Speed and Velocity

Solved Example: Equal Distance

Question: A car covers half distance at 40 km h^-1 and half at 60 km h^-1. Find average speed.

Given: v₁=40, v₂=60, equal distances.

Formula: v_avg = 2v₁v₂/(v₁+v₂)

Substitution: 2×40×60/(40+60)

Calculation: 4800/100 = 48 km h^-1

Solved Example: Equal Time

Question: A cyclist moves 10 m s^-1 for 5 s and 20 m s^-1 for 5 s. Find average speed.

Given: Equal times.

Formula: v_avg = (v₁+v₂)/2

Substitution: (10+20)/2

Calculation: 15 m s^-1

Zero Average Velocity Example

Question: A runner completes one round of a circular track in 100 s. Find average speed and average velocity if track circumference is 400 m.

Given: Distance = 400 m, displacement = 0, time = 100 s.

Formula: Average speed = distance/time; average velocity = displacement/time

Substitution: 400/100 and 0/100

Calculation: Average speed = 4 m s^-1, average velocity = 0

Negative Displacement Example

Question: A particle moves from x = 10 m to x = -5 m in 3 s. Find average velocity.

Given: x₁=10 m, x₂=-5 m, t=3 s.

Formula: v_avg = (x₂-x₁)/t

Substitution: (-5-10)/3

Calculation: -15/3 = -5 m s^-1

Two runners towards each other

Question: Two runners 100 m apart run towards each other at 6 m s^-1 and 4 m s^-1. Find meeting time.

Given: separation=100 m, speeds 6 and 4.

Formula: t = separation/(v₁+v₂)

Substitution: 100/(6+4)

Calculation: 10 s

Same direction trains

Question: Train A at 30 m s^-1 overtakes train B at 20 m s^-1. Relative speed?

Given: same direction.

Formula: v_rel = |v₁-v₂|

Substitution: |30-20|

Calculation: 10 m s^-1

Opposite direction trains

Question: Two trains move opposite at 18 m s^-1 and 22 m s^-1. Find relative speed.

Given: opposite directions.

Formula: v_rel = v₁+v₂

Substitution: 18+22

Calculation: 40 m s^-1

Train crossing platform

Question: A 150 m train moving 15 m s^-1 crosses a 300 m platform. Find time.

Given: total length = 150+300 = 450 m.

Formula: time = total length/speed

Substitution: 450/15

Calculation: 30 s

Rain Example 1

Question: Rain falls vertically at 10 m s^-1 and a man walks horizontally at 5 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=10, v_man=5.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(10²+5²), tan θ=5/10

Calculation: v=11.18 m s^-1, θ=26.6°

Rain Example 2

Question: Rain falls vertically at 12 m s^-1 and a man walks horizontally at 5 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=12, v_man=5.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(12²+5²), tan θ=5/12

Calculation: v=13.0 m s^-1, θ=22.6°

Rain Example 3

Question: Rain falls vertically at 15 m s^-1 and a man walks horizontally at 10 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=15, v_man=10.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(15²+10²), tan θ=10/15

Calculation: v=18.03 m s^-1, θ=33.7°

Rain Example 4

Question: Rain falls vertically at 20 m s^-1 and a man walks horizontally at 15 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=20, v_man=15.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(20²+15²), tan θ=15/20

Calculation: v=25.0 m s^-1, θ=36.9°

Rain Example 5

Question: Rain falls vertically at 8 m s^-1 and a man walks horizontally at 6 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=8, v_man=6.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(8²+6²), tan θ=6/8

Calculation: v=10.0 m s^-1, θ=36.9°

Rain Example 6

Question: Rain falls vertically at 24 m s^-1 and a man walks horizontally at 7 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=24, v_man=7.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(24²+7²), tan θ=7/24

Calculation: v=25.0 m s^-1, θ=16.3°

Rain Example 7

Question: Rain falls vertically at 18 m s^-1 and a man walks horizontally at 12 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=18, v_man=12.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(18²+12²), tan θ=12/18

Calculation: v=21.63 m s^-1, θ=33.7°

Rain Example 8

Question: Rain falls vertically at 30 m s^-1 and a man walks horizontally at 16 m s^-1. Find apparent speed and umbrella angle from vertical.

