Chapter 8

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What you will learn.

-Explain the role of Physical layer protocols and services in supporting communication across data networks. -Describe the purpose of Physical layer signaling and encoding as they are used in networks. -Describe the role of signals used to represent bits as a frame is transported across the local media. -Identify the basic characteristics of copper, fiber, and wireless network media. -Describe common uses of copper, fiber, and wireless network media.

8.2.2 Encoding- Grouping Bits.

4B/5B An example, we will examine a simple code group called 4B/5B. Code groups that are currently used in modern networks are generally more complex. In this technique, 4 bits of data are turned into 5-bit code symbols for transmission over the media system. In 4B/5B, each byte to be transmitted is broken into four-bit pieces or nibbles and encoded as five-bit values known as symbols. These symbols represent the data to be transmitted as well as a set of codes that help control transmission on the media. Among the codes are symbols that indicate the beginning and end of the frame transmission. Although this process adds overhead to the bit transmissions, it also adds features that aid in the transmission of data at higher speeds.

8.3.8 Media Connectors.

Common Copper Media Connectors Different Physical layer standards specify the use of different connectors. These standards specify the mechanical dimensions of the connectors and the acceptable electrical properties of each type for the different implementations in which they are employed. Although some connectors may look the same, they may be wired differently according to the Physical layer specification for which they were designed. The ISO 8877 specified RJ-45 connector is used for a range of Physical layer specifications, one of which is Ethernet. Another specification, EIA-TIA 568, describes the wire color codes to pin assignments (pinouts) for Ethernet straight-through and crossover cables. Correct Connector Termination Each time copper cabling is terminated, there is the possibility of signal loss and the introduction of noise to the communication circuit. Ethernet workplace cabling specifications stipulate the cabling necessary to connect a computer to an active network intermediary device. When terminated improperly, each cable is a potential source of Physical layer performance degradation. It is essential that all copper media terminations be of high quality to ensure optimum performance with current and future network technologies.

8.2.3 Data Carrying Capacity.

Different physical media support the transfer of bits at different speeds. Data transfer can be measured in three ways: -Bandwidth -Throughput -Goodput Bandwidth The capacity of a medium to carry data is described as the raw data bandwidth of the media. Digital bandwidth measures the amount of information that can flow from one place to another in a given amount of time. Bandwidth is typically measured in kilobits per second (kbps) or megabits per second (Mbps). Throughput Throughput is the measure of the transfer of bits across the media over a given period of time. Due to a number of factors, throughput usually does not match the specified bandwidth in Physical layer implementations such as Ethernet. Goodput A third measurement has been created to measure the transfer of usable data. That measure is known as goodput. Goodput is the measure of usable data transferred over a given period of time, and is therefore the measure that is of most interest to network users. As shown in the figure, goodput measures the effective transfer of user data between Application layer entities, such as between a source web server process and a destination web browser device.

8.3.5 Copper Media Safety.

Electrical Hazards A potential problem with copper media is that the copper wires could conduct electricity in undesirable ways. This could subject personnel and equipment to a range of electrical hazards. A defective network device could conduct currents to the chassis of other network devices. Additionally, network cabling could present undesirable voltage levels when used to connect devices that have power sources with different ground potentials. Such situations are possible when copper cabling is used to connect networks in different buildings or on different floors of buildings that use different power facilities. Finally, copper cabling may conduct voltages caused by lightning strikes to network devices. The result of undesirable voltages and currents can include damage to network devices and connected computers, or injury to personnel. It is important that copper cabling be installed appropriately, and according to the relevant specifications and building codes, in order to avoid potentially dangerous and damaging situations. Fire Hazards Cable insulation and sheaths may be flammable or produce toxic fumes when heated or burned. Building authorities or organizations may stipulate related safety standards for cabling and hardware installations.

