Chapter 3 : Data transmission Networks and Communication Department Data and Communication book by William stalling
Lecture Contents 3.1 Concepts and Terminology The Physical Layer. Transmission Terminology. Spectrum and Bandwidth. DC component Data Rate an Bandwidth. Digital signal and Bandwidth. 13-Nov-18 Networks and Communication Department
3.1 Concepts and Terminology 13-Nov-18 Networks and Communication Department
The Physical Layer Foundation on which other layers build Properties of wires, fiber, wireless limit what the network can do Key problem is to send (digital) bits using only (analog) signals This is called modulation 13-Nov-18 Networks and Communication Department
Transmission medium and physical layer A transmission media defined as anything that carry information between a source to a destination Located below the sender physical layer and is connected to the other receiver physical layer.
Classes of Transmission Media
Transmission Terminology: The successful transmission of data depends on two factors: Quality of the signal being transmitted Characteristics of the transmission medium 13-Nov-18 Networks and Communication Department
Transmission Terminology 13-Nov-18 Networks and Communication Department
Transmission Terminology: Types of connections The term direct link is used to refer to the transmission path between two devices in which signals propagate directly from transmitter to receiver with no intermediate devices, 1-Point –to-point it provides a direct link between two devices and those are the only two devices sharing the medium. 2- Multipoint In which more than two devices share the same medium. 13-Nov-18 Networks and Communication Department
Transmission Terminology: Direction of data flow Simplex : signals transmitted in one direction eg : Television Half duplex: both stations transmit, but only one at a time eg : Police radio Full duplex: simultaneous transmissions eg : Telephone 13-Nov-18 Networks and Communication Department
Spectrum & Bandwidth range of frequencies contained in signal spectrum width of spectrum Absolute bandwidth narrow band of frequencies containing most energy often just bandwidth Effective bandwidth component of zero frequency dc component 13-Nov-18 Networks and Communication Department
Time and Frequency Domain Figure 4-11 Time and Frequency Domain WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Examples The McGraw-Hill Companies, Inc., 1998 Figure 4-12 WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Signal with DC Component Figure 4-13 Signal with DC Component WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Complex Waveform The McGraw-Hill Companies, Inc., 1998 Figure 4-14 WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Bandwidth The McGraw-Hill Companies, Inc., 1998 Figure 4-15 WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Digital Signal The McGraw-Hill Companies, Inc., 1998 Figure 4-16 WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Amplitude, Period, and Phase Figure 4-17 Amplitude, Period, and Phase for a Digital Signal WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Bit Rate and Bit Interval Figure 4-18 Bit Rate and Bit Interval WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Harmonics of a Digital Signal Figure 4-19 Harmonics of a Digital Signal WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Exact and Significant Spectrums Figure 4-20 Exact and Significant Spectrums However, most of the energy in the signal is contained in a relatively narrow band of frequencies. This band is referred to as the effective bandwidth, or just bandwidth. WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998 Lte Capacity Workstream RMEA | Ericsson Internal | Uen, Rev DRAFT | 18-May-2014 | Page ‹#›
Corruption Due to Insufficient Bandwidth Figure 4-22 Corruption Due to Insufficient Bandwidth WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998
Bandwidth and Data Rate Figure 4-23 Bandwidth and Data Rate Increasing the Bit Rate result in increasing the BW كلما زاد ال bit rate كلما زاد ال لb.w WCB/McGraw-Hill The McGraw-Hill Companies, Inc., 1998 Lte Capacity Workstream RMEA | Ericsson Internal | Uen, Rev DRAFT | 18-May-2014 | Page ‹#›
DC component 13-Nov-18 Networks and Communication Department
DC component No DC component. DC component = 1 13-Nov-18 Networks and Communication Department
Data rate & Bandwidth Data rate: is the amount of data that is moved from one place to another in a given time. It is measured in bps , and can be calculated by: Data rate=2*f Bandwidth: is the actual speed at which data can be transmitted on a connection. There is a direct relationship between data rate & bandwidth 13-Nov-18 Networks and Communication Department
Data Rate Calculation Suppose that we are using a digital transmission system that is capable of transmitting signals with a bandwidth of 12 MHz From the figures, What data rate can be achieved? 13-Nov-18 Networks and Communication Department
Data Rate Calculation Fig . A : Fig . B : BW = 5f – f 12 MHz = 5f – f f = 3 MHz Data rate = 2 * f = 2 * 3 = 6 Mbps Fig . B : BW = 7f – f 12 MHz = 7f – f f = 2 MHz Data rate = 2 * f = 2 * 2 = 4 Mbps 13-Nov-18 Networks and Communication Department
Data rate & Bandwidth relationship any transmission system has a limited band of frequencies this limits the data rate that can be carried on the transmission medium square waves have infinite components and hence an infinite bandwidth most energy in first few components limiting bandwidth creates distortions 13-Nov-18 Networks and Communication Department
Data rate & Bandwidth relationship In general : any digital waveform will have infinite bandwidth. If we attempt to transmit this waveform as a signal over any medium, the transmission system will limit the bandwidth that can be transmitted. On one hand, for any medium, the greater the bandwidth transmitted, the greater the cost. On the other hand limiting the bandwidth creates distortions, and the greater the potential for error by the receiver. 13-Nov-18 Networks and Communication Department
Effect of bandwidth on a digital signal greater the bandwidth transmitted, the greater the quality. 13-Nov-18 Networks and Communication Department
Units of period and frequency TABLE 3.1
The end Any Question ? 13-Nov-18 Networks and Communication Department