Given: v_rain=30, v_man=16.

Formula: v_apparent = √(v_rain² + v_man²), tan θ = v_man/v_rain

Substitution: √(30²+16²), tan θ=16/30

Calculation: v=34.0 m s^-1, θ=28.1°

River Boat Example 1

Question: River width is 120 m, boat speed in still water 6 m s^-1, river speed 2 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=120/6, drift=2×20.0

Calculation: t=20.0 s, drift=40.0 m

River Boat Example 2

Question: River width is 200 m, boat speed in still water 10 m s^-1, river speed 5 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=200/10, drift=5×20.0

Calculation: t=20.0 s, drift=100.0 m

River Boat Example 3

Question: River width is 300 m, boat speed in still water 15 m s^-1, river speed 9 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=300/15, drift=9×20.0

Calculation: t=20.0 s, drift=180.0 m

River Boat Example 4

Question: River width is 80 m, boat speed in still water 4 m s^-1, river speed 3 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=80/4, drift=3×20.0

Calculation: t=20.0 s, drift=60.0 m

River Boat Example 5

Question: River width is 150 m, boat speed in still water 5 m s^-1, river speed 4 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=150/5, drift=4×30.0

Calculation: t=30.0 s, drift=120.0 m

River Boat Example 6

Question: River width is 240 m, boat speed in still water 12 m s^-1, river speed 5 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=240/12, drift=5×20.0

Calculation: t=20.0 s, drift=100.0 m

River Boat Example 7

Question: River width is 100 m, boat speed in still water 8 m s^-1, river speed 6 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=100/8, drift=6×12.5

Calculation: t=12.5 s, drift=75.0 m

River Boat Example 8

Question: River width is 180 m, boat speed in still water 9 m s^-1, river speed 3 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=180/9, drift=3×20.0

Calculation: t=20.0 s, drift=60.0 m

River Boat Example 9

Question: River width is 360 m, boat speed in still water 18 m s^-1, river speed 6 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=360/18, drift=6×20.0

Calculation: t=20.0 s, drift=120.0 m

River Boat Example 10

Question: River width is 90 m, boat speed in still water 5 m s^-1, river speed 1 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=90/5, drift=1×18.0

Calculation: t=18.0 s, drift=18.0 m

River Boat Example 11

Question: River width is 250 m, boat speed in still water 10 m s^-1, river speed 6 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=250/10, drift=6×25.0

Calculation: t=25.0 s, drift=150.0 m

River Boat Example 12

Question: River width is 400 m, boat speed in still water 20 m s^-1, river speed 12 m s^-1. If boat is aimed perpendicular to bank, find crossing time and drift.

Given: Boat aimed perpendicular.

Formula: t = width/v_boat, drift = v_rivert

Substitution: t=400/20, drift=12×20.0

Calculation: t=20.0 s, drift=240.0 m

Bird Shuttle Example 1

Question: A car is 100 m from a wall and moves toward it at 10 m s^-1. A bird flies between car and wall at 20 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=100/10; distance=20×10

Calculation: t=10 s, distance=200 m

Bird Shuttle Example 2

Question: A car is 200 m from a wall and moves toward it at 20 m s^-1. A bird flies between car and wall at 30 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=200/20; distance=30×10

Calculation: t=10 s, distance=300 m

Bird Shuttle Example 3

Question: A car is 150 m from a wall and moves toward it at 15 m s^-1. A bird flies between car and wall at 25 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=150/15; distance=25×10

Calculation: t=10 s, distance=250 m

Bird Shuttle Example 4

Question: A car is 300 m from a wall and moves toward it at 30 m s^-1. A bird flies between car and wall at 40 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=300/30; distance=40×10

Calculation: t=10 s, distance=400 m

Bird Shuttle Example 5

Question: A car is 120 m from a wall and moves toward it at 12 m s^-1. A bird flies between car and wall at 18 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=120/12; distance=18×10

Calculation: t=10 s, distance=180 m

Bird Shuttle Example 6

Question: A car is 500 m from a wall and moves toward it at 25 m s^-1. A bird flies between car and wall at 50 m s^-1 until collision. Find bird distance.

