1 / 65

EENG 3810 Chapter 4

EENG 3810 Chapter 4. Amplitude Modulation (AM). 1. Chapter 4 Homework. 1. For an AM DSBFC modulator with a carrier frequency f c = 200KHz and a maximum modulating signal frequency f m(max) = 10 KHz, determine : a. Frequency limits for the upper and lower sidebands. b. Bandwidth.

mary-mullins
Download Presentation

EENG 3810 Chapter 4

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. EENG 3810 Chapter 4 Amplitude Modulation (AM) 1

  2. Chapter 4 Homework 1. For an AM DSBFC modulator with a carrier frequency fc = 200KHz and a maximum modulating signal frequency fm(max) = 10 KHz, determine : a. Frequency limits for the upper and lower sidebands. b. Bandwidth. b. Upper and lower side frequencies produced when the modulating signal is a single-frequency 6 KHz tone. 2

  3. Homework Continued 2. For the AM wave form above determine: 3

  4. Homework Continued 3. 4

  5. Homework Continued • Repeat steps (a) through (d) in Example 4 in these lecture slides for a modulation coefficient of 0.5. • For an AM DSBFC wave with a peak unmodulated carrier voltage Vc = 20 Vp, a load resistance RL = 20 , and a modulation coefficient m = 0.8, determine the power of the modulated wave 5

  6. Homework Continued 6.Determine the noise improvement for a receiver with an RF bandwidth equal to 100 KHz and an IF bandwidth equal to 20 KHz.

  7. Amplitude Modulation Transmission 7

  8. AM Generation 8

  9. Frequency Spectrum of An AM Double Sideband Full Carrier (DSBFC) Wave 9

  10. Example 1 For an AM DSBFC modulator with a carrier frequency fc = 100KHz and a maximum modulating signal frequency fm(max) = 5 KHz, determine : a. Frequency limits for the upper and lower sidebands. b. Bandwidth. c. Upper and lower side frequencies produced when the modulating signal is a single-frequency 3 KHz tone. 10

  11. Example 1 Solution a. b. c. 11

  12. Example 1 d. The Output Spectrum For An AM DSBFC Wave 12

  13. Phasor addition in an AM DSBFC envelope • For a single-frequency modulating signal, am AM envelop is produced from the vector addition of the carrier and upper and lower side frequencies. Phasors of the carrier, • The upper and lower frequencies combine and produce a resultant component that combines with the carrier component. • Phasors for the carrier, upper and lower frequencies all rotate in the counterclockwise direction. • The upper sideband frequency rotates faster than the carrier. (usf> c) • The lower sideband frequency rotes slower than the carrier. (usf< c) 13

  14. Phasor addition in an AM DSBFC envelope 14

  15. Modulation Coefficient 15

  16. If the modulating signal is pure, single frequency sine wave and the modulation process is symmetrical, the % modulation can be derived as follows: 16

  17. Peak Amplitudes of Upper and Lower Sidebands The peak change in amplitude of the output wave (Em) is equal to the sum of the voltages from the upper and lower sideband frequencies. Therefore, 17

  18. Percent Modulation of An AM DSBFC Envelope(a) modulating signal; (b) unmodulated carrier; (c) 50% modulated wave; (d) 100% modulated wave 18

  19. Example 2 For the AM wave form above determine: 19

  20. Example 2 20

  21. Voltage Spectrum for an AM DSBFC Wave 21

  22. Generation of an AM DSBFC Envelope Shown in The Time Domain –½ cos(230t) sin(225t) + ½ cos(220t) summation of (a), (b), and (c) 22

  23. Voltage of an AM DSBFC Envelope In The Time Domain 23

  24. Example 3 24

  25. Example 3 Continued 25

  26. Output Spectrum for Example 3 26

  27. AM envelope for Example 3 27

  28. Power for Upper and Lower Sideband 28

  29. Total Power for an AM DSBFC Envelop 29

  30. Power Spectrum for an AM DSBFC Wave with a Single-frequency Modulating Signal 30

  31. Example 4 31

  32. Power Spectrum for Example 4 32

  33. Single Transistor, Emitter Modulator 33

  34. Single Transistor, Emitter Modulator (output waveforms ) 34

  35. Medium-power Transistor AM DSBFC Modulator 35

  36. High-power AM DSBFC Transistor Modulator 36

  37. Linear Integrated-circuit AM Modulator 37

  38. Block Diagram of a Low-level AM DSBFC Transmitter 38

  39. Block Diagram of a High-level AM DSBFC Transmitter 39

  40. Single-Sideband

  41. Conventional DSFC-AM

  42. Single-side Band Full Carrier (SSBFC) The carrier is transmitted at full power and only one sideband is transmitted.

  43. SSBFC waveform, 100% modulation

  44. Single-Sideband Suppressed Carrier (SSBSC) The carrier is suppressed 100% and one sideband is removed. Only one sideband is transmitted.

  45. SSBSC waveform

  46. Single-Sideband Reduced Carrier(SSBRC) One sideband is removed and the carrier voltage is reduced to 10% of its un-modulated amplitude.

  47. Independent Sideband(ISB) A single carrier is independently modulated by two different modulating signals.

  48. ISB waveform

  49. Vestigial Sideband(VSB) The carrier and one complete sideband are transmitted, but only part of the other sideband is transmitted.

More Related