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PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 111
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PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 1122
ANNOUNCEMENTS
ITEM DURATION START
Introductory Concept Survey (Individual) 0:10 0:00
Initial Kinematic Analysis of Rotating Plate 0:20 0:10
Relationship Between Linear and Angular Variables 0:20 0:30
Deriving Formulas for Linear Acceleration (middle of p. 3) 0:15 0:50
Complete Kinematic Analysis of Points A and B 0:25 1:05
Survey Re-vote (Group Discussion Mode) 0:10 1:30
Dismissal 1:40
AGENDA
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 113
1 of 3Boxes A and B are sitting on the platform of a merry-go-round, held by static friction. B is twice as far from the axis of rotation as A. The merry-go-round is accelerating in an angular sense. The magnitude of the centripetal acceleration experienced by B is
1. Zero.2. Half that of A.3. Equal to that of A.4. Twice that of A.5. Four times that of A.
B
A
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 114
2 of 3Boxes A and B are sitting on the platform of a merry-go-round, held by static friction. B is twice as far from the axis of rotation as A. The merry-go-round is accelerating in an angular sense. The magnitude of the tangential acceleration experienced by B is
1. Zero.2. Half that of A.3. Equal to that of A.4. Twice that of A.5. Four times that of A.
B
A
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 115
3 of 3
The box is sitting on the platform of a merry-go-round, held by static friction. The merry-go-round is accelerating in an angular sense. The linear acceleration vector is best represented by
1. 2.
3. 4.
a
a
a
a
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 1166
ANNOUNCEMENTS
ITEM DURATION START
Introductory Concept Survey (Individual) 0:10 0:00
Initial Kinematic Analysis of Rotating Plate 0:20 0:10
Relationship Between Linear and Angular Variables 0:20 0:30
Deriving Formulas for Linear Acceleration (middle of p. 3) 0:15 0:50
Complete Kinematic Analysis of Points A and B 0:25 1:05
Survey Re-vote (Group Discussion Mode) 0:10 1:30
Dismissal 1:40
AGENDA
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 117
IV2 Exit Homework Problem #1
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 118
IV2 Exit Homework Problem #2
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 119
1 of 3Boxes A and B are sitting on the platform of a merry-go-round, held by static friction. B is twice as far from the axis of rotation as A. The merry-go-round is accelerating in an angular sense. The magnitude of the centripetal acceleration experienced by B is
1. Zero.2. Half that of A.3. Equal to that of A.4. Twice that of A.5. Four times that of A.
B
A
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 1110
2 of 3Boxes A and B are sitting on the platform of a merry-go-round, held by static friction. B is twice as far from the axis of rotation as A. The merry-go-round is accelerating in an angular sense. The magnitude of the tangential acceleration experienced by B is
1. Zero.2. Half that of A.3. Equal to that of A.4. Twice that of A.5. Four times that of A.
B
A
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 1111
3 of 3
The box is sitting on the platform of a merry-go-round, held by static friction. The merry-go-round is accelerating in an angular sense. The linear acceleration vector is best represented by
1. 2.
3. 4.
a
a
a
a
PHYS-1600/2000 IV2 Angular and Linear Variables NEBRASKA WESLEYAN UNIVERSITYFALL 2014-2015
DEAN SIEGLAFF NATHANIEL CUNNINGHAM of 1112
1 4 1 4 1 4 1 4
2 5 2 5 2 5 2 5
3 3 3 3
PROJECTION SCREEN
6 6 6 6
IV2: HAND IN TODAY’S ACTIVITIES SHEETS