oct-03 ©cisco systems ccna semester 1 version 3 comp11 mod7 – st. lawrence college – cornwall...
TRANSCRIPT
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 1
Cisco Systems CCNA Version 3 Semester 1
Module 7
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 2
Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 3
This module introduces the specifics of the most important varieties of Ethernet.
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Students completing this module should be able to:
1. Describe the differences and similarities among 10BASE5, 10BASE2, and 10BASE-T Ethernet.
2. Define Manchester encoding. 3. List the factors affecting Ethernet timing limits. 4. List 10BASE-T wiring parameters. 5. Describe the key characteristics and varieties of 100-Mbps
Ethernet. 6. Describe the evolution of Ethernet. 7. Explain the MAC methods, frame formats, and transmission
process of Gigabit Ethernet. 8. Describe the uses of specific media and encoding with Gigabit
Ethernet. 9. Identify the pinouts and wiring typical to the various
implementations of Gigabit Ethernet. 10. Describe the similarities and differences between Gigabit and
10 Gigabit Ethernet. 11. Describe the basic architectural considerations of Gigabit and
10 Gigabit Ethernet.
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Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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All versions of Ethernet have the same:1. MAC addressing2. CSMA/CD3. Frame format
However, other aspects of the MAC sublayer, physical layer, and medium have changed.
10 0
Note: error ?
802.2
Legacy Ethernet
7.1.1 10-Mbps and 100-Mbps Ethernet
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7.1.1 10-Mbps Ethernet
Common timing parameters – all 10 Mbps10BASE2 - 10BASE5 - 10BASE-T
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7.1.1 10-Mbps Ethernet
Common Frame Format
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7.1.1 10-Mbps Ethernet
Differences from higher Bit Rates1. Signal Quality Errors (AKA Heartbeat or CPT)
SQE is always used in half-duplex. (Can be used in full-duplex operation but is not required.) www.ethermanage.com/ethernet/sqe/sqe.html
SQE is active: • Within 4 to 8 microseconds following a normal
transmission to indicate that the outbound frame was successfully transmitted.
• Whenever there is a collision on the medium.• Whenever there is an improper signal on the
medium. Improper signals might include jabber, or reflections that result from a cable short.
• Whenever a transmission has been interrupted.
2. 10 Mbps uses Manchester Encoding3. 10 Mbps System Layout(Architecture
features)
As the frame passes from the MAC sublayer to the physical layer, speed dependent processes occur prior to the bits being placed from the physical layer
onto the medium.
??
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The purpose of the CQE signal is to test the important collision detection electronics of the transceiver, and to let the Ethernet interface in the computer know that the collision detection circuits and signal paths are working correctly. The earliest Ethernet standard, DIX V1.0, did not include a test signal for the collision detection system. However, in the DIX V2.0 specifications the transceiver was provided with a new signal called Collision Presence Test (CPT) whose nickname was "heartbeat."
The way heartbeat works is simple: after every packet is sent, the transceiver waits a few bit times and then sends a short burst of the collision detect signal over the collision presence wires of the transceiver cable back to the Ethernet interface, thereby testing all aspects of the collision detection electronics and signal paths. The result is that the Ethernet interface in the computer receives a heartbeat signal on the collision presence signal wires of the transceiver cable after every packet transmission made by the interface.
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7.1.1 10-Mbps Ethernet
• No Direct Current• Always a
synchronizing signal
Encoding – Manchester
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• Not recommended for new installations. • Sensitive to signal reflections on the cable. • Single point of failure. • The cable is large, heavy, and difficult to
install. • Half-duplex only.
7.1.2 10BASE5
Thick Net
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7.1.2 10BASE5
1. Legacy Ethernet has common architectural features. 2. Networks usually contain multiple types of media. 3. The standard ensures that interoperability is
maintained. 4. The overall architectural design is of the utmost
importance when implementing a mixed-media network.
5. It becomes easier to violate maximum delay limits as the network grows and becomes more complex.
6. The timing limits are based on parameters such as: • Cable length and its propagation delay • Delay of repeaters • Delay of transceivers • Interframe gap shrinkage • Delays within the station
The main advantages of 10BASE5 were:• It was inexpensive • No configuration was necessary
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• Not more than five segments.• No more than four repeaters may be connected in series
between any two distant stations. • No more than three populated segments.
7.1.2 10BASE5
The 5-4-3 rule.
no more than 5 segments separated by more than 4 repeaters, and no more than three populated segments
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7.1.3 10BASE2
• Not recommended for new installations. • Sensitive to signal reflections on the cable. • Single point of failure. • Half-duplex only.• More flexible than 10BASE5 cable
Thin Net
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7.1.3 10BASE2
Thin Net
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7.1.4 10BASE-T
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Signal leaves the NIC and enters the cable on the Orange pair. White-Orange is +ve, solid Orange is
negative.
