Adding Sinusoids of differing Magnitute & Phases

  • Thread starter Thread starter jeff1evesque
  • Start date Start date
  • Tags Tags
    Phases Sinusoids
Join the discussion
Ask a follow-up here, or get your own question answered by working scientists, mathematicians and engineers — people, not an autocomplete.
Real named experts · corrections over time · the nuance an AI answer skips
3 replies · 4K views
jeff1evesque
Messages
312
Reaction score
0

Homework Statement


Find A and [tex]\theta[/tex] given that:
[tex]Acos(\omega t + \theta) = 4sin(\omega t) + 3 cos(\omega t)[/tex]
Could someone elaborate on how to solve this. I mean it looks to me that one simply takes the magnitude of the coefficient and the inverse tangent of the same coefficients. But I feel there needs to be justification as to why we're allowed to do this.

Homework Equations


not sure.

The Attempt at a Solution


But the solution (according to my notes) is: [tex]A = \sqrt{4^2 + 3^2} = 5[/tex] and [tex]\theta^{-1}[/tex] = [tex]\frac{4}{3} = 53.1[/tex]

Thanks,

JL
 
Last edited:
Physics news on Phys.org
What if instead of

[tex] Acos(\omega t + \theta) = 4sin(\omega t) + 3 cos(\omega t)[/tex],

I wanted to write it as,

[tex] Asin(\omega t + \theta) = 4sin(\omega t) + 3 cos(\omega t)[/tex],

would the values of A and [tex]\theta[/tex] change at all?
 
jeff1evesque said:
What if instead of

[tex] Acos(\omega t + \theta) = 4sin(\omega t) + 3 cos(\omega t)[/tex],

I wanted to write it as,

[tex] Asin(\omega t + \theta) = 4sin(\omega t) + 3 cos(\omega t)[/tex],

would the values of A and [tex]\theta[/tex] change at all?
Oh, actually I think I know. The x coordinate axis is [tex]Acos(\omega t)[/tex] (negative for the negative x-axis), and the y coordinate axis is [tex]Asin(\omega t)[/tex] (negative for the negative y-axis). So this means the left side value in the equality is the actual vector, and the terms on the right are the x and y components.

Thannks,JL
 
You need addition and subtraction formulas for sine and cosine (or you can use Euler's identity, but that is more advanced).