Week 5-2.docx

Transcript

**Week 5-2**

**Ethernet Switching**

**Ethernet Frames**

**Ethernet Encapsulation**

Ethernet operates in the data link layer and the physical layer.

It is a family of networking technologies defined in the IEEE802.2 and
802.3 standards.A close-up of a computer screen Description
automatically generated

**Data Link Sublayers**

The 802 LAN/MAN standards, including Ethernet, use two separate
sublayers of the data link layer to operate:

**LLC Sublayer**: (IEEE 802.2) Places information in the frame to
identify which network layer protocol is used for the frame.

**MAC Sublayer**: (IEEE 802.3, 802.11, or 802.15) Responsible for data
encapsulation and media access control and provides data link layer
addressing![A close-up of a computer network Description automatically
generated](media/image2.png)

**MAC Sublayer**

The MAC sublayer is responsible for data encapsulation and accessing the
media.

**Data Encapsulation**

IEEE 802.3 data encapsulation includes the following:

**1. Ethernet frame**- This is the internal structure of the Ethernet
frame.

**2. Ethernet Addressing**- The Ethernet frame includes both a source
and destination MAC address to deliver the Ethernet frame from Ethernet
NIC to Ethernet NIC on the same LAN.

**3. Ethernet Error detection**- The Ethernet frame includes a frame
check sequence (FCS) trailer used for error detection.

**MAC Sublayer**

**Media Access**

The IEEE 802.3 MAC sublayer includes the specifications for different
Ethernet communications standards over various types of media including
copper and fiber.

Legacy Ethernet using a bus topology or hubs, is a shared, half-duplex
medium. Ethernet over a half-duplex medium uses a contention-based
access method, carrier sense multiple access/collision detection
(CSMA/CD).

Ethernet LANs of today use switches that operate in full duplex.
Full-duplex communications with Ethernet switches do not require access
control through CSMA/CD.A screen shot of a computer Description
automatically generated

**Ethernet Frame Fields**

The minimum Ethernet frame size is 64 bytes and the maximum is 1518
bytes. The preamble field is not included when describing the size of
the frame.

Any frame less than 64 bytes in length is considered a "collision
fragment" or "runt frame" and is automatically discarded. Frames with
more than 1500 bytes of data are considered "jumbo" or "baby giant
frames".

If the size of a transmitted frame is less than the minimum, or
greater than the maximum,

the receiving device drops the frame. Dropped frames are likely to be
the result of

collisions or other unwanted signals. They are considered invalid. Jumbo
frames are

usually supported by most Fast Ethernet and Gigabit Ethernet switches
and NICs.![A diagram of a computer data Description automatically
generated](media/image4.png)

**\
**

**MEDIA ACCESS CONTROL**

- MediaAccess Control Protocol:

CSMA/CD: Carrier Sense MultipleAccess / Collision Detection

- Ethernet is a "Local Area Network"

It is a layer 2 protocol intended for multiple user access

A computer network diagram Description automatically generated with
medium confidence- - Each station is electrically attached to the shared
Ethernet cable using a MAU

\- Ethernet CSMA/CD Protocol

1\. A station listens for a signal on the Ethernet Cable

2\. If no signal is heard then the station transmits the frame and
listens for

collisions

3\. If a collision occurs, then delay a random backoff wait-time and
retry

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**

1. Ethernet Hub replaces Ethernet Cable

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**

**Unicast MAC Address**

In Ethernet, different MAC addresses are used for Layer 2 unicast,
broadcast, and multicast communications.

A unicast MAC address is the unique address that is used when a frame
is sent from a single transmitting device to a single destination
device.

The process that a source host uses to determine the destination MAC
address

associated with an IPv4 address is known as Address Resolution Protocol
(ARP).

The process that a source host uses to determine the destination MAC
address

associated with an IPv6 address is known as Neighbor Discovery (ND).

**Note:** The source MAC address must always

be a unicast

![A diagram of a computer network Description automatically
generated](media/image10.png)

**\
**

**Broadcast MAC Address**

An Ethernet broadcast frame is received and processed by every device on
the Ethernet LAN. The features of an Ethernet broadcast are as follows:

It has a destination MAC address of FF-FF-FF-FF-FF-FF in hexadecimal
(48 ones in binary).

It is flooded out all Ethernet switch ports except the incoming port.
It is not forwarded by a router.