8.2.1 Signaling Bits for the Media.

Eventually, all communication from the human network becomes binary digits, which are transported individually across the physical media. The Physical layer represents each of the bits in the frame as a signal. Each signal placed onto the media has a specific amount of time to occupy the media. This is referred to as its bit time. Signals are processed by the receiving device and returned to its representation as bits. Signaling Methods Bits are represented on the medium by changing one or more of the following characteristics of a signal: Amplitude Frequency Phase The nature of the actual signals representing the bits on the media will depend on the signaling method in use. Some methods may use one attribute of signal to represent a single 0 and use another attribute of signal to represent a single 1. As an example, with Non-Return to Zero (NRZ), a 0 may be represented by one voltage level on the media during the bit time and a 1 might be represented by a different voltage on the media during the bit time. Signaling methods to represent bits on the media can be complex. We will look at two of the simpler techniques to illustrate the concept. NRZ Signaling As a first example, we will examine a simple signaling method, Non Return to Zero (NRZ). In NRZ, the bit stream is transmitted as a series of voltage values, as shown in the figure. A low voltage value represents a logical 0 and a high voltage value represents a logical 1. The voltage range depends on the particular Physical layer standard in use. This simple method of signaling is only suited for slow speed data links. NRZ signaling uses bandwidth inefficiently and is susceptible to electromagnetic interference. Additionally, the boundaries between individual bits can be lost when long strings of 1s or 0s are transmitted consecutively. In that case, no voltage transitions are detectable on the media. Therefore, the receiving nodes do not have a transition to use in resynchronizing bit times with the transmitting node. Manchester Encoding Instead of representing bits as pulses of simple voltage values, in the Manchester Encoding scheme, bit values are represented as voltage transitions. For example, a transition from a low voltage to a high voltage represents a bit value of 1. A transition from a high voltage to a low voltage represents a bit value of 0. Although Manchester Encoding is not efficient enough to be used at higher signaling speeds, it is the signaling method employed by 10BaseT Ethernet (Ethernet running at 10 Megabits per second).

8.3.6 Fiber Media.

Fiber-optic cabling uses either glass or plastic fibers to guide light impulses from source to destination. The bits are encoded on the fiber as light impulses. Optical fiber cabling is capable of very large raw data bandwidth rates. Most current transmission standards have yet to approach the potential bandwidth of this media. Fiber Compared to Copper Cabling Given that the fibers used in fiber-optic media are not electrical conductors, the media is immune to electromagnetic interference and will not conduct unwanted electrical currents due to grounding issues. Because optical fibers are thin and have relatively low signal loss, they can be operated at much greater lengths than copper media, without the need for signal regeneration. Some optical fiber Physical layer specifications allow lengths that can reach multiple kilometers. Optical fiber media implementation issues include: -More expensive (usually) than copper media over the same distance (but for a higher capacity) -Different skills and equipment required to terminate and splice the cable infrastructure -More careful handling than copper media Cable Construction Optical fiber cables consist of a PVC jacket and a series of strengthening materials that surround the optical fiber and its cladding. The cladding surrounds the actual glass or plastic fiber and is designed to prevent light loss from the fiber. Because light can only travel in one direction over optical fiber, two fibers are required to support full duplex operation. Fiber-optic patch cables bundle together two optical fiber cables and terminate them with a pair of standard single fiber connectors. Some fiber connectors accept both the transmitting and receiving fibers in a single connector. Generating and Detecting the Optical Signal Either lasers or light emitting diodes (LEDs) generate the light pulses that are used to represent the transmitted data as bits on the media. Electronic semi-conductor devices called photodiodes detect the light pulses and convert them to voltages that can then be reconstructed into data frames. Note: The laser light transmitted over fiber-optic cabling can damage the human eye. Care must be taken to avoid looking into the end of an active optical fiber. Single-mode and Multimode Fiber Fiber optic cables can be broadly classified into two types: single-mode and multimode. Single-mode optical fiber carries a single ray of light, usually emitted from a laser. Because the laser light is uni-directional and travels down the center of the fiber, this type of fiber can transmit optical pulses for very long distances. Multimode fiber typically uses LED emitters that do not create a single coherent light wave. Instead, light from an LED enters the multimode fiber at different angles. Because light entering the fiber at different angles takes different amounts of time to travel down the fiber, long fiber runs may result in the pulses becoming blurred on reception at the receiving end. This effect, known as modal dispersion, limits the length of multimode fiber segments. Multimode fiber, and the LED light source used with it, are cheaper than single-mode fiber and its laser-based emitter technology.