Given: separation, car speed, bird speed given.

Formula: time before collision = separation/car speed; bird distance = bird speed × time

Substitution: t=500/25; distance=50×20

Calculation: t=20 s, distance=1000 m

Square Chasing Problem

Question: Four persons at corners of a square of side a run with speed v, each chasing the next person. Find meeting time.

Given: side = a, speed = v.

Formula: Component of velocity towards centre = v cos 45° = v/√2; distance to centre = a/√2.

Substitution: t = (a/√2)/(v/√2)

Calculation: t = a/v

Triangle Chasing Problem

Question: Three persons at corners of an equilateral triangle of side a run with speed v, each chasing the next. Find meeting time.

Given: equilateral triangle side a.

Formula: component toward centre = v cos 30°, distance to centre = a/√3.

Substitution: t=(a/√3)/(v√3/2)

Calculation: t = 2a/(3v)

General Polygon

Question: N particles at regular polygon vertices chase next particle with speed v. What is the meeting point?

Given: Regular polygon and equal speeds.

Formula: By symmetry, all meet at centre.

Substitution: All remain symmetrically placed during motion.

Calculation: Meeting point is centre.

Graph Example 1

Question: In an x-t graph, position changes from 2 m to 14 m in 3 s. Find average velocity.

Given: x₁=2 m, x₂=14 m, t=3 s.

Formula: v_avg = Δx/Δt

Substitution: (14-2)/3

Calculation: 4 m s^-1

Graph Example 2

Question: In a v-t graph, velocity is 10 m s^-1 for 5 s. Find displacement.

Given: v=10, t=5.

Formula: Displacement = area under v-t graph

Substitution: 10×5

Calculation: 50 m

Average Speed

Question: A body covers 100 m in 10 s and 100 m in 20 s. Find average speed.

Given: Total distance=200 m, total time=30 s.

Formula: v_avg=total distance/total time

Substitution: 200/30

Calculation: 6.67 m s^-1

Train Crossing

Question: A train of length 180 m crosses a pole in 12 s. Find speed.

Given: length=180 m, time=12 s.

Formula: speed=distance/time

Substitution: 180/12

Calculation: 15 m s^-1

Relative Velocity

Question: Two cars move same direction at 25 and 15 m s^-1. Relative speed?

Given: same direction.

Formula: v_rel=difference

Substitution: 25-15

Calculation: 10 m s^-1

Graph Velocity

Question: Position changes from -4 m to +8 m in 6 s. Average velocity?

Given: Δx=12 m, t=6 s.