If the encapsulated data is an IPv4 broadcast packet, this means the
packet contains a destination IPv4 address that has all ones (1s) in the
host portion. This numbering in the address means that all hosts on that
local network (broadcast domain) will receive and process the packet.

A diagram of a network connection Description automatically generated

**Multicast MAC Address**

An Ethernet multicast frame is received and processed by a group of
devices that belong to the same multicast group.

There is a destination MAC address of 01-00-5E when the encapsulated
data is an IPv4 multicast packet and a destination MAC address of 33-33
when the encapsulated

data is an IPv6 multicast packet.

There are other reserved multicast destination MAC addresses for when
the encapsulated data is not IP, such as Spanning Tree Protocol (STP).

It is flooded out all Ethernet switch ports except the incoming port,
unless the switch is configured for multicast snooping. It is not
forwarded by a router, unless the router is configured to route
multicast packets.

Because multicast addresses represent a group of addresses (sometimes
called a host group), they can only be used as the destination of a
packet. The source will always be a unicast address.

As with the unicast and broadcast addresses, the multicast IP address
requires a corresponding multicast MAC address.

![A diagram of a network Description automatically
generated](media/image12.png)

**THE MAC ADDRESS TABLE**

**Switch Fundamentals**

** ** A Layer 2 Ethernet switch uses Layer 2 MAC addresses to make
forwarding

decisions. It is completely unaware of the data (protocol) being carried
in the data

portion of the frame, such as an IPv4 packet, an ARP message, or an IPv6
ND

packet. The switch makes its forwarding decisions based solely on the
Layer 2

Ethernet MAC addresses.

An Ethernet switch examines its MAC address table to make a forwarding
decision for

each frame, unlike legacy Ethernet hubs that repeat bits out all ports
except the

incoming port.

When a switch is turned on, the MAC address table is empty

Note: The MAC address table is sometimes referred to as a content
addressable memory

(CAM) table.

**Switch Learning and Forwarding**

- **Examine the Source MAC Address (Learn)**

Every frame that enters a switch is checked for new information to
learn. It does this by examining the source MAC address of the frame and
the port number where the frame entered the switch. If the source MAC
address does not exist, it is added to the table along with the incoming
port number. If the source MAC address does exist, the switch updates
the refresh timer for that entry. By default, most Ethernet switches
keep an entry in the table for 5 minutes.

***Note**: If the source MAC address does exist in the table but on a
different port, the switch treats this as a new entry. The entry is
replaced using the same MAC address but with the more current port
number.*

- **Find the Destination MAC Address (Forward)**

If the destination MAC address is a unicast address, the switch will
look for a match between the destination MAC address of the frame and an
entry in its MAC address table. If the destination MAC address is in the
table, it will forward the frame out the specified port. If the
destination MAC address is not in the table, the switch will forward the
frame out all ports except the incoming port. This is called an unknown
**unicast.**

***Note**: If the destination MAC address is a broadcast or a multicast,
the frame is also flooded out all ports except the incoming port.*

**Filtering Frames**

As a switch receives frames from different devices, it is able to
populate its MAC address table by examining the source MAC address of
every frame. When the MAC address table of the switch contains the
destination MAC address, it is able to filter the frame and forward out
a single port. A computer address panel with many computer ports
Description automatically generated with medium confidence*\
*

**Frame Forwarding Methods on Cisco Switches**

**Switch speeds and Forwarding Methods**

Frame Forwarding Methods on Cisco Switches

Switches use one of the following forwarding methods for switching data
between network ports:

**Store-and-forward switching**- This frame forwarding method receives
the entire frame and computes the CRC. If the CRC is valid, the switch
looks up the destination address, which determines the outgoing
interface. Then the frame is forwarded out of the correct port.

**Cut-through switching**- This frame forwarding method forwards the
frame before it is entirely received. At a minimum, the destination
address of the frame must be read before the frame can be forwarded.

A big advantage of store-and-forward switching is that it determines
if a frame has errors before propagating the frame. When an error is
detected in a frame, the switch discards the frame. Discarding frames
with errors reduces the amount of bandwidth consumed by corrupt data.

Store-and-forward switching is required for quality of service (QoS)
analysis on converged networks where frame classification for traffic
prioritization is necessary. For example, voice over IP (VoIP) data
streams need to have priority over web-browsing traffic.

