- #1
christian0710
- 407
- 8
Hi, I'm trying to understand how Differentiation and
integral works in practice, and would really appreciate
some help interpreting this calculation-
If we have a circle with Area A=pi*r^2 1) If i want to find the change in Area with respect to
radius then
dA/dr= 2pi*r2) If I'm told that the area of the circle changes with
time
dA/dt = 0.03 (in)^2/sec
And i wanted to find how the radius changes with time,
would this then be the right conclusion
dr/dt = dr/dA*dA/dt = (1/dA/dr)*dA/dt = 1/(2pi*r)*0.03 So the change in radius with respect to time decreases as
the radius increases. So is it correct to leave the
expression like this, or should i express r in the equation
as time, t, since it says dr/dt?
If i want to find the radius at a specific time when the
area increases as
dA/dt = 0.03 (in)^2/sec would it the be correct to
integrate
dr/dt= 0.03/(2pi*r)
to give me a function r which depends on t?
If i want to express r as t in the equation
dr/dt= 1/(2pi*r)*0.03 , how exactly would i do it: I could isolate r in A=pi*r^2 --> sqrt(A/pi) and
substitute sqrt(A/pi) into the equation and then to
substitute t into A, i guess i would integrate dA/dt = 0.03
(in)^2/sec to get A=A(t)=0.03*t and then substitute A=0.03t
like this
dr/dt= 0.03/(2pi*(sqrt(0.03*t/pi)I don't know if I'm breaking any rules here? OR if my
reasoning is wrong?
integral works in practice, and would really appreciate
some help interpreting this calculation-
If we have a circle with Area A=pi*r^2 1) If i want to find the change in Area with respect to
radius then
dA/dr= 2pi*r2) If I'm told that the area of the circle changes with
time
dA/dt = 0.03 (in)^2/sec
And i wanted to find how the radius changes with time,
would this then be the right conclusion
dr/dt = dr/dA*dA/dt = (1/dA/dr)*dA/dt = 1/(2pi*r)*0.03 So the change in radius with respect to time decreases as
the radius increases. So is it correct to leave the
expression like this, or should i express r in the equation
as time, t, since it says dr/dt?
If i want to find the radius at a specific time when the
area increases as
dA/dt = 0.03 (in)^2/sec would it the be correct to
integrate
dr/dt= 0.03/(2pi*r)
to give me a function r which depends on t?
If i want to express r as t in the equation
dr/dt= 1/(2pi*r)*0.03 , how exactly would i do it: I could isolate r in A=pi*r^2 --> sqrt(A/pi) and
substitute sqrt(A/pi) into the equation and then to
substitute t into A, i guess i would integrate dA/dt = 0.03
(in)^2/sec to get A=A(t)=0.03*t and then substitute A=0.03t
like this
dr/dt= 0.03/(2pi*(sqrt(0.03*t/pi)I don't know if I'm breaking any rules here? OR if my
reasoning is wrong?
