A switch is a telecommunication device
which receives a message from any device connected to it and then transmits the
message only to that device for which the message was meant. It plays an
integral part in most modern Ethernet Local Area Networks (LANs).
Network switch represents the features and technologies that can be used to
respond to the requirements in emerging network design. Some basic operations
and technologies of switches are as follows:
Fast Convergence: Switches stipulate that the
network must adapt quickly to network topology changes.
Deterministic Paths: Switches provide desirability of a
given path to a destination for certain applications or user groups.
Deterministic Failover: Switches specify that a mechanism
be in place to ensure that the network is operational all the times.
Scalable Size and Throughput: Switches provide the
infrastructure that must handle the increased traffic demands.
Centralized Applications: Switches dictate that the
centralized applications be available to support most or all users on the
network.
The New 20/80 Rule: This feature of the switches focus
on the shift in traditional traffic patterns.
Multiprotocol Support: Switches support multiprotocol
environment for the campus network.
Multicasting: Switches support IP multicast
traffic in addition to IP unicast traffic for the campus network.
Before delving into the different switching
technologies, the user must understand the functions performed within the
different OSI reference model layers to understand how both routers and
switches inter-operate and how the different switching technologies work.
The different OSI reference model layers
and the functions that each layer performs are summarized below:
Application
Layer–provides communication services to
applications, file and print services, application services, database services,
and message services.
Presentation
Layer–presents data to the Application layer,
defines frame formats, provides data encryption and decryption and compression
and decompression.
Session
Layer–defines how sessions between nodes are
established, maintained, and terminated and controls communication and
coordinates communication between nodes.
Transport
Layer–provides end-to-end data transport
services.
Network
Layer–transmits packets from the source network
to the specified destination network and defines end-to-end packet delivery,
end-to-end error detection, routing functions, fragmentation, packet switching,
and packet sequence control.
Data-Link
Layer–translates messages into bits for the
Physical layer to transmit and formats messages into data frames.
Physical
Layer–deals with the
sending and the receiving of bits and with the actual physical connection
between the computer and the network medium.
Data encapsulation is the process whereby
the information in a protocol is wrapped within another protocol’s data
section. When a layer of the OSI reference model receives data, the layer
places this data behind its header and before its trailer, and thus
encapsulates the higher layer’s data. In short, each layer encapsulates the
layer directly over it when data moves through the protocol stack. Since the
Physical layer does not use headers and trailers, no data encapsulation is
performed at this layer.
Each OSI reference model layer exchanges
Protocol Data Units (PDUs). The PDUs are added to the data at each OSI
reference model layer.
Each layer that adds PDUs to data has a
unique name for that specific protocol data unit:
- Transport layer = segment
- Network layer = packet
- Data Link layer = frame
- Physical layer = bits
The data encapsulation process is
illustrated below:
1. The user creates the data.
2. At the Transport layer, data is changed
into segments.
3. At the Network layer, segments are
changed into packets or datagrams and routing information is appended to the
protocol data unit.
4. At the Data Link layer, the packets or
datagrams are changed to frames.
5. At the Physical layer, the frames are
changed into bits – 1s and 0s are encoded in the digital signal and are then
transmitted.
Layer 2 Switching Overview
While an Ethernet switch utilizes the same
logic as a transparent bridge, switches use hardware to learn addresses to make
filtering and forwarding decisions. Bridges, on the other hand, utilize
software running on general purpose processors. Switches provide more features
and functions when compared to bridges. Switches have more physical ports as
well.
The basic forward and filter logic that a
switch uses is illustrated here:
1. The frame is received.
2. When the destination is a unicast
address, the address exists in the address table, and the interface is not the
same interface where the frame was received, the frame is forwarded.
3. When the destination is a unicast
address and the address does not exist in the address table, the frame
is forwarded out on all ports.
4. When the destination is a broadcast or
multi-cast address, the frame is forwarded out on all ports.
Switches utilize application specific
integrated circuits (ASICs) to create filter tables and to maintain these
tables’ content. Because Layer 2 switches do not utilize and reference Network
layer header information, they are faster than both bridges and routers. Layer
2 switching is hardware based. The Media Access Control (MAC) address of
the host’s network interface cards (NICs) filters the network.