Signal leaves the cable and enters the NIC on the SPLIT Green pair. White-Green is +ve, solid Green is
negative.
568B
7.1.4 10BASE-T
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7.1.4 10BASE-T
• UTP is cheaper and easier to install• Category 3 and 5 cable are adequate for 10BASE-T networks.• New cable installations use Category 5e or better for multiple protocols.• 10 Mbps of traffic in half-duplex mode and 20 Mbps in full-duplex mode.
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7.1.5 10BASE-T wiring and architecture
The 5-4-3 rule still applies.
• 10BASE-T links can have unrepeated distances up to 100 m. • Hubs can solve the distance issue but will allow collisions to
propagate. • The 100 m distance starts over at a Switch.
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Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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All versions of Ethernet have the same:1. MAC addressing2. CSMA/CD3. Frame format
However, other aspects of the MAC sublayer, physical layer, and medium have changed.
802.2
Fast Ethernet
7.1 10-Mbps and 100-Mbps Ethernet
10 0
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7.1.6 100-Mbps Ethernet
The only difference between Ethernet and Fast Ethernet is the Bit
Time
The two technologies that have become important are 100BASE-TX, which is a copper UTP medium and 100BASE-FX, which is a multimode optical fiber medium.
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7.1.6 100-Mbps Ethernet
The 100-Mbps frame format is the same as the 10-Mbps frame.
• These higher frequency signals are more susceptible to noise. • In response to these issues, two separate encoding steps are used by
100-Mbps Ethernet. 1. The first part of the encoding uses a technique called 4B/5B2. The second part of the encoding is the actual line encoding
specific to copper or fiber.
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7.1.7 100BASE-TX/FX
1. The data byte to be sent is first broken into two nibbles. 2. If the byte is 0E, the first nibble is 0 and the second nibble is E. 3. Next each nibble is remapped according to the 4B5B table.
• Hex 0 is remapped to the 4B5B code 11110. • Hex E is remapped to the 4B5B code 11100.
4. In 100BASE-FX and 100BASE-TX, the 4B5B replacement happens at the Physical Coding Sublayer (PCS)
5. Information is then further encoded for transmission using • MLT-3 in 100BASE-TX at the Physical Medium Dependent
(PMD) sublayer• NRZI in 100BASE-FX at the Physical Media Attachment (PMA)
sublayer
4B5B Encoding TableData (Hex) (Binary) 4B5B Code
0 0000 111101 0001 010012 0010 10100... ... ...D 1101 11011E 1110 11100F 1111 11101
There will always be at least one ‘1’ in
each byte, eliminating long strings of zeros.
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7.1.7 100BASE-TX multi-level transmit-3 levels
100BASE-TX (like 100BASE-FX) uses 4B/5B encoding which is then scrambled and converted to multi-level transmit-3 levels or MLT-3.
Any Transition = binary 1.
No transition = binary 0.
Long strings of zeros would give a ‘DC’
component but because of the 4B/5B encoding this can never happen.
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7.1.7 100BASE-TX
• 100BASE-TX can be either full-duplex or half-duplex • An Ethernet network using separate transmit and receive wire pairs (full-duplex) and a
switched topology prevents collisions on the physical bus.
MLT3 coding
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7.1.7 100BASE-TX
RJ45 Pinouts are the same as 10BASE-T
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7.1.8 100BASE-FX
100BASE-FX (like 100BASE-TX) uses 4B/5B encoding which is then scrambled and converted to Non Return to Zero, Inverted.
Non Return to Zero, Inverted
Any Transition = binary 1.
No transition = binary 0.
Long strings of zeros would give a ‘DC’
component but because of the 4B/5B encoding this can never happen.
Fiber cannot use the 3 level MLT3 because the light source has only two levels, ON and OFF.
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7.1.8 100BASE-FX
200 Mbps transmission is possible because of the separate Transmit and Receive paths in 100BASE-FX optical fiber.
• The main application for which 100BASE-FX was designed was inter-building backbone connectivity
• 100BASE-FX was never adopted successfully. This was due to the timely introduction of Gigabit Ethernet copper and fiber standards.
• Gigabit Ethernet standards are now the dominant technology for backbone installations, high-speed cross-connects, and general infrastructure needs.
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7.1.8 100BASE-FX
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7.1.8 100BASE-FX
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7.1.8 100BASE-FX
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7.1.8 100BASE-FX
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7.1.8 100BASE-FX
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7.1.9 Fast Ethernet architecture
1. The introduction of switches has made this distance limitation less important.2. If workstations are located within 100 m of a switch, the 100 m distance starts
over at the switch. 3. Since most Fast Ethernet is switched, these are the practical limits between
devices.
