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    Ts patil Ts patil Presentation Transcript

    • SONET
      • S ynchronous O ptical NET work (SONET) – North America
      • Synchronous Digital Hierarchy – Europe
      • SONET is said to be service-independent or transparent.
    • SONET
      • SONET is a standard for optical telecommunications transport formulated by the Exchange Carriers Standards Association (ECSA) for the American National Standards Institute (ANSI), which sets industry standards in the U.S. for telecommunications and other industries.
    • SONET
      • SONET is a physical layer network technology designed to carry large volumes of traffic over relatively long distances on fiber optic cabling.
      • SONET was originally designed by ANSI for the public telephone network in the mid-1980s.
    • SONET
      • SONET defines clear interoperability standards between different vendors' products.
      • SONET can carry nearly any higher-level protocol (including IP), and it includes built-in support for ease of management and maintenance.
    • SONET
      • SONET performs at high speeds at a cost competitive with alternatives like ATM and Gigabit Ethernet.
      • SONET commonly transmits data at speeds between 155 Mbps and 2.5 Gbps.
    • SONET
      • To build these high-bandwidth data streams, SONET multiplexes together channels having bandwidth as low as 64 Kpbs into data frames sent at fixed intervals.
    • SONET
      • The increased configuration flexibility and bandwidth availability of SONET provides significant advantages over the older telecommunications system.
      • SONET defines optical carrier (OC) levels and electrically equivalent synchronous transport signals (STSs) for the fiber-optic–based transmission hierarchy.
    • SONET: advantages
      • Reduction in equipment requirements and an increase in network reliability
      • Provision of overhead and payload bytes—the overhead bytes permit management of the payload bytes on an individual basis and facilitate centralized fault sectionalization
    • SONET: advantages
      • Definition of a synchronous multiplexing format for carrying lower level digital signals and a synchronous structure that greatly simplifies the interface to digital switches, digital cross-connect switches, and add-drop multiplexers
    • SONET: advantages
      • Availability of a set of generic standards that enable products from different vendors to be connected
      • Definition of a flexible architecture capable of accommodating future applications, with a variety of transmission rates
    • Synchronization of Digital Signals
      • There are 3 types of signals;
        • Synchronous
        • Plesiochronous
        • Asynchronous
    • Synchronization of Digital Signals
      • Synchronous signals ….
        • The digital transitions in the signals occur at exactly the same rate.
        • In a synchronous network, all the clocks are traceable to one primary reference clock (PRC).
    • Synchronization of Digital Signals
      • Plesiochronous signals…
        • Their transitions occur at almost the same rate, with any variation being constrained within tight limits.
    • Synchronization of Digital Signals
      • Asynchronous signals….
        • The transitions of the signals do not necessarily occur at the same nominal rate.
        • Asynchronous means that the difference between two clocks is much greater than a plesiochronous difference.
    • Basic SONET signal
      • SONET defines a technology for carrying many signals of different capacities through a synchronous, flexible, optical hierarchy.
      • This is accomplished by means of a byte-interleaved multiplexing scheme.
      • Byte-interleaving simplifies multiplexing and offers end-to-end network management
    • Basic SONET signal
      • The first step in the SONET multiplexing process involves the generation of the lowest level or base signal.
      • In SONET, this base signal is referred to as synchronous transport signal–level 1, or simply STS–1, which operates at 51.84 Mbps.
    • Basic SONET signal
      • Higher-level signals are integer multiples of STS–1, creating the family of STS–N signals.
      • An STS–N signal is composed of N byte-interleaved STS–1 signals.
    • Basic SONET signal STS = synchronous transport signal N byte-interleaved; OC-N = Optical carrier level N ; DS = Digital Signal. SONET Hierarchy 5,376 DS–1s or 192 DS–3s 9,953.280 STS–192, OC–192 1,344 DS–1s or 48 DS–3s 2,488.320 STS–48, OC–48 336 DS–1s or 12 DS–3s 622.080 STS–12, OC–12 84 DS–1s or 3 DS–3s 155.520 STS–3, OC–3 28 DS–1s or 1 DS–3 51.840 STS–1, OC–1 Capacity Bit Rate (Mbps) Signal
    • Basic SONET signal Nonsynchronous Hierarchy 28 DS–1s 44.736 DS–3 96 DS–0s 6.312 DS–2 24 DS–0s 1.544 DS–1 1 DS–0 0.064 DS–0 Channels Bit Rate (Mbps) Signal
    • Why Synchronize?
      • In digital transmission, asynchronous mode, clocking is one of the most important considerations.
      • Clocking means using a series of repetitive pulses to keep the bit rate of data constant and to indicate where the ones and zeroes are located in a data stream.
      • These clocks are totally free-running and not synchronized, large variations occur in the clock rate and thus the signal bit rate.
    • Why Synchronize?
      • In a synchronous system such as SONET, the average frequency of all clocks in the system will be the same (synchronous) or nearly the same ( plesiochronous ).
      • If two digital signals are plesiochronous, their transitions occur at almost the same rate, with any variation being constrained within tight limits.
    • Why Synchronize?
      • Every clock can be traced back to a highly stable reference supply (PRC) .
