Answer:
[tex]T(t)=100*sin(\frac{2\pi}{40000}*(t-2000)+\frac{\pi}{2})[/tex]
Explanation:
The cosinusoidal equation has a the following structure:
[tex]T(t)=A*cos(\frac{2\pi}{P} (t-t_o))[/tex]
Where:
A: amplitude from the wave. If max =800 and min=600. Then 2*A=(max-min)=200. A=100
P: Period of the wave. If it takes 20000 years go from the high to the low. Then P/2=20000, P=40000
to: is the time at the time of a maximum. to=2000
Relation between sin and cos:
[tex]cos(\alpha)=sin(\alpha+\pi/2)[/tex]
We replace all these values in the cosinus equation:
[tex]T(t)=100*sin(\frac{2\pi}{40000}*(t-2000)+\frac{\pi}{2})[/tex]
Answer:
T (t) = A x cos (2π/40000 x (t - 2000) +π/2)
Explanation:
From the question given, we recall the following,
The co-sinusoidal equation formation is denoted as:
T (t) = A x cos (2π/p (t - t₀))
At one place on earth the highest temperature = 800
At one place on earth The lowest temperature = 600
A: represents the wave amplitude, if the max and min are both = 800 and 600 respectively.
Thus,
2 x A = maximum -minimum = 200,
A = 100
P: Represents the wave period
Now suppose it takes 20,000 years to go from the high to the low average
Then,
P/2=20000, P=40000
t₀: Represents the time at the time of a maximum. t₀=2000
The Relationship between cos and sin is:
cos (α)= sin ( α + π/2)
In the cosinus equation, all the values are replaced.
Therefore,
We have, T (t) = A x cos (2π/40000 x (t - 2000) +π/2)
