Presentation is loading. Please wait.

Presentation is loading. Please wait.

Crossing the River Discussion

Published byLennart Hansen Modified over 5 years ago

Similar presentations

Presentation on theme: "Crossing the River Discussion"— Presentation transcript:

1 Crossing the River Discussion
Created for CVCA Physics by Dick Heckathorn 15 October 2K+4

2 Q-1 Problem 1 Heading downstream (w/current) v = ?
Q-2 Heading upstream (against current) V=? Q-3 What is shore doing? Q-3a Tuber observation of boat Q-4 Heading across river (no current) v = ? Q-5 Heading across river (w/current) v = ? Q- Study the v and d vector drawings Q-6 Going directly across the river with current Quiz 1 Quiz 2 Quiz 3 Quiz 4

3 Problem We wish to cross a river. This unique river has a constant current of 6 m/s from bank to bank. Speed of the Current 6 m/s

4 We will be crossing in a boat that can travel with a speed of 8 m/s in still water.
(This means that the boat will have this speed in the direction that the boat is pointing.) Speed of the boat 8 m/s

5 Question 1 Heading Downstream
If the boat is heading downstream, what will be the resultant speed of the boat as seen from shore? VC = 6 m/s VB = 8 m/s VR = 14 m/s

6 Question 2 Heading Upstream
If the boat is heading upstream, what will be the resultant speed of the boat as seen from shore? VR = 2 m/s VC = 6 m/s VB = 8 m/s

7 Question 3 Changing to Boat Reference Frame
How fast will a person in the boat see the shore pass by? At the same speed that the person on shore sees the boat pass by - but - in the opposite direction.

8 Question 3a Changing To Tuber Reference Frame
How fast will a tuber drifting with the water see the water pass by? The tuber will be floating with the water. Thus they will say the speed of the water relative to them is zero.

9 Question 3a Changing Reference Frame
How fast will a tuber see the boat go by? VB+C = 14 m/s - VB = 8 m/s VC = 6 m/s

10 Question 3a Changing Reference Frame
What is the new velocity of the boat? Has the velocity of the boat changed? I trust you said no. Thus the tuber always sees the boat traveling at a speed of 8 m/s and... with a velocity of 8 m/s in the direction it is heading. (downstream)

11 Problem 4 Heading Across - No Current
The river has no current. We will now head (in the boat) across the river which is 120 m wide.

12 Problem 4 Heading Across - No Current
he crossing displacement is: he velocity of the boat is: dA = 120m VB = 8 m/s Note…Both must have different scales!

13 Problem 4 Heading Across - No Current
How long will it take to cross the river? We know : VB = 8 m/s dA = 120m

14 Problem 5 Heading Across - With Current
Now lets turn the current back on and head directly across the river. What will be the resultant velocity of the boat?

15 Problem 5 Heading Across - With Current
Then find the magnitude of the resultant: Finally, find the angle . Next, draw the resultant vector First draw the velocity vector of the boat. Next add the current vector. VC = 6 m/s Thus the resultant velocity of the boat is VR = 10 m/s VB = 8 m/s 36.9o 10 m/s across 36.9o downstream

16 Problem 5 Heading Across - With Current
How long will it take to cross the river? We know that: VC = 6 m/s d = 120 m VB = 8 m/s Which v ? VR = 10 m/s 10 m/s

17 Problem 5 Heading Across - With Current
Nice try… but 12 sec is incorrect. Why? Where do we go from here? We have learned that a vector times a scalar results in a vector with the same direction as the original vector. Thus when we divide a vector by a vector, they both must be in the same direction.

18 Problem 5 Heading Across - With Current
We know that: VC = 6 m/s d = 120 m VB = 8 m/s Which v ? VR = 10 m/s 8 m/s

19 Problem 5 Heading Across - With Current
Are you surprised that the time (15 sec) to cross the river heading at right angle to the current is the same time that it took to cross the river with no current? (15 sec)?

20 Problem 5 Heading Across - With Current
If so, remember that the current is at right angles to the direction you are heading. Thus the current has no affect on the crossing speed or the crossing time.

21 Problem 5 Heading Across - With Current
How far downstream will we be when we reach the other shore? The one that is in the same direction as the displacement which we want to find. What time and which velocity will we use? This equation relates distance to velocity and time.