8.2.2 Encoding- Grouping Bits.

In the prior section, we describe the signaling process as how bits are represented on physical media. In this section, we use of the word encoding to represent the symbolic grouping of bits prior to being presented to the media. By using an encoding step before the signals are placed on the media, we improve the efficiency at higher speed data transmission. Signal Patterns- One way to provide frame detection is to begin each frame with a pattern of signals representing bits that the Physical layer recognizes as denoting the start of a frame. Another pattern of bits will signal the end of the frame. Signal bits not framed in this manner are ignored by the Physical layer standard being used. Code Groups- Encoding techniques use bit patterns called symbols. The Physical layer may use a set of encoded symbols - called code groups - to represent encoded data or control information. A code group is a consecutive sequence of code bits that are interpreted and mapped as data bit patterns. For example, code bits 10101 could represent the data bits 0011. Advantages using code groups include: Reducing bit level error Limiting the effective energy transmitted into the media Helping to distinguish data bits from control bits Better media error detection Reducing Bit Level Errors To properly detect an individual bit as a 0 or as a 1, the receiver must know how and when to sample the signal on the media. This requires that the timing between the receiver and transmitter be synchronized. In many Physical layer technologies, transitions on the media are used for this synchronization. If the bit patterns being transmitted on the media do not create frequent transitions, this synchronization may be lost and individual bit error can occur. Code groups are designed so that the symbols force an ample number of bit transitions to occur on the media to synchronize this timing. They do this by using symbols to ensure that not too many 1s or 0s are used in a row. Distinguish Data from Control The code groups have three types of symbols: Data symbols - Symbols that represent the data of the frame as it is passed down to the Physical layer. Control symbols - Special codes injected by the Physical layer used to control transmission. These include end-of-frame and idle media symbols. Invalid symbols - Symbols that have patterns not allowed on the media. The receipt of an invalid symbol indicates a frame error. Better Media Error Detection In addition to the data symbols and control symbols, code groups contain invalid symbols. These are the symbols that could create long series of 1s or 0s on the media; therefore, they are not used by the transmitting node. If a receiving node receives one of these patterns, the Physical layer can determine that there has been an error in data reception.

8.5.1 Summary and Review.

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8.1.1 Physical Layer- Purpose.

The OSI Physical layer provides the means to transport across the network media the bits that make up a Data Link layer frame. The delivery of frames across the local media requires the following Physical layer elements: -The physical media and associated connectors -A representation of bits on the media -Encoding of data and control information -Transmitter and receiver circuitry on the network devices The purpose of the Physical layer is to create the electrical, optical, or microwave signal that represents the bits in each frame. It is also the job of the Physical layer to retrieve these individual signals from the media, restore them to their bit representations, and pass the bits up to the Data Link layer as a complete frame.

8.1.3 Physical Layer- Standards.

The Physical layer consists of hardware, developed by engineers, in the form of electronic circuitry, media, and connectors. Therefore, it is appropriate that the standards governing this hardware are defined by the relevant electrical and communications engineering organizations. Similar to technologies associated with the Data Link layer, the Physical layer technologies are defined by organizations such as: -The International Organization for Standardization (ISO) -The Institute of Electrical and Electronics Engineers (IEEE) -The American National Standards Institute (ANSI) -The International Telecommunication Union (ITU) -The Electronics Industry Alliance/Telecommunications Industry Association (EIA/TIA) -National telecommunications authorities such as the Federal Communication Commission (FCC) in the USA. PHYSICAL LAYER TECHNOLOGIES AND HARDWARE The technologies defined by these organizations include four areas of the Physical layer standards: -Physical and electrical properties of the media -Mechanical properties (materials, dimensions, pinouts) of the connectors -Bit representation by the signals (encoding) -Definition of control information signals (Click Signals, Connectors, and Cables in the figure to see the hardware.) Hardware components such as network adapters (NICs), interfaces and connectors, cable materials, and cable designs are all specified in standards associated with the Physical layer.

8.3.1 Types of Physical Media.

The Physical layer is concerned with network media and signaling. This layer produces the representation and groupings of bits as voltages, radio frequencies, or light pulses. Various standards organizations have contributed to the definition of the physical, electrical, and mechanical properties of the media available for different data communications. These specifications guarantee that cables and connectors will function as anticipated with different Data Link layer implementations. As an example, standards for copper media are defined for the: -Type of copper cabling used -Bandwidth of the communication -Type of connectors used -Pinout and color codes of connections to the media -Maximum distance of the media The figure shows some of the characteristics of networking media. This section will also describe some of the important characteristics of commonly used copper, optical, and wireless media.