A Class I repeater may introduce up to 140 bit-times of latency. Any repeater that changes between one Ethernet implementation and another is a Class I
repeater.
A Class II repeater may only introduce a maximum of 92 bit-times
latency.
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7.1.9 Fast Ethernet architecture
1. Only one Class I repeater can be used in a single collision domain.
2. Two Class II repeaters are allowed in a single collision domain, with up to a 5 meter inter-repeater link between them.
3. Class II repeaters are faster than Class I repeaters. 4. This allows Class I repeaters to provide other
services besides simple repeating, such as translating between 100BASE-TX and 100BASE-T4.
5. Class II repeaters are primarily used to link two hubs each supporting only a single implementation of Fast Ethernet.
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Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 40
All versions of Ethernet have the same:1. MAC addressing2. CSMA/CD3. Frame format
However, other aspects of the MAC sublayer, physical layer, and medium have changed.
10 0
802.2
Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 41
Fast Ethernet
7.2.1 1000-Mbps Ethernet
Gigabit Ethernet
1000BASE-T inter-switch links are useful for• video streaming applications • server to DAT backup drive links • intra-building backbones
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 42
Once again the frame remains unchanged.
The differences between standard Ethernet, Fast Ethernet and Gigabit Ethernet occur at the physical layer.
• Since the bits are introduced on the medium for a shorter duration and more often, timing is critical.
• This high-speed transmission requires frequencies closer to copper medium bandwidth limitations.
• This causes the bits to be more susceptible to noise on copper media. • Like 100Base-TX these issues require Gigabit Ethernet to use two
separate encoding steps. • Data transmission is made more efficient by using codes to represent
the binary bit stream. • The encoded data provides synchronization, efficient usage of
bandwidth, and improved Signal-to-Noise Ratio characteristics.
To interconnect a 1000BASE-T network to a 100BASE-T network use a layer 2 bridge or switch.
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1st Frame
2nd Frame
3rd Frame
4th Frame
• Cat 5e cable can reliably carry up to 125 Mbps of traffic.
• 1000BASE-T uses all four pairs of wires.
• This is done using complex circuitry called a Hybrid to allow full duplex transmissions on the same wire pair.
• This provides 250 Mbps per pair. • With all four-wire pairs, this provides
the desired 1000 Mbps. • Since the information travels
simultaneously across the four paths, the circuitry has to divide frames at the transmitter and reassemble them at the receiver.
Because Gigabit Ethernet is inherently full-duplex, the Media Access Control method views it as a point-to-point
link.
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• With the complex integrated circuits using techniques such as echo cancellation, Layer 1 Forward Error Correction (FEC), and prudent selection of voltage levels, the system achieves the 1 Gigabit throughput.
• In idle periods there are nine voltage levels found on the cable, and during data transmission periods there are 17 voltage levels found on the cable.
• With this large number of states and the effects of noise, the signal on the wire looks more analog than digital.
• Like analog, the system is more susceptible to noise due to cable and termination problems.
• The use of full-duplex 1000BASE-T is widespread.
• For 1000BASE-T 4D-PAM5 line encoding is used on Cat 5e or better UTP.
• The actual transmitted signal in each direction on each wire pair is a 5-level {+2, +1, 0, -1, -2} pulse modulated symbol (PAM5).
• This results in a permanent collision on the wire pairs.
• These collisions result in complex voltage patterns.
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 45
Why is the half-duplex operation undesirable for Gigabit Ethernet? (Choose three.)1. Gigabit Ethernet is inherently full-duplex. 2. Half-duplex operation reduces the effective cable lengths. 3. Half-duplex operation introduces increased overhead by the carrier extension.
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• Fiber cannot do multi level signaling (not 4D-PAM5 nor MLT3)• at 1 Gigabit Non Return to Zero (NRZ) signaling is used with• 8B/10B coding to ensure that a good synchronizing signal is
always present.
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Code GroupName
Actual Byte BeingEncoded
RD-Encoding Value
RD+Encoding Value
Effect onRD afterSending
D1.0 000 00001 011101 0100 100010 1011 same
D4.1 001 00100 110101 1001 001010 1001 flip
D28.5 101 11100 001110 1010 001110 1010 same
D28.5 101 11100 001111 1010 110000 0101 flip
Examples of 8B/10B coding
Features And Operation Of 8B/10B Encoding
Every ten bit code group must fit into one of the following three possibilities:
1. Six ones and four zeros2. Five ones and five zeros 3. Four ones and six zeros
This helps limit the number of consecutive ones and zeros between any two code groups.