22 Problem 5 Heading Across - With Current
And the answer is: VC = 6 m/s t = 15 s

23 Study The Following Vc = 6 m/s dD = 90m vB = 8 m/s vR = 10 m/s
dA = 120m dR = 150m Each vector on the right is equal to the vector on the left multiplied by 15 sec. They are completely different vectors. Thus different scales must be used for the velocity and the displacement. They are similar triangles: a vector times a scalar = a vector in the same direction. How does the triangle on the right compare to the one on the left?

24 Problem 6 Going Directly Across with Current
At what direction must one head so that we will reach the shore directly across the river from where we started?

25 Problem 6 Going Directly Across with Current
We know the following: VC = 6 m/s Speed of boat = 8 m/s Direction we wish to go.

26 Problem 6 Going Directly Across with Current
We proceed as follows: Then add the speed of the boat with its head at the tail of the current and its tail on the resultant direction. Finally, add the two vectors. First, draw the current velocity vector. Next add a dotted line indicating the direction of the resultant velocity. VC = 6 m/s VB = 8 m/s

27 Problem 6 Going Directly Across with Current
Did you guess 36.9o? What do you think angle  is? What trig function can we use to find angle ? We have the side opposite and the hypotenuse. We can use the sine function to find the angle . Next we will need to find the direction the boat will head? VC = 6 m/s Sorry ? ? ? VB = 8 m/s That is not the correct answer?

28 Problem 6 Going Directly Across with Current
The resultant speed of the boat is Finally we need to find the resultant speed of the boat. We will use pythagorean theorem: VC = 6 m/s VB = 8 m/s

29 Problem 6 Going Directly Across with Current
The resultant velocity of the boat is The velocity of the current is Or we could use the vadd computer program. Giving the result of: VC = 6 m/s VB = 8 m/s = 5.83 m/s 90o

30 Problem 6 Going Directly Across with Current
The resultant velocity of the boat is: VC = 6 m/s VB = 8 m/s across, 48.6o upstream

31 Quiz Question 1 A boat heads directly across a river 41 m wide at 3.8 m/s. The current is 2.2 m/s. a. What is resultant velocity of the boat? b. How long to cross the river? c. How far downstream is boat when it reaches the other side?

32 a. 4.39 m/s across 30.1o downstream b. 10.8 sec c. 23.7 m
Quiz Question 1 Answers a m/s across 30.1o downstream b sec c m

33 Quiz Question 1 Answers (not to scale) VC = 2.2m/s dD = VB = 3.8 m/s VR = dA = 41m dR =

34 Quiz Question 2 A boat heads directly across a river 187 m wide at 10.3 m/s. The current is 6.7 m/s. a. What is resultant velocity of the boat? b. How long to cross the river? c. How far downstream is boat when it reaches the other side?

35 a. 12.3 m/s across 33.0o downstream b. 18.2 sec c. 121.9 m
Quiz Question 2 Answers a m/s across 33.0o downstream b sec c m

36 Quiz Question 2 Answers (not to scale) VC = 6.7m/s dD = VB = 10.3 m/s VR = dA = 187m dR =

37 Quiz Question 3 A boat heads directly across a river 110 m wide at 8.5 m/s. The current is 3.8 m/s. a. What is resultant velocity of the boat? b. How long to cross the river? c. How far downstream is boat when it reaches the other side?

38 Quiz Question 3 A boat heads directly across a river 110 m wide at 8.5 m/s. The current is 3.8 m/s. d. At what angle will the boat head so that it will go directly across? e. What will be the crossing speed when heading directly across? f. How long to cross?

39 a. 9.31 m/s across 24.1o downstream b. 12.9 sec c. 49.2 m
Quiz Question 3 Answers a m/s across 24.1o downstream b sec c m d. across 26.6o upstream e m/s f sec

40 Quiz Question 3 Answers (not to scale) VC = 3.8/s dD = VB = 8.5 m/s VR = dA = 110m dR =

41 Quiz Question 4 A boat heads directly across a river 245 m wide with a speed of 14.2 m/s. The current is 8.3 m/s. a. What is resultant velocity of the boat? b. How long will it take the boat to cross the river? c. How far downstream is boat when it reaches the other side?

42 d. At what angle will the boat head so that it will go directly across?
e. What will be the crossing speed when heading directly across? How long to cross? g. How long will it take the boat to cross the river if there is no current?

43 a. 16.45 m/s across 30.3o downstream b. 17.3 sec c. 143.2 m
Quiz Question 4 Answers a m/s across 30.3o downstream b sec c m d. across 35.8o upstream e m/s f sec g sec

44 That’s all folks!

Download ppt "Crossing the River Discussion"

Similar presentations

Chapter 5 Projectile motion. 1. Recall: a projectile is an object only acted upon by gravity.

