1 / 20

Chapter 6: Data Transmission

Chapter 6: Data Transmission. Business Data Communications, 4e. Electromagnetic Signals. Function of time Analog (varies smoothly over time) Digital (constant level over time, followed by a change to another level) Function of frequency (more important) Spectrum (range of frequencies)

redell
Download Presentation

Chapter 6: Data Transmission

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. Chapter 6:Data Transmission Business Data Communications, 4e

  2. Electromagnetic Signals • Function of time • Analog (varies smoothly over time) • Digital (constant level over time, followed by a change to another level) • Function of frequency (more important) • Spectrum (range of frequencies) • Bandwidth (width of the spectrum)

  3. Periodic Signal Characteristics • Amplitude (A): signal value, measured in volts • Frequency (f): repetition rate, cycles per second or Hertz • Period (T): amount of time it takes for one repetition, T=1/f • Phase (f): relative position in time, measured in degrees

  4. Bandwidth • Width of the spectrum of frequencies that can be transmitted • if spectrum=300 to 3400Hz, bandwidth=3100Hz • Greater bandwidth leads to greater costs • Limited bandwidth leads to distortion

  5. Why Study Analog in a Data Comm Class? • Much of our data begins in analog form; must understand it in order to properly convert it • Telephone system is primarily analog rather than digital (designed to carry voice signals) • Low-cost, ubiquitous transmission medium • If we can convert digital information (1s and 0s) to analog form (audible tone), it can be transmitted inexpensively

  6. Analog data Voice Images Digital data Text Digitized voice or images Data vs Signals

  7. Analog Signaling phase difference • represented by sine waves 1 cycle amplitude (volts) time (sec) frequency (hertz) = cycles per second

  8. Voice/Audio Analog Signals • Easily converted from sound frequencies (measured in loudness/db) to electromagnetic frequencies, measured in voltage • Human voice has frequency components ranging from 20Hz to 20kHz • For practical purposes, the telephone system has a narrower bandwidth than human voice, from 300 to 3400Hz

  9. Image/Video: Analog Data to Analog Signals • Image is scanned in lines; each line is displayed with varying levels of intensity • Requires approximately 4Mhz of analog bandwidth • Since multiple signals can be sent via the same channel, guardbands are necessary, raising bandwidth requirements to 6Mhz per signal

  10. Digital Signaling • represented by square waves or pulses 1 cycle amplitude (volts) time (sec) frequency (hertz) = cycles per second

  11. Digital Text Signals • Transmission of electronic pulses representing the binary digits 1 and 0 • How do we represent letters, numbers, characters in binary form? • Earliest example: Morse code (dots and dashes) • Most common current form: ASCII

  12. Digital Image Signals • Analog facsimile • similar to video scanning • Digital facsimile, bitmapped graphics • uses pixelization • Object-oriented graphics • image represented using library of objects • e.g. Postscript, TIFF

  13. Pixelization and Binary Representation • Used in digital fax, bitmapped graphics 1-bit code:00000000 00111100 01110110 01111110 01111000 01111110 00111100 00000000

  14. Transmission Media • the physical path between transmitter and receiver (“channel”) • design factors affecting data rate • bandwidth • physical environment • number of receivers • impairments

  15. Impairments and Capacity • Impairments exist in all forms of data transmission • Analog signal impairments result in random modifications that impair signal quality • Digital signal impairments result in bit errors (1s and 0s transposed)

  16. Transmission Impairments:Guided Media • Attenuation • loss of signal strength over distance • Attenuation Distortion • different losses at different frequencies • Delay Distortion • different speeds for different frequencies • Noise • distortions of signal caused by interference

  17. Transmission Impairments:Unguided (Wireless) Media • Free-Space Loss • Signals disperse with distance • Atmospheric Absorption • Water vapor and oxygen contribute to signal loss • Multipath • Obstacles reflect signal creating multiple copies • Refraction • Noise

  18. Types of Noise • Thermal (aka “white noise”) • Uniformly distributed, cannot be eliminated • Intermodulation • When different frequencies collide (creating “harmonics”) • Crosstalk • Overlap of signals • Impulse noise • Irregular spikes, less predictable

  19. Channel Capacity • The rate at which data can be transmitted over a given path, under given conditions • Four concepts • Data rate • Bandwidth • Noise • Error rate

  20. Shannon Equation • C = B log2 (1 + SNR) • B = Bandwidth • C= Channel • SNR = Signal-to-noise ratio

More Related