Formula: v=Δx/t

Substitution: 12/6

Calculation: 2 m s^-1

NEET Exam-style Question 1

Question: Average speed is defined as

NEET Exam-style Question 2

Question: Average velocity is defined as

NEET Exam-style Question 3

Question: Speed is

NEET Exam-style Question 4

Question: Velocity can be

NEET Exam-style Question 5

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 6

Question: Same direction relative speed equals

NEET Exam-style Question 7

Question: Opposite direction relative speed equals

NEET Exam-style Question 8

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 9

Question: In bird shuttle problem, first find

NEET Exam-style Question 10

Question: In x-t graph, slope gives

NEET Exam-style Question 11

Question: Average speed is defined as

NEET Exam-style Question 12

Question: Average velocity is defined as

NEET Exam-style Question 13

Question: Speed is

NEET Exam-style Question 14

Question: Velocity can be

NEET Exam-style Question 15

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 16

Question: Same direction relative speed equals

NEET Exam-style Question 17

Question: Opposite direction relative speed equals

NEET Exam-style Question 18

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 19

Question: In bird shuttle problem, first find

NEET Exam-style Question 20

Question: In x-t graph, slope gives

NEET Exam-style Question 21

Question: Average speed is defined as

NEET Exam-style Question 22

Question: Average velocity is defined as

NEET Exam-style Question 23

Question: Speed is

NEET Exam-style Question 24

Question: Velocity can be

NEET Exam-style Question 25

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 26

Question: Same direction relative speed equals

NEET Exam-style Question 27

Question: Opposite direction relative speed equals

NEET Exam-style Question 28

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 29

Question: In bird shuttle problem, first find

NEET Exam-style Question 30

Question: In x-t graph, slope gives

NEET Exam-style Question 31

Question: Average speed is defined as

NEET Exam-style Question 32

Question: Average velocity is defined as

NEET Exam-style Question 33

Question: Speed is

NEET Exam-style Question 34

Question: Velocity can be

NEET Exam-style Question 35

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 36

Question: Same direction relative speed equals

NEET Exam-style Question 37

Question: Opposite direction relative speed equals

NEET Exam-style Question 38

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 39

Question: In bird shuttle problem, first find

NEET Exam-style Question 40

Question: In x-t graph, slope gives

NEET Exam-style Question 41

Question: Average speed is defined as

NEET Exam-style Question 42

Question: Average velocity is defined as

NEET Exam-style Question 43

Question: Speed is

NEET Exam-style Question 44

Question: Velocity can be

NEET Exam-style Question 45

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 46

Question: Same direction relative speed equals

NEET Exam-style Question 47

Question: Opposite direction relative speed equals

NEET Exam-style Question 48

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 49

Question: In bird shuttle problem, first find

NEET Exam-style Question 50

Question: In x-t graph, slope gives

NEET Exam-style Question 51

Question: Average speed is defined as

NEET Exam-style Question 52

Question: Average velocity is defined as

NEET Exam-style Question 53

Question: Speed is

NEET Exam-style Question 54

Question: Velocity can be

NEET Exam-style Question 55

Question: If equal distances are covered at v₁ and v₂, average speed is

NEET Exam-style Question 56

Question: Same direction relative speed equals

NEET Exam-style Question 57

Question: Opposite direction relative speed equals

NEET Exam-style Question 58

Question: For shortest time in river crossing, boat should be aimed

NEET Exam-style Question 59

Question: In bird shuttle problem, first find

NEET Exam-style Question 60

Question: In x-t graph, slope gives

JEE Main Exam-style Question

Question: Rain falls vertically at 12 m s^-1. A man moves east at 5 m s^-1. Find apparent speed.

Given: v_r=12, v_m=5.

Formula: v=√(12²+5²)

Substitution: √169

Calculation: 13 m s^-1

JEE Main Exam-style Question

Question: A train of length 200 m overtakes another of length 150 m. Relative speed is 10 m s^-1. Find time.

Given: total length=350 m.

Formula: time=total length/relative speed

Substitution: 350/10

Calculation: 35 s

JEE Main Exam-style Question

Question: A boat speed in still water is 5 m s^-1, river speed 3 m s^-1, river width 100 m. Find shortest time.

Given: perpendicular aiming.

Formula: t=width/v_boat

Substitution: 100/5

Calculation: 20 s

JEE Main Exam-style Question

Question: For x = 3t², find instantaneous velocity at t=2 s.

Given: x=3t².

Formula: v = change rate of x = 6t

Substitution: 6×2

Calculation: 12 m s^-1

JEE Advanced Exam-style Question

Question: Four particles at square corners chase next with speed v. Find meeting time for side a.

Given: square symmetry.

Formula: t=a/v

Substitution: radial component method

Calculation: a/v

JEE Advanced Exam-style Question

Question: Three particles at equilateral triangle corners chase next with speed v. Find meeting time.

Given: side a.

Formula: t = 2a/(3v)

Substitution: centre distance divided by radial component

Calculation: 2a/(3v)

JEE Advanced Exam-style Question

Question: A boat must cross river with no drift. Boat speed b, river speed r. Find upstream angle with perpendicular.

Given: b>r.

Formula: b sin θ = r

Substitution: sin θ = r/b

Calculation: θ = sin^-1(r/b)

JEE Advanced Exam-style Question

Question: Can instantaneous speed be positive while instantaneous velocity is negative?