Chapter 5 Projectile motion. 1. Recall: a projectile is an object only acted upon by gravity.
Chapter 5 Projectile motion

Chapter 5 Projectile motion
RELATIVE VELOCITY IN 2D. WARM UP A boat travels at a constant speed of 3 m/s on a river. The river’s current has a velocity of 2 m/s east. 1.If the boat.

RELATIVE VELOCITY IN 2D. WARM UP A boat travels at a constant speed of 3 m/s on a river. The river’s current has a velocity of 2 m/s east. 1.If the boat.
FA3.4: 1-3: A boat points straight across a 68.0 m wide river and crosses it in 18.2 seconds. In doing this it is carried downstream 23.7 m. 1. What the.

FA3.4: 1-3: A boat points straight across a 68.0 m wide river and crosses it in 18.2 seconds. In doing this it is carried downstream 23.7 m. 1. What the.
Graphical Analytical Component Method

Graphical Analytical Component Method
Motion 11.2 Speed and Velocity

Motion 11.2 Speed and Velocity
Vectors Vector: a quantity that has both magnitude (size) and direction Examples: displacement, velocity, acceleration Scalar: a quantity that has no.

Vectors Vector: a quantity that has both magnitude (size) and direction Examples: displacement, velocity, acceleration Scalar: a quantity that has no.
Chapter 3 Kinematics in Two Dimensions

Chapter 3 Kinematics in Two Dimensions
VECTORSVECTORS Describing paths. VECTOR: line segment with… i. Direction(an angle) ii. Magnitude||v|| = length of vector (distance)

VECTORSVECTORS Describing paths. VECTOR: line segment with… i. Direction(an angle) ii. Magnitude||v|| = length of vector (distance)
Review Displacement Average Velocity Average Acceleration

Review Displacement Average Velocity Average Acceleration
Forces in 2D Chapter 5. 5.1 Vectors Both magnitude (size) and direction Magnitude always positive Can’t have a negative speed But can have a negative.

Forces in 2D Chapter Vectors Both magnitude (size) and direction Magnitude always positive Can’t have a negative speed But can have a negative.
Vectors. Vectors and Scalars A vector has magnitude as well as direction. Some vector quantities: displacement, velocity, force, momentum A scalar has.

Vectors. Vectors and Scalars A vector has magnitude as well as direction. Some vector quantities: displacement, velocity, force, momentum A scalar has.
Vector Addition and Subtraction

Vector Addition and Subtraction
Chapter 4 Vector Addition When handwritten, use an arrow: When printed, will be in bold print: A When dealing with just the magnitude of a vector in print,

Chapter 4 Vector Addition When handwritten, use an arrow: When printed, will be in bold print: A When dealing with just the magnitude of a vector in print,
Vectors Physics Objectives Graphical Method Vector Addition Vector Addition Relative Velocity.

Vectors Physics Objectives Graphical Method Vector Addition Vector Addition Relative Velocity.
Vector Addition Chapter 4. Objectives Quiz 3 Determine graphically the sum of two or more vectors Solve problems of relative velocity Establish a coordinate.

Vector Addition Chapter 4. Objectives Quiz 3 Determine graphically the sum of two or more vectors Solve problems of relative velocity Establish a coordinate.
Vectors have magnitude AND direction. – (14m/s west, 32° and falling [brrr!]) Scalars do not have direction, only magnitude. – ( 14m/s, 32° ) Vectors tip.

Vectors have magnitude AND direction. – (14m/s west, 32° and falling [brrr!]) Scalars do not have direction, only magnitude. – ( 14m/s, 32° ) Vectors tip.
Relative Velocity. Example 1 A man is trying to cross a river that flows due W with a strong current. If the man starts on the N bank, how should he head.

Relative Velocity. Example 1 A man is trying to cross a river that flows due W with a strong current. If the man starts on the N bank, how should he head.
Today, we will have a short review on vectors and projectiles and then have a quiz. You will need a calculator, a clicker and some scratch paper for the.

Today, we will have a short review on vectors and projectiles and then have a quiz. You will need a calculator, a clicker and some scratch paper for the.
Motion Vectors. What is the difference between a vector and a scalar quantity?

Motion Vectors. What is the difference between a vector and a scalar quantity?

Similar presentations

Ads by Google