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Protocols and Protocol Suit Review Lecture 13 Overview Network Access Layer Transport Layer Protocols Protocol Data Unit Protocol Architecture TCP/IP Stack Layered Approach and its Advantages Router 2 Network Access Layer Q:- What is the major function of the network access layer? 3 OSI Model Application Layer 7 Presentation Layer 6 Session Layer 5 Transport Layer 4 Network Layer 3 Data link Layer 2 Physical Layer 1 7 layers OSI model 4 Physical Layer Functions Establishment and termination of a connection to a communication medium Process for effective use of communication resources (e.g., contention resolution and flow control) Conversion between representation of digital data in the end user’s equipment The physical layer is responsible for movements of individual bits from one hop (node) to the next. 5 Data Link Layer Functions Responds to service requests from the network layer and issues requests to the physical layer. Provides functional and procedural means to transfer data between network entities and to detect and correct errors that may occur in the physical layer. Concerned with: Framing Physical addressing (MAC address) Flow Control Error Control Access Control The data link layer is responsible for moving frames from one hop (node) to the next. 6 Hop-to-hop Delivery 7 Network Layer Functions Provides for transfer of variable length sequences from source to destination via one or more networks Responds to service requests from the transport layer and issues requests to the data link layer Concerned with: Data Packet Logical addressing (IP address) Routing The network layer is responsible for the delivery of individual packets from the source host to the destination host. 8 Source to Destination Delivery 9 Transport Layer Functions Provides transparent data transfer between end users Responds to service requests from the session layer and issues requests to the network layer. Concerned with: Service-point addressing Segmentation and reassembly Connection control and Flow Control (end-to-end) Error Control The transport layer is responsible for the delivery of a message from one process to another. 10 Reliable Process to Process Delivery 11 Session Layer Functions Provides mechanism for managing a dialogue between end-user application processes Responds to service requests from the presentation layer and issues requests to the transport layer Supports duplex or half- duplex operations. Concerned with: Dialogue control Synchronization (Check point) The session layer is responsible for dialog control and synchronization. 12 Presentation Layer Functions Relieves application layer from concern regarding syntactical differences in data representation with end-user systems Responds to service requests from the application layer and issues requests to the session layer Concerned with: Translation Encryption Compression The presentation layer is responsible for translation, compression, and encryption. 13 Application Layer Functions Interfaces directly to and performs common application services for application processes Issues service requests to the Presentation layer Specific services provided: Network virtual terminal File transfer, access and management Mail services Directory services HTTP, FTP, DHCP… The application layer is responsible for providing services to the user. 14 OSI Layered Model 15 TCP/IP Protocol The lower four layers correspond to the layer of the OSI model The application layer of the TCP/IP model represents the three topmost layers of the OSI model. The layers in the TCP/IP protocol suite do not exactly match those in the OSI model. The original TCP/IP protocol suite was defined as having four layers: host-to-network, internet, transport, and application. However, when TCP/IP is compared to OSI, we can say that the TCP/IP protocol suite is made of five layers: physical, data link, network, transport, and application. 16 TCP/IP Protocol stack OSI layers TCP/IP layers Application DNS Presentation Application Session Transport Network Data link Physical FTP, Telnet, SMTP TCP IP OSPF DHCP UDP ICMP IGMP Lower level vendor implementations 17 18 Addressing Four levels of addresses are used in an internet employing the TCP/IP protocols: physical, logical, port, and specific. Topics discussed in this section: Physical Addresses Logical Addresses Port Addresses Specific Addresses 19 Addressing 20 Addressing 21 Example In Figure below a node with physical address 10 sends a frame to a node with physical address 87. The two nodes are connected by a link (bus topology LAN). As the figure shows, the computer with physical address 10 is the sender, and the computer with physical address 87 is the receiver. 22 Example Most local-area networks use a 48-bit (6-byte) physical address written as 12 hexadecimal digits; every byte (2 hexadecimal digits) is separated by a colon, as shown below: 07:01:02:01:2C:4B A 6-byte (12 hexadecimal digits) physical address. 23 Example Figure shows a part of an internet with two routers connecting three LANs. Each device (computer or router) has a pair of addresses (logical and physical) for each connection. In this case, each computer is connected to only one link and therefore has only one pair of addresses. Each router, however, is connected to three networks (only two are shown in the figure). So each router has three pairs of addresses, one for each connection. 