Given: 1D motion opposite positive direction.

Formula: speed = magnitude of velocity

Substitution: velocity negative, speed positive

Calculation: yes

Assertion Reason 1

Assertion: Speed is a scalar quantity.

Reason: Speed has magnitude only.

Assertion Reason 2

Assertion: Velocity can be negative.

Reason: Direction is represented by sign in 1D motion.

Assertion Reason 3

Assertion: Average speed and average velocity are always equal.

Reason: Distance and displacement are always equal.

Assertion Reason 4

Assertion: Relative speed in opposite directions is sum of speeds.

Reason: Separation closes faster when bodies move toward each other.

Assertion Reason 5

Assertion: For shortest time crossing a river, boat is aimed perpendicular to bank.

Reason: This maximizes across-river component.

Assertion Reason 6

Assertion: In rain problems, umbrella is held along actual rain velocity.

Reason: Umbrella must be held opposite apparent rain velocity.

Assertion Reason 7

Assertion: Bird shuttle problems require counting each trip.

Reason: Total bird distance equals bird speed times total time.

Assertion Reason 8

Assertion: Slope of x-t graph gives velocity.

Reason: Velocity is rate of change of position.

Assertion Reason 9

Assertion: Area under v-t graph gives displacement.

Reason: Displacement equals integral of velocity over time.

Assertion Reason 10

Assertion: Instantaneous speed is magnitude of instantaneous velocity.

Reason: Speed has no direction.

Assertion Reason 11

Assertion: Speed is a scalar quantity.

Reason: Speed has magnitude only.

Assertion Reason 12

Assertion: Velocity can be negative.

Reason: Direction is represented by sign in 1D motion.

Assertion Reason 13

Assertion: Average speed and average velocity are always equal.

Reason: Distance and displacement are always equal.

Assertion Reason 14

Assertion: Relative speed in opposite directions is sum of speeds.

Reason: Separation closes faster when bodies move toward each other.

Assertion Reason 15

Assertion: For shortest time crossing a river, boat is aimed perpendicular to bank.

Reason: This maximizes across-river component.

Assertion Reason 16

Assertion: In rain problems, umbrella is held along actual rain velocity.

Reason: Umbrella must be held opposite apparent rain velocity.

Assertion Reason 17

Assertion: Bird shuttle problems require counting each trip.

Reason: Total bird distance equals bird speed times total time.

Assertion Reason 18

Assertion: Slope of x-t graph gives velocity.

Reason: Velocity is rate of change of position.

Assertion Reason 19

Assertion: Area under v-t graph gives displacement.

Reason: Displacement equals integral of velocity over time.

Assertion Reason 20

Assertion: Instantaneous speed is magnitude of instantaneous velocity.

Reason: Speed has no direction.

Assertion Reason 21

Assertion: Speed is a scalar quantity.

Reason: Speed has magnitude only.

Assertion Reason 22

Assertion: Velocity can be negative.

Reason: Direction is represented by sign in 1D motion.

Assertion Reason 23

Assertion: Average speed and average velocity are always equal.

Reason: Distance and displacement are always equal.

Assertion Reason 24

Assertion: Relative speed in opposite directions is sum of speeds.

Reason: Separation closes faster when bodies move toward each other.

Assertion Reason 25

Assertion: For shortest time crossing a river, boat is aimed perpendicular to bank.

Reason: This maximizes across-river component.

Assertion Reason 26

Assertion: In rain problems, umbrella is held along actual rain velocity.

Reason: Umbrella must be held opposite apparent rain velocity.

Assertion Reason 27

Assertion: Bird shuttle problems require counting each trip.

Reason: Total bird distance equals bird speed times total time.

Assertion Reason 28

Assertion: Slope of x-t graph gives velocity.

Reason: Velocity is rate of change of position.

Assertion Reason 29

Assertion: Area under v-t graph gives displacement.

Reason: Displacement equals integral of velocity over time.

Assertion Reason 30

Assertion: Instantaneous speed is magnitude of instantaneous velocity.

Reason: Speed has no direction.