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Any Transition = binary 1 No transition = binary 0
Light = binary 1 No Light = binary 0
1 0 1 0 0 1 0 1 1 1
1000BASE-S or L X8B/10B
NRZI
NRZ
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Different sub layers in the Physical Layer
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L=Long Wave Length
1300nm
S=Short Wave Length 850
nm
• The Media Access Control method treats the link as point-to-point.
• Since separate fibers are used for transmitting (Tx) and receiving (Rx) the connection is inherently full duplex.
• Gigabit Ethernet permits only a single repeater between two stations.
multimode
error
5000
550
550
550
275
100
25
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 52
The bandwidth of fiber is inherently very large. It has been limited by
• emitter technology • fiber manufacturing processes • detector technology
Single mode
error
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Table 1 100BASE-TX, 1000BASE-X, and 1000BASE-T
100BASE-TX 1000BASE-X 1000BASE-T
Frame format 802.3 Ethernet 802.3 Ethernet 802.3 Ethernet
MAC protocol 802.3 Ethernet 802.3 Ethernet 802.3 Ethernet
Flow control 802.3x 802.3x 802.3x
Symbol rate 125 Mbaud 125 Mbaud 1.25 Gbaud
Data rate 100 Mbps 1000 Mbps 1000 Mbps
Encoding (PCS) ANSI FDDI 4B/5B ANSI FC 8B/10B 5 level PAM
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Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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Oct-03 ©Cisco Systems CCNA Semester 1 Version 3 Comp11 Mod7 – St. Lawrence College – Cornwall Campus, ON, Canada – Clark slide 55
All versions of Ethernet have the same:1. MAC addressing2. CSMA/CD3. Frame format
However, other aspects of the MAC sublayer, physical layer, and medium have changed.
10 0
802.2
10 Gigabit Ethernet
7.2.5 10-Gigabit Ethernet
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Fast Ethernet
Gigabit Ethernet
All versions of Gigabit Ethernet have the same frame format, timing and transmission
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How does 10GbE compare to other varieties of Ethernet?
1. Frame format is the same, allowing interoperability between all varieties of legacy, fast, gigabit, and 10 Gigabit, with no reframing or protocol conversions.
2. Bit time is now 0.1 nanoseconds. All other time variables scale accordingly.
3. Since only full-duplex fiber connections are used, CSMA/CD is not necessary
4. The IEEE 802.3 sublayers within OSI Layers 1 and 2 are mostly preserved, with a few additions to accommodate 40 km fiber links and interoperability with SONET/SDH technologies.
5. Flexible, efficient, reliable, relatively low cost end-to-end Ethernet networks become possible.
6. TCP/IP can run over LANs, MANs, and WANs with one Layer 2 Transport method.
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802.3ae June 2002 10GbE family.
1. 10GBASE-SR – Intended for short distances over already-installed multimode fiber, supports a range between 26 m to 82 m
2. 10GBASE-LX4 – Uses wavelength division multiplexing (WDM), supports 240 m to 300 m over already-installed multimode fiber and 10 km over single-mode fiber
3. 10GBASE-LR and 10GBASE-ER – Support 10 km and 40 km over single-mode fiber
4. 10GBASE-SW, 10GBASE-LW, and 10GBASE-EW – Known collectively as 10GBASE-W are intended to work with OC-192 synchronous transport module (STM) SONET/SDH WAN equipment.
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Physical Media
Dependent
Each transceiver has four 3.125-Gbit/s DFB lasers that are optically multiplexed to provide a 10-Gbit/s data throughput.
10GBASE-LX4 uses Wide Wavelength Division Multiplex (WWDM) to multiplex four bit simultaneous bit streams as four wavelengths of light launched into the fiber at one time.
Physical Media
Attachment
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http://standards.ieee.org/getieee802/802.3.html
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Coarse Wavelength Division Multiplexing
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Overview 7.1 10-Mbps and 100-Mbps Ethernet
7.1.1 10-Mbps Ethernet
7.1.2 10BASE5
7.1.3 10BASE2
7.1.4 10BASE-T
7.1.5 10BASE-T wiring and architecture
7.1.6 100-Mbps Ethernet
7.1.7 100BASE-TX
7.1.8 100BASE-FX
7.1.9 Fast Ethernet architecture
7.2 Gigabit and 10-Gigabit Ethernet
7.2.1 1000-Mbps Ethernet
7.2.2 1000BASE-T
7.2.3 1000BASE-SX and LX
7.2.4 Gigabit Ethernet architecture
7.2.5 10-Gigabit Ethernet
7.2.6 10-Gigabit Ethernet architectures
7.2.7 Future of Ethernet
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7.2.7 Future of Ethernet
1. Copper (up to 1000 Mbps, perhaps more) 2. Wireless (approaching 100 Mbps, perhaps more) 3. Optical fiber (currently at 10,000 Mbps and soon to be more)
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FIN