24 Example Figure below shows two computers communicating via the Internet. The sending computer is running three processes at this time with port addresses a, b, and c. The receiving computer is running two processes at this time with port addresses j and k. Process a in the sending computer needs to communicate with process j in the receiving computer. Note that although physical addresses change from hop to hop, logical and port addresses remain the same from the source to destination. The physical addresses will change from hop to hop, but the logical addresses usually remain the same. 25 26 TCP/IP Protocol stack OSI layers TCP/IP layers Application DNS Presentation Application Session Transport Network Data link Physical FTP, Telnet, SMTP TCP IP OSPF DHCP UDP ICMP IGMP Lower level vendor implementations 27 Internet Protocol (IP) Provides connection-less, best-effort service for delivery of packets through the inter-network Best-effort: No error checking or tracking done for the sequence of packets (datagrams) being transmitted Upper layer should take care of sequencing Datagrams transmitted independently and may take different routes to reach same destination Fragmentation and reassembly supported to handle data links with different maximum – transmission unit (MTU) sizes 28 Internet Control Message Protocol (ICMP) Companion protocol to IP Provides mechanisms for error reporting and query to a host or a router Query message used to probe the status of a host or a router Error reporting messages used by the host and the routers to report errors 29 Internet Group Management Protocol (IGMP) Used to maintain multicast group membership within a domain Similar to ICMP, IGMP query and reply messages are used by routers to maintain multicast group membership Periodic IGMP query messages are used to find new multicast members within the domain A member sends a IGMP join message to the router, which takes care of joining the multicast tree 30 Dynamic Host Configuration Protocol (DHCP) Used to assign IP addresses dynamically in a domain Extension to Bootstrap Protocol (BOOTP) Node Requests an IP address from DHCP server Helps in saving IP address space by using same IP address to occasionally connecting hosts 31 Internet Routing Protocols Routing Information Protocol (RIP) An intra-domain distance vector routing protocol Uses the Bellman-Ford algorithm to calculate routing table Distance information about all the nodes is conveyed to the neighbors. Open Shortest Path First (OSPF) Based on shortest path algorithm, sometimes also known as Dijkstra algorithm Hosts are partitioned into autonomous systems (AS) AS is further partitioned into OSPF areas that helps boarder routers to identify every single node in the area Link-state advertisements sent to all routers within the same 32 hierarchical area Internet Routing Protocols Border Gateway Protocol (BGP) Intra-autonomous systems communicate with each other using path vector routing protocol Each entry in the routing table contains the destination network, the next router, and the path to reach the destination 33 Example Interior Router BGP Router 34 TCP 6 1 4 A routing table maintained at each node, indicating the best known distance and next hop to get there Calculate w(u,v), is the cost associated with edge uv Calculate d(u), the distance of node u from a root node For each uv, find minimum d(u,v) Repeat n-1 times for n-nodes 3 2 3 3 1 -1 4 3 Application Layer Top three layers (session, presentation, and application) merged into application layer Routing using Bellman-Ford Algorithm 0 2 Root Abstract model of a wireless network in the form of a graph 35 TCP (ctd) 1 1 6 4 3 3 2 Abstract model of a wireless network in the form of a graph 3 1 -1 3 2 4 0 Pass 3 Pass 4 0 1 * * 2 3 4 0 Pass 0 8 Pass 2 To Node 3 2 Pass 1 8 8 0 4 8 8 8 Pass 1 3 8 0 2 8 8 Pass 0 1 8 0 Root 8 8 To Node 0 7 3 1 2 Pass 2 * 2 0 4 0 0 4 3 1 2 Pass 3 * 3 0 4 0 0 4 3 1 2 Pass 4 * 3 0 4 0 Successive calculation of distance D(u) from node 0 0 Predecessor from node 0 to other network nodes 36 TCP over Wireless The wireless domain is not only plagued by the mobility problem, but also by high error rates and low BW Traditional TCP: provides a connected-oriented, reliable, and byte stream service TCP functions: flow-control (controlled by sliding window), congestion-control (congestion window), data segmentation, retransmission, and recovery Slow Start: resets the congestion window (CW) size to one and let threshold to half of the current CW size Double the CW on every successful transmission until the CW reach threshold and after that increases the CW by one for each successful transmission 37 Solutions for Wireless Environment Networking layering provides good abstraction in the network design Wireless networks are interference limited, and the information delivery capability is closely dependent on current channel quality Adoption in physical and link layer broadcast could lead to efficient resource usage Protocol changes need to be made in MSs and mobile access points to ensure compatibility with existing TCP applications 38 End-to-End Solutions TCP-SACK WTCP Protocol Selective Acknowledgement and Selective Retransmission. Sender can retransmit missing data due to random errors/mobility Separate flows for wired (Sender to AP) and wireless (AP to MS) segments of TCP connections Local retransmission for mobile link breakage AP sends ACK to sender after timestamp modification to avoid change in round trip estimates Freeze-TCP Protocol Mobile detects impending handoff Advertises Zero Window size, to force the sender into Zero Window Probe mode 39 End-to-End Solutions (Cont’d) Explicit Band State Notification (EBSN) Local Retransmission from BS (AP) to shield wireless link errors EBSN message from BS to Source during local recovery Source Resets its timeout value after EBSN Fast Retransmission Approach Tries to reduce the effect of MS handoff MS after handoff sends certain number of duplicate ACKs Avoids coarse time-outs at the sender, accelerates retransmission 40 Link Layer Protocols Snoop Protocol Transport layer aware