1 / 12

Sin & Cos with Amplitude and Phase.

Sin & Cos with Amplitude and Phase. Sin & Cos with Amplitude and Phase. In the equation, 2 is a multiplier and called an amplitude. Amplitude describes the “height” of the trigonometric function. Sin & Cos with Amplitude and Phase.

baird
Download Presentation

Sin & Cos with Amplitude and Phase.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Sin & Cos with Amplitude and Phase.

  2. Sin & Cos with Amplitude and Phase. In the equation, 2 is a multiplier and called an amplitude.Amplitude describes the “height” of the trigonometric function.

  3. Sin & Cos with Amplitude and Phase. In the equation, 2 is a multiplier and called an amplitude.Amplitude describes the “height” of the trigonometric function.

  4. Sin & Cos with Amplitude and Phase. In the equation, 2 is a multiplier and called an amplitude.Amplitude describes the “height” of the trigonometric function. 2 1 -1 -2

  5. Sin & Cos with Amplitude and Phase. I used just basic angles and plotted my sin x curve. 2 1 -1 -2

  6. Sin & Cos with Amplitude and Phase. I used just basic angles and plotted my sin x curve. Now let’s get our values for 2 1 -1 -2

  7. Sin & Cos with Amplitude and Phase. I used just basic angles and plotted my sin x curve. Now let’s get our values for As you can see, all the values doubled ( x 2 ) 2 1 -1 -2

  8. Sin & Cos with Amplitude and Phase. Phase relation is seen in practical applications such as sound, electrical, and radio waves. This “phase shift” adjusts the wave by sliding it either left or right a number of degrees. The waves mostly frequently shifted are sine waves.

  9. Sin & Cos with Amplitude and Phase. Phase relation is seen in practical applications such as sound, electrical, and radio waves. This “phase shift” adjusts the wave by sliding it either left or right a number of degrees. The waves mostly frequently shifted are sine waves. Here is an example of a sine wave shifted 45⁰.

  10. Sin & Cos with Amplitude and Phase. Phase relation is seen in practical applications such as sound, electrical, and radio waves. This “phase shift” adjusts the wave by sliding it either left or right a number of degrees. The waves mostly frequently shifted are sine waves. Here is an example of a sine wave shifted 45⁰. ( the interval is [ 0 , 2π ] 1 -1

  11. Sin & Cos with Amplitude and Phase. Phase relation is seen in practical applications such as sound, electrical, and radio waves. This “phase shift” adjusts the wave by sliding it either left or right a number of degrees. The waves mostly frequently shifted are sine waves. Here is an example of a sine wave shifted 45⁰. ( the interval is [ 0 , 2π ] 1 -1 And so on

  12. Sin & Cos with Amplitude and Phase. Phase relation is seen in practical applications such as sound, electrical, and radio waves. This “phase shift” adjusts the wave by sliding it either left or right a number of degrees. The waves mostly frequently shifted are sine waves. As you can see, we either add or subtract the angle. Here is an example of a sine wave shifted 45⁰. ( the interval is [ 0 , 2π ] 1 -1 And so on

More Related