8.1.2 Physical Layer- Operation.

The media does not carry the frame as a single entity. The media carries signals, one at a time, to represent the bits that make up the frame. There are three basic forms of network media on which data is represented: -Copper cable -Fiber -Wireless The representation of the bits - that is, the type of signal - depends on the type of media. For copper cable media, the signals are patterns of electrical pulses. For fiber, the signals are patterns of light. For wireless media, the signals are patterns of radio transmissions. IDENTIFYING A FRAME When the Physical layer encodes the bits into the signals for a particular medium, it must also distinguish where one frame ends and the next frame begins. Otherwise, the devices on the media would not recognize when a frame has been fully received. In that case, the destination device would only receive a string of signals and would not be able to properly reconstruct the frame. To enable a receiving device to clearly recognize a frame boundary, the transmitting device adds signals to designate the start and end of a frame. These signals represent particular bit patterns that are only used to denote the start or end of a frame. The process of encoding a frame of data from the logical bits into the physical signals on the media, and the characteristics of particular physical media, are covered in detail in the following sections of this chapter.

8.3.2 Copper Media.

The most commonly used media for data communications is cabling that uses copper wires to signal data and control bits between network devices. Cabling used for data communications usually consists of a series of individual copper wires that form circuits dedicated to specific signaling purposes. Other types of copper cabling, known as coaxial cable, have a single conductor that runs through the center of the cable that is encased by, but insulated from, the other shield. The copper media type chosen is specified by the Physical layer standard required to link the Data Link layers of two or more network devices. Networking media generally make use of modular jacks and plugs, which provide easy connection and disconnection. Also, a single type of physical connector may be used for multiple types of connections. For example, the RJ-45 connector is used widely in LANs with one type of media and in some WANs with another media type. External Signal Interference Data is transmitted on copper cables as electrical pulses. A detector in the network interface of a destination device must receive a signal that can be successfully decoded to match the signal sent. The timing and voltage values of these signals are susceptible to interference or "noise" from outside the communications system. These unwanted signals can distort and corrupt the data signals being carried by copper media. Radio waves and electromagnetic devices such as fluorescent lights, electric motors, and other devices are potential sources of noise. Cable types with shielding or twisting of the pairs of wires are designed to minimize signal degradation due to electronic noise. The susceptibility of copper cables to electronic noise can also be limited by: -Selecting the cable type or category most suited to protect the data signals in a given networking environment -Designing a cable infrastructure to avoid known and potential sources of interference in the building structure -Using cabling techniques that include the proper handling and termination of the cables.

8.1.4 Physical layer fundamental principles.

The three fundamental functions of the Physical layer are: -The physical components -Data encoding -Signaling The physical elements are the electronic hardware devices, media and connectors that transmit and carry the signals to represent the bits. Encoding- Encoding is a method of converting a stream of data bits into a predefined code. Codes are groupings of bits used to provide a predictable pattern that can be recognized by both the sender and the received. Using predictable patterns helps to distinguish data bits from control bits and provide better media error detection. Signaling- The Physical layer must generate the electrical, optical, or wireless signals that represent the "1" and "0" on the media. The method of representing the bits is called the signaling method. The Physical layer standards must define what type of signal represents a "1" and a "0". This can be as simple as a change in the level of an electrical signal or optical pulse or a more complex signaling method.

8.3.4 Other Copper Cable.

Two other types of copper cable are used: 1. Coaxial 2. Shielded Twisted-Pair (STP) Coaxial Cable Coaxial cable consists of a copper conductor surrounded by a layer of flexible insulation, as shown in the figure. Over this insulating material is a woven copper braid, or metallic foil, that acts as the second wire in the circuit and as a shield for the inner conductor. This second layer, or shield, also reduces the amount of outside electromagnetic interference. Covering the shield is the cable jacket. Uses of Coaxial Cable The coaxial cable design has been adapted for different purposes. Coax is an important type of cable that is used in wireless and cable access technologies. Coax cables are used to attach antennas to wireless devices. The coaxial cable carries radio frequency (RF) energy between the antennas and the radio equipment. Cable service providers are currently converting their one-way systems to two-way systems to provide Internet connectivity to their customers. To provide these services, portions of the coaxial cable and supporting amplification elements are replaced with multi-fiber-optic cable. However, the final connection to the customer's location and the wiring inside the customer's premises is still coax cable. This combined use of fiber and coax is referred to as hybrid fiber coax (HFC). Shielded Twisted-Pair (STP) Cable Another type of cabling used in networking is shielded twisted-pair (STP). As shown in the figure, STP uses four pairs of wires that are wrapped in an overall metallic braid or foil. STP cable shields the entire bundle of wires within the cable as well as the individual wire pairs. STP provides better noise protection than UTP cabling, however at a significantly higher price.