Snoop Agent at BS Agent monitors all TCP segments destined to MS, caches it in buffer Also monitors ACKs from MS Loss detected by duplicate ACKs from MS or local time-out Local Retransmission of missing segment if cached Suppresses the duplicate ACKs 41 Split TCP Approach Indirect TCP: splits the TCP connection into two distinct connections, one is MS and BS and another is BS and corresponding node (CN) The AP acts as a proxy for MS The AP acknowledges CN for the data sent to MS and buffers this data until it is successfully transmitted to MS Handoff may take a longer time as all the data acknowledged by AP and not transmitted to MS must be buffered at the new AP 42 Indirect TCP Wireless link MS Wired Domain AP CN (Acts as proxy) 43 Split TCP Approach (Cont’d) M-TCP Protocol Split the connection into wired component and wireless component BS relays ACKs for sender only after receiving ACKs from MS In case of frequent disconnections, receiver can signal sender to enter in persist mode by advertising Zero Window size 44 Impact of Mobility Handoffs occur in wireless domains when an MN moves into a new BS’s domain The result of the packet loss during handoff is slow start The solution involves artificially forcing the sender to go into fast retransmission mode immediately, by sending DUP ACK after the handoff, instead of go into slow start Using multicast: the MN is required to define a group of BSs that it is likely to visit in the near future Reduce the handoff latency: Only one BS is in contact with the MN and the others buffer the packets addressed to the multicast address 45 Internet Protocol Version 6 (IPv6) Designed to address the unforeseen growth of the internet and the limited address space provided by IPv4 Features of IPv6: • Enhanced Address Space: 128 bits long, can solve the problem created by limited IPv4 address space (32 bits) • Resource Allocation: By using “Flow Label”, a sender can request special packet handling • Modified Address Format: Options and Base Header are separated which speeds up the routing process • Support for Security: Encryption and Authentication options are supported in option header 46 IPv4 Header Format Version (4 bits) Header length (4 bits) Type of service (8 bits) Identification (16 bits) Time to live (8 bits) Protocol (8 bits) Total length (16 bits) Flags (3 bits) Fragment offset (13 bits) Header checksum (16 bits) Source address (32 bits) Destination address (32 bits) Options and padding (if any) 47 IPv6 Header Format Address Space Resource Allocation Modified Header Format Support for Security Version Traffic Class Flow Label Payload Length Next Hop Header Limit Source Address Destination Address Data 48 Format of IPv6 Name Bits Function Version 4 IPv6 version number Traffic Class 8 Internet traffic priority delivery value Flow Label 20 Used for specifying special router handling from source to destination(s) for a sequence of packets Payload Length Next Header Hop Limit 16, unsigned 8 8, unsigned Specifies the length of the data in the packet. When set to zero, the option is a hop-by-hop Jumbo payload Specifies the next encapsulated protocol. The values are compatible with those specified for the IPv4 protocol field For each router that forwards the packet, the hop limit is decremented by 1. When the hop limit field reaches zero, the packet is discarded. This replaces the TTL field in the IPv4 header that was originally intended to be used as a time based hop limit Source Address 128 The IPv6 address of the sending node Destination Address 128 The IPv6 address of the destination node 49 Differences between IPv4 and IPv6 Expanded Addressing Capabilities Simplified Header Format Improved Support for Options and Extensions Flow Labeling Capabilities Support for Authentication and Encryption 50 Network Transition from IPv4 to IPv6 • Dual IP-Stack: IPv4-hosts and IPv4-routers have an IPv6-stack, this ensures full compatibility to not yet updated systems • IPv6-in-IPv4 Encapsulation (Tunneling): Encapsulate IPv6 datagram in IPv4 datagram and tunnel it to next router/host 51 52 Network Access Layer The Internet Protocol Suite (commonly known as TCP/IP) is the set of communications protocols used for the Internet and other similar networks. Transmission Control Protocol (TCP) and the Internet Protocol (IP) The Internet Protocol Suite may be viewed as a set of layers. Each layer solves a set of problems involving the transmission of data, and provides a well-defined service to the upper layer protocols based on using services from some lower layers. The TCP/IP model consists of four layers. This layer architecture is often compared with the seven-layer OSI Reference Model. From lowest to highest, these are • the Network Access Layer, • the Internet Layer, • the Transport Layer, • and the Application Layer The TCP/IP Network Access Layer can encompass the functions of two lower layers of theOSI reference Model: Data Link, and Physical. 53 Network Access Layer Q:- What is the major function of the network access layer? Ans: The network access layer is concerned with the exchange of data between a computer and the network to which it is attached. 54 55 Transport Layer Recap Q:- What tasks are performed by the transport layer? Isolates messages from lower and upper layers Breaks down message size Monitors quality of communications channel Selects most efficient communication service necessary for a given transmission 56 Transport Layer Concerned with reliable transfer of information between applications Independent of the nature of the application Includes aspects like flow control and error checking 57 Transport Layer Recap Q:- What tasks are performed by the transport layer? Ans:- The transport layer is concerned with data reliability and correct sequencing. 58