Position, Velocity, and Acceleration of a Golf Ball at t = 1.20 s

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Homework Help Overview

The discussion revolves around the motion of a golf ball hit off a cliff, with its position, velocity, and acceleration described by mathematical expressions involving time. The subject area includes kinematics and vector analysis.

Discussion Character

  • Exploratory, Mathematical reasoning, Problem interpretation

Approaches and Questions Raised

  • Participants discuss writing vector expressions for position, velocity, and acceleration as functions of time. There are attempts to derive these expressions through differentiation and to evaluate them at a specific time, t = 1.20 s. Some participants express uncertainty about the final evaluations of these expressions.

Discussion Status

The discussion includes various attempts to clarify the steps needed to express the golf ball's position, velocity, and acceleration at a specific time. Some participants have successfully derived the necessary expressions, while others seek confirmation and guidance on applying these expressions to find the values at t = 1.20 s. There is a recognition of the need to plug in the time into the derived equations.

Contextual Notes

Participants are working within the constraints of a homework assignment, which may limit the amount of direct assistance they can provide to one another. There is an emphasis on using previously derived equations to find specific values without providing complete solutions.

ramin86
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A golf ball is hit off a tee at the edge of a cliff. Its x and y coordinates as functions of time are given by the following expressions.

x = (15.0 m/s)t

y = (2.00 m/s)t - (4.90 m/s2)t2

(a) Write a vector expression for the ball's position as a function of time, using the unit vectors i and j. (Use t, i and j as necessary.)
 
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You have all the information you need. v = a*i+b*j where i is the x direction and j is the y direction. a and b specify the magnitude of the i and j directions, respectively. I am not sure how to answer this question without just flat out telling you.

Say you have the cartesian point (3,4)

in vector form this is 3i+4j
 
yeah lol, got that one and the next couple, but having trouble with the next few:
(a) Write a vector expression for the ball's position as a function of time, using the unit vectors i and j. (Use t, i and j as necessary.) Got this one
r = correct check mark m
(b) By taking derivatives, obtain an expression for the velocity vector v as a function of time. Got this one
v = correct check mark m/s
(c) By taking derivatives, obtain an expression for the acceleration vector a as a function of time. Got this one
a = correct check mark m/s2

Don't get these :
(d) Next use unit vector notation to write an expression for the position of the golf ball at t = 1.20 s.
r(1.20 s) = ( m ) i + ( m ) j
(e) Write an expression for the velocity at this time.
v(1.20 s) = ( m/s ) i + ( m/s ) j
(f) Write an expression for the acceleration at this time.
a(1.20 s) = ( m/s2 ) j
 
lol nevermind, got them all
 
ramin86 said:
yeah lol, got that one and the next couple, but having trouble with the next few:
(a) Write a vector expression for the ball's position as a function of time, using the unit vectors i and j. (Use t, i and j as necessary.) Got this one
r = correct check mark m
(b) By taking derivatives, obtain an expression for the velocity vector v as a function of time. Got this one
v = correct check mark m/s
(c) By taking derivatives, obtain an expression for the acceleration vector a as a function of time. Got this one
a = correct check mark m/s2

Don't get these :
(d) Next use unit vector notation to write an expression for the position of the golf ball at t = 1.20 s.
r(1.20 s) = ( m ) i + ( m ) j
(e) Write an expression for the velocity at this time.
v(1.20 s) = ( m/s ) i + ( m/s ) j
(f) Write an expression for the acceleration at this time.
a(1.20 s) = ( m/s2 ) j

I think semantics are messing you up. All they're asking is using the formulae you derived, plug t = 1.20s into each of them: position for d, velocity for e and acceleration for f. Your previous equations should have told you what the i and j components will be at any time t.
 

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