concept of rotatory motion with an example.
20. Differentiate between translatory motion and rotatory motion.
21. What is vibratory motion? How is it different from translatory motion?
22. What are the conditions for uniform velocity?
23. Explain the role of the third equation of motion in determining the position of an object.
24. How can vectors be represented graphically?
25. What is meant by the position of an object? How is it determined?
26. How is the distance covered by an object calculated?
27. Differentiate between object moving with constant speed and uniform speed.
28. What are the units of velocity and acceleration?
29. How is the speed-time graph used to determine the motion of an object?
30. Explain the first equation of motion with an example.
31. What is meant by variable speed? How does it affect the motion of an object?
32. Explain the process of calculating distance travelled by a moving object.
33. How does the second equation of motion determine the displacement of an object?
34. What is meant by translatory motion? Give an example.
35. Describe circular motion in terms of direction and speed.
36. How can vectors be resolved into components?
37. What is the graphical representation of an object's position over time?
38. Explain how acceleration is related to the motion of freely falling bodies.
39. How is random motion different from linear motion?
40. What is the formula for calculating acceleration?
41. Describe the graphical representation of uniform speed.
42. What is the relationship between velocity and acceleration?
43. Explain the concept of ‘object moving with variable speed’.
44. What are the factors affecting the motion of freely falling bodies?
45. How is the displacement of an object represented on a graph?
46. How are the three equations of motion interconnected?
47. What is the concept of average speed?
48. How can speed be determined from a distance-time graph?
Tough Questions (36)
1. Derive the first equation of motion algebraically.
2. Explain the derivation of the second equation of motion with a practical example.
3. How can the third equation of motion be used to calculate the velocity of an object?
4. How are the three types of motion (translatory, rotatory, vibratory) interconnected?
5. Derive the expression for acceleration of freely falling bodies.
6. What is the relationship between displacement and velocity in the context of kinematics?
7. How can you graphically represent uniform and non-uniform acceleration?
8. Explain the concept of position vector and its importance in kinematics.
9. How can the distance-time graph be used to determine instantaneous speed?
10. Explain the role of vectors in representing physical quantities in motion.
11. Derive the second equation of motion for a freely falling body.
12. How is variable speed different from uniform speed mathematically?
13. What is the role of the third equation of motion in determining the acceleration of an object?
14. Explain how distance and displacement can have different values for the same motion.
15. How are the equations of motion derived for uniformly accelerated motion?
16. Describe the motion of a body in free fall using the first equation of motion.
17. What are the factors influencing the motion of a body in circular motion?
18. Explain how the speed-time graph helps in understanding variable motion.
19. How can you derive the position vector of a moving object?
20. What is the impact of initial velocity on the motion of freely falling bodies?
21. How is uniform acceleration related to linear motion?
22. Derive the formula for displacement using the third equation of motion.
23. How can you determine the velocity of an object using the first equation of motion?
24. How does the motion of a freely falling body differ from that of an object in uniform motion?
25. What are the limitations of the equations of motion for non-uniform acceleration?
26. Derive the expression for the motion of an object with variable acceleration.
27. How can the position of an object be determined using a velocity-time graph?
28. Derive the second equation of motion for an object in uniform acceleration.
29. What are the factors affecting acceleration in vibratory motion?
30. Explain the derivation of acceleration for a body moving in a circular path.
31. How does the motion of a body vary with changing acceleration?
32. How can we determine the direction of motion using vector representation?
33. Derive the third equation of motion for a body in translatory motion.
34. Explain the effect of changing velocity on the displacement of an object.
35. How can the equations of motion be modified for a body moving in a non-linear path?
36. Derive the formula for the distance travelled by a body under uniform acceleration.
Long Questions (10)
Easy Questions (3)
1. Define and explain the terms speed, velocity, and acceleration. Give practical examples to distinguish between them.
2. Describe the types of motion with suitable examples. Include translatory, rotatory, and vibratory motion in your explanation.
3. Discuss the concept of distance and displacement. Explain how they can have different values for the same motion with appropriate examples.
Moderate Questions (4)
1. Derive the first equation of motion with a practical example. Explain the significance of each term in the equation.
2. Explain the relationship between velocity and acceleration using the second equation of motion. Provide graphical representations.
3. Discuss the types of motion with special emphasis on circular and linear motion. How are they mathematically represented?
4. Derive the third equation of motion for uniformly accelerated motion. Discuss its applications with real-world examples.
Tough Questions (3)
1. Derive the second equation of motion for a freely falling body and explain its significance in determining the displacement of the body over time.
2. Discuss in detail the graphical representation of the motion of a body with varying speed. Explain the concept of instantaneous velocity and its practical applications.
3. Explain how the equations of motion change for a body moving in a non-linear path. Discuss the limitations of the equations of motion for non-uniform acceleration.
This set of questions is structured to match the style and level of the BISE Gujranwala board. Feel free to ask for further customizations!