        • Thus, the STS–1 rate remains at a nominal 51.84 Mbps, allowing many synchronous STS–1 signals to be stacked together when multiplexed without any bit-stuffing.
        • Thus, the STS–1s are easily accessed at a higher STS–N rate.
    • Synchronizing SONET
      • The internal clock of a SONET terminal will serve as a master for other SONET nodes.
      • This internal clock provides timing on its outgoing Optical Carrier level N (OC–N) signal.
      • Other SONET nodes will operate in a slave mode called loop timing with their internal clocks timed by the incoming OC–N signal.
    • SONET Frame Format
      • SONET uses a basic transmission rate of STS–1 that is equivalent to 51.84 Mbps.
      • Higher-level signals are integer multiples of the base rate.
        • For example, STS–3 is three times the rate of STS–1 ;
          • 3 x 51.84 = 155.52 Mbps
    • SONET: STS–1 Building Block STS–1 Frame Format
    • SONET: STS–1 Building Block STS–1 Frame Elements
    • SONET: STS–1 Building Block
      • STS-1 frame can be divided into two main areas:
        • transport overhead
        • synchronous payload envelope (SPE)
          • the STS path overhead (POH)
          • the payload
    • SONET: STS–1 Building Block
    • SONET: STS–1 Building Block
      • The payload is the revenue-producing traffic being transported and routed over the SONET network.
      • Once the payload is multiplexed into the synchronous payload envelope, it can be transported and switched through SONET without having to be examined and possibly demultiplexed at intermediate nodes.
    • SONET: STS–1 Building Block
      • STS–1 is a specific sequence of 810 bytes (6,480 bits) -- 90-column by 9-row structure
      • 810 bytes include various overhead bytes and an envelope capacity for transporting payloads.
    • SONET: STS–1 Building Block
      • The byte transmission order is row-by-row, left to right.
      • With a frame length of 125  s (8,000 frames per second), STS–1 has a bit rate of 51.840 Mbps.
      STS–1 signal rate =(9) x (90 bytes/frame) x (8 bits/byte) x (8,000 frames/s) = 51,840,000 bps =51.840 Mbps
    • SONET Alarm Structure
      • The overhead information provides a variety of management and other functions (such as centralized fault sectionalization).
      • Much of this overhead information is involved with alarm and in-service monitoring of the particular SONET sections.
    • SONET Alarm Structure
      • Overhead Information are such as;
        • error performance monitoring
        • pointer adjustment information
        • path status
        • path trace
        • section trace
        • remote defect, error, and failure indications
    • SONET Alarm Structure
      • (Cont.)
        • signal labels
        • new data flag indications
        • data communications channels (DCC)
        • automatic protection switching (APS) control
        • orderwire
        • synchronization status message
    • SONET Alarms
      • SONET alarms are defined as follows:
        • anomaly
        • defect
        • failure
    • SONET Alarm: anomaly
      • This is the smallest discrepancy that can be observed between the actual and desired characteristics of an item.
      • The occurrence of a single anomaly does not constitute an interruption in the ability to perform a required function.
    • SONET Alarm: defect
      • The density of anomalies has reached a level where the ability to perform a required function has been interrupted.
      • Defects are used as input for performance monitoring, the control of consequent actions, and the determination of fault cause.
    • SONET Alarm: failure
      • This is the inability of a function to perform a required action persisted beyond the maximum time allocated.
    • ISDN
      • Integrated Services Digital Network (ISDN)
      • ISDN offers faster networking speeds than conventional dial-up for home and business users.
      • ISDN is a network technology that supports transfer of simultaneous voice and data traffic.
    • ISDN
      • Similar to DSL in this respect, an ISDN Internet service works over ordinary telephone lines.
      • ISDN Internet service generally supports data rates of 128 Kbps.
      • The relatively high cost of service, though, limited its popularity with home users.
    • ISDN BRT
      • BRT = Basic Rate Interface
      • In order to use ISDN BRI, each end of the connection requires special equipment to communicate over the digital network.
    • ISDN BRT
      • There are two pieces of the ISDN puzzle that are required at the end points of a connection.
        • The network termination (NT) equipment
        • The terminal equipment (TE) or terminal adapter(TA )
    • ISDN BRT
      • NT equipment provides the interface between the phone company's ISDN services and the user's equipment.
      • TE's are built to talk directly to an ISDN connection, whereas a TA provides the conversion necessary for non-ISDN devices to talk to the ISDN network.
    • ISDN BRT
      • ISDN BRI service runs over the ordinary telephone twisted pair wiring that is installed in most every home today which means that these homes are ISDN ready.
      • The phone company must have ISDN service available in the area.
    • ISDN BRT
      • One of the advantages ISDN BRI has over plain old telephone service (POTS) is the fact that it provides a high speed digital connection through the phone system.
    • ISDN BRT
      • ISDN BRT ( 2B+D) contains two types of channels;
        • bearer channels  B-channel;
          • two 64 Kbps digital channels
          • carry the data, voice or video traffic
        • delta channel  D-channel;
          • 16 Kbps digital channel
          • primarily used for signaling and call setup information.
    • ISDN BRT
      • Each B-channel in ISDN BRI is conceptually equivalent to a standard POTS line.
      • They are each assigned a separate identifier or phone number by which they can individually make and receive calls (connections).