**Cut-Through Switching**

In cut-through switching, the switch acts upon the data as soon as it is
received, even if the transmission is not complete. The switch buffers
just enough of the frame to read the destination MAC address so that it
can determine to which port it should forward out the data. The switch
does not perform any error checking on the frame. There are two variants
of cut-through switching:

**Fast-forward switching** - Offers the lowest level of latency by
immediately forwarding a packet after reading the destination address.
Because fast-forward switching starts forwarding before the entire
packet has been received, there may be times when packets are relayed
with errors. The destination NIC discards the faulty packet upon
receipt. Fast- forward switching is the typical cut-through method of
switching.

**Fragment-free switching** - A compromise between the high latency
and high integrity of store-and-forward switching and the low latency
and reduced integrity of fast-forward switching, the switch stores and
performs an error check on the first 64 bytes of the frame

before forwarding. Because most network errors and collisions occur
during the first 64 bytes, this ensures that a collision has not
occurred before forwarding the frame.

**Memory Buffering on Switches**

An Ethernet switch may use a buffering technique to store frames before
forwarding them or when the destination port is busy because of
congestion.

+-----------------------------------+-----------------------------------+
| **Method** | **Description** |
+===================================+===================================+
| Port-based memory | Frames are stored in queues that |
| | are linked to specific incoming |
| | and outgoing ports. |
| | |
| | A frame is transmitted to the |
| | outgoing port only when all the |
| | frames ahead in the queue have |
| | been successfully transmitted. |
| | |
| | It is possible for a single |
| | frame to delay the transmission |
| | of all the frames in memory |
| | because of a busy destination |
| | port. |
| | |
| | This delay occurs even if the |
| | other frames could be transmitted |
| | to open destination ports. |
+-----------------------------------+-----------------------------------+
| Shared memory | Deposits all frames into a |
| | common memory buffer shared by |
| | all switch ports and the amount |
| | of buffer memory required by a |
| | port is dynamically allocated. |
| | |
| | The frames in the buffer are |
| | dynamically linked to the |
| | destination port enabling a |
| | packet to be received on one port |
| | and then transmitted on another |
| | port, without moving it to a |
| | different queue. |
+-----------------------------------+-----------------------------------+

Shared memory buffering also results in larger frames that can be
transmitted with fewer dropped frames. This is important with asymmetric
switching which allows for different data rates on different ports.
Therefore, more bandwidths can be dedicated to certain ports (e.g.,
server port).

**Duplex and Speed Settings**

Two of the most basic settings on a switch are the bandwidth ("speed")
and duplex settings for each individual switch port. It is critical that
the duplex and bandwidth settings match between the switch port and the
connected devices.

There are two types of duplex settings used for communications on an
Ethernet network:

**Full-duplex**- Both ends of the connection can send and receive
simultaneously.

**Half-duplex**- Only one end of the connection can send at a time.

**Autonegotiation** is an optional function found on most Ethernet
switches and NICs. It enables two devices to automatically negotiate the
best speed and duplex capabilities.

***Note**: Gigabit Ethernet ports only operate in full-duplex.*

Duplex and Speed Settings

Duplex mismatch is one of the most common causes of performance issues
on

10/100 Mbps Ethernet links. It occurs when one port on the link operates
at half-

duplex while the other port operates at full duplex.

This can occur when one or both ports on a link are reset, and the
autonegotiation

process does not result in both link partners having the same
configuration.

It also can occur when users reconfigure one side of a link and forget
to reconfigure the other. Both sides of a link should have
autonegotiation on, or both sides should have it off. Best practice is
to configure both Ethernet switch ports as full duplex.

![A diagram of a fire Description automatically
generated](media/image14.png)

Auto-MDIX

Connections between devices once required the use of either a crossover
or straight-through cable. The type of cable required depended on the
type of interconnecting devices.

***Note**: A direct connection between a router and a host requires a
cross-over connection.*

Most switch devices now support the automatic medium-dependent
interface

crossover (auto-MDIX) feature. When enabled, the switch automatically
detects the

type of cable attached to the port and configures the interfaces
accordingly.

The auto-MDIX feature is enabled by default on switches running Cisco
IOS Release

12.2(18)SE or later. However, the feature could be disabled. For this
reason, you

should always use the correct cable type and not rely on the auto-MDIX
feature.

Auto-MDIX can be re-enabled using the **mdix auto** interface
configuration command