In short, switches use the frame’s hardware
addresses to determine whether the frame would be forwarded or dropped. Layer 2
switching does not change the data packet, only the frame encapsulating the packet
is read! This basically makes switching a faster process than the routing
process.
The primary differences between bridges
and Layer 2 switches are listed here:
- Bridges utilize software running on general purpose processors to make decisions, which essentially makes bridges software based. Switches use hardware to learn addresses and to make filtering and forwarding decisions.
- For each bridge, only one spanning-tree instance can exist. Switches, on the other hand, can have multiple spanning-tree instances.
- The maximum ports allowed for bridges are 16. One switch can have hundreds of ports.
A few Layer 2 switching benefits
include:
- Low cost
- Hardware-based bridging
- High speed
- Wire speed
- Low latency
- Increases bandwidth for each user
There are a few limitations associated with
Layer 2 switching. Broadcasts and multicasts can cause issues when the network
expands. Another issue is the slow convergence time of the Spanning-Tree
Protocol (SPT). Collision domains also have to be broken up correctly.
Switch Functions Associated with Layer 2
Switching
Layer 2 switching has three main functions:
- Address learning: Layer 2 switches use a MAC database known as the MAC forward/filter table to create and maintain information on which interfaces the sending devices are located on. The forward/filter table contains information on the source hardware address of each frame received. The MAC forward/filter table contains no information when a Layer 2 switch starts for the first time. When a frame is received, the switch examines the frame’s source address and adds this information to the MAC forward/filter table. Because the switch does not know where the device is located that the frame should be sent to, the switch floods the network with the frame. When a device responds by returning a frame, the switch adds the MAC address from that particular frame to the MAC forward/filter table as well. Next, the two devices establish a point-to-point connection and the frame are forwarded between the two.
- Making forwarding and filtering decisions: When a frame is received on a switch interface, the switch examines the frame’s destination hardware address then compares this address to the information contained within the MAC forward/filter table:
- If the destination hardware address is listed in the MAC forward/filter table, the frame is forwarded out the correct exit or destination interface. Bandwidth on the other network segments is preserved because the correct destination interface is used. This concept is known as frame filtering.
- If the destination hardware address is not listed in the MAC forward/filter table, the frame is flooded out all active interfaces, but not on the specific interface on which the frame was received. When a device responds by returning a frame, the switch adds the MAC address from that particular frame to the MAC forward/filter table. Next, the two devices establish a point-to- point connection and the frame is forwarded between the two.
- If a server transmits a broadcast on the LAN, the switch floods the frame out all its ports by default.
- Ensuring loop avoidance: Network loops can typically occur when there are numerous connections between switches. Multiple connections between switches are usually created to allow redundancy. To prevent network loops from occurring and to still maintain redundant links between switches, the Spanning-Tree Protocol (STP) can be used.
The common problems caused by creating
redundant links between switches are listed here:
- While redundant links between routers can provide a few features, remember that frames can in fact be broadcast from all redundant links at the same time. This could possibly result in the creation of network loops.
- Because frames can be received from a number of segments simultaneously, devices can end up receiving multiple copies of the exact frame. This results in additional network overhead.
- When no loop avoidance mechanisms are used, a broadcast storm can occur. Broadcast storms occur when switches flood broadcasts continuously all over the internetwork.
- The user could end up with multiple loops generating all over an internetwork – loops are being created within other loops! This could result in no switching being performed on the network.
- The MAC forward/filter table’s data could become ineffective when switches can receive a frame from multiple links. This is typically due to the table not being able to establish the device’s location.
- Switches can also end up continuously adding source hardware address information to the MAC forward/filter table, to the point that the switch no longer sends frames.
Routing Overview
While routers and Layer 3 switches can be considered similar in concept, their design
differs. Before discussing Layer 3 switching, some important factors on routing
and routers will e summarized.