8.3.3 Unshielded Twisted Pair (UTP) Cable.

Unshielded twisted-pair (UTP) cabling, as it is used in Ethernet LANs, consists of four pairs of color-coded wires that have been twisted together and then encased in a flexible plastic sheath. As seen in the figure, the color codes identify the individual pairs and wires in the pairs and aid in cable termination. The twisting has the effect of canceling unwanted signals. When two wires in an electrical circuit are placed close together, external electromagnetic fields create the same interference in each wire. The pairs are twisted to keep the wires in as close proximity as is physically possible. When this common interference is present on the wires in a twisted pair, the receiver processes it in equal yet opposite ways. As a result, the signals caused by electromagnetic interference from external sources are effectively cancelled. This cancellation effect also helps avoid interference from internal sources called crosstalk. Crosstalk is the interference caused by the magnetic field around the adjacent pairs of wires in the cable. UTP Cabling Standards The UTP cabling commonly found in workplaces, schools, and homes conforms to the standards established jointly by the Telecommunications Industry Association (TIA) and the Electronics Industries Alliance (EIA). TIA/EIA-568A stipulates the commercial cabling standards for LAN installations and is the standard most commonly used in LAN cabling environments. Some of the elements defined are: -Cable types -Cable lengths -Connectors -Cable termination -Methods of testing cable Cables in higher categories are designed and constructed to support higher data rates. As new gigabit speed Ethernet technologies are being developed and adopted, Cat5e is now the minimally acceptable cable type, with Cat6 being the recommended type for new building installations. Some people connect to data network using existing telephone systems. Often the cabling in these systems are some form of UTP that are lower grade than the current Cat5+ standards. Installing less expensive but lower rated cabling is potentially wasteful and shortsighted. If the decision is later made to adopt. UTP Cable Types UTP cabling, terminated with RJ-45 connectors, is a common copper-based medium for interconnecting network devices, such as computers, with intermediate devices, such as routers and network switches. Different situations may require UTP cables to be wired according to different wiring conventions. This means that the individual wires in the cable have to be connected in different orders to different sets of pins in the RJ-45 connectors. The following are main cable types that are obtained by using specific wiring conventions: -Ethernet Straight-through -Ethernet Crossover -Rollover

8.3.7 Wireless Media.

Wireless media carry electromagnetic signals at radio and microwave frequencies that represent the binary digits of data communications. As a networking medium, wireless is not restricted to conductors or pathways, as are copper and fiber media. Types of Wireless Networks The IEEE and telecommunications industry standards for wireless data communications cover both the Data Link and Physical layers. Four common data communications standards that apply to wireless media are: -Standard IEEE 802.11 - Commonly referred to as Wi-Fi, is a Wireless LAN (WLAN) technology that uses a contention or non-deterministic system with a Carrier Sense Multiple Access/Collision Avoidance (CSMA/CA) media access process. -Standard IEEE 802.15 - Wireless Personal Area Network (WPAN) standard, commonly known as "Bluetooth", uses a device pairing process to communicate over distances from 1 to 100 meters. -Standard IEEE 802.16 - Commonly known as Worldwide Interoperability for Microwave Access (WiMAX), uses a point-to-multipoint topology to provide wireless broadband access. -Global System for Mobile Communications (GSM) - Includes Physical layer specifications that enable the implementation of the Layer 2 General Packet Radio Service (GPRS) protocol to provide data transfer over mobile cellular telephony networks. In each of the above examples, Physical layer specifications are applied to areas that include: data to radio signal encoding, frequency and power of transmission, signal reception and decoding requirements, and antenna design and construction.


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