Routers operate at the Network layer of the
OSI reference model to route data to remote destination networks. Routers use
Layer 3 headers and logic to route packets. Routers use Routing table
information that contains information on how the remote destination networks
can be reached to make routing decisions. Cisco routers maintain a Routing
table for each network protocol. Using routers can be considered a better
option than using bridges. While bridges filter by MAC address, routers filter
by IP address. Bridges forward a packet to all segments that it is connected
to. Routers, on the other hand, only forward the packet to the particular
network segment that the packet is intended for. The default configuration is
that the router does not forward broadcasts and multicast frames.
A few benefits of routing are listed
here:
- Routers do not forward broadcasts and multicasts, thereby decreasing the impact of broadcasts/multicasts. Routers tend to contain broadcasts to localized broadcast domains. They do not forward broadcasts like switches and bridges do.
- Routers perform optimal path determination. Each packet is checked and the router only forwards the packet to the particular network segment for which it is intended.
- The routing protocol configured on the router, path metrics, source service access points (SSAPs), and destination service access points (DSAPs) are utilized to make these informed routing decisions.
- Routers provide traffic management and security.
- Logical Layer 3 addressing is another benefit.
Overview on Layer 3 Switching
As mentioned previously, the main
difference between Layer 3 switches and routers is the physical design. Other
than this, routers and Layer 3 switches perform similar functions. Layer 3
switches can be placed anywhere in the network to process high performance LAN
traffic. In fact, Layer 3 switches can replace routers.
The main functions of Layer 3 switches
are listed here:
- Use logical addressing to determine the paths to destination networks.
- Layer 3 switches can provide security.
- Layer 3 switches can also be used to add Management Information Base (MIB) information to Simple Network Management Protocol (SNMP) managers.
- Layer 3 switches can use Time to Live (TTL).
- They can respond to and process any option information.
A few benefits of Layer 3 switching
include:
- High performance packet switching.
- Hardware based packet forwarding occurs.
- High speed scalability.
- Low cost and low latency.
- Provides security.
- Flow accounting capabilities.
- Quality of service (QoS).
Layer 4 Switching
Layer 4 switching is a Layer 3 hardware
based switching technology that can also provide routing over Layer 3. Layer 4
switching works by taking into account the application that was used. Layer 4
switching examines the port numbers contained within the Transport layer header
to make routing decisions. The ports in the Transport layer header pertain to
the upper layer protocol or application and are defined in Request for Comments
(RFC) 1700.
The characteristics of Layer 4 switching
are listed here:
- A Layer 4 switch has to maintain a larger filter table than the table Layer 3 and Layer 2 switches maintain.
- A Layer 4 switch can be configured to prioritize certain data traffic based on application. This basically allows users to specify QoS for users.
Quick Look at Multi-Layer Switching
(MLS)
Multi-layer switching (MLS) is the
terminology used to describe the technology whereby Layer 2, Layer 3, and Layer
4 switching technologies are combined. Multi-layer switching (MLS) works on the
concept of routing one and switching many.
Multi-layer switching can make routing
decisions with the following:
- The MAC source and MAC destination address within a Data Link frame.
- The IP source address and IP destination address within the Network layer header.
- The protocol defined within the Network layer.
- The port source number and port destination number specified in the Transport layer header.
The features of Multi-Layer Switching
(MLS) are summarized below:
- High speed scalability
- Low latency
- Provide Layer 3 routing
- Transport traffic at wire speed
To read the information in the packet
header, the Cisco Catalyst switches need certain hardware:
- To obtain packet header information and cache the information, Catalyst 5000 switches need the NetFlow Feature Card (NFFC).
- To obtain packet header information and cache the information, Catalyst 6000 switches need the Multilayer Switch Feature Card (MSFC) and the Policy Feature Card (PFC).
The Cisco MLS implementation requires te
following components:
- Multilayer Switching Switch Engine (MLS-SE) – this is a switch that deals with moving and rewriting the packets.
- Multilayer Switching Route Processor (MLS-RP) – an MLS capable router or an RSM, RSFC, MSFC that transmits MLS configuration information and updates.
- Multilayer Switching Protocol (MLSP) – the protocol that operates between the MLS-SE and MLS-RP to enable multilayer switching.
Cisco Catalyst Switches Overview: Cisco Catalyst & Cisco Catalyst Switches
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