- Table of Contents
-
- H3C S12500R-2L Switch Router Installation Guide-6W102
- 00-Preface
- 01-Chapter 1 Preparing for Installation
- 02-Chapter 2 Installing the Device
- 03-Chapter 3 Installing Removalbe Components
- 04-Chapter 4 Connecting Your Device to the Network
- 05-Chapter 5 Troubleshooting
- 06-Chapter 6 Replacement Procedures
- 07-Appendix A Chassis Views and Technical Specifications
- 08-Appendix B Removable Components and Compatibility Matrixes
- 09-Appendix C LEDs
- 10-Appendix D Cables
- Related Documents
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Title | Size | Download |
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10-Appendix D Cables | 203.18 KB |
1 Appendix D Cables
This chapter describes cables used for connecting the ports on the device.
Table1-1 Cable description
Cable |
Port type |
Application |
RJ-45 Ethernet port at one end and DB-9 port at the other end |
Connects the console port of the device to the console terminal |
|
RJ-45 Ethernet ports |
Connects RJ-45 Ethernet ports to transmit data |
|
QSFP+/QSFP28 ports |
Connects the fiber ports to transmit data |
|
QSFP+ ports |
Connects QSFP+ ports to transmit data |
|
QSFP28 ports |
Connects QSFP28 ports to transmit data |
Console cable
A console cable is an 8-core shielded cable, with a crimped RJ-45 connector at one end for connecting to the console port of the device, and a DB-9 female connector at the other end for connecting to the serial port on the console terminal.
Figure1-1 Console cable
RJ-45 |
Signal |
DB-9 |
Signal |
1 |
RTS |
8 |
CTS |
2 |
DTR |
6 |
DSR |
3 |
TXD |
2 |
RXD |
4 |
SG |
5 |
SG |
5 |
SG |
5 |
SG |
6 |
RXD |
3 |
TXD |
7 |
DSR |
4 |
DTR |
8 |
CTS |
7 |
RTS |
Ethernet twisted pair cable
An Ethernet twisted pair cable consists of four pairs of insulated wires twisted together. It mainly transmits analog signals and is advantageous in transmitting data over shorter distances. The maximum transmission distance is 100 m (328.08 ft).
RJ-45 connector
An Ethernet twisted pair cable connects network devices through the RJ-45 connectors at the two ends. Figure1-2 shows the pinouts of an RJ-45 connector.
Figure1-2 RJ-45 connector pinout diagram
Cable pinouts
EIA/TIA cabling specifications define two standards: 568A and 568B for cable pinouts.
· Standard 568A—pin 1: white/green stripe, pin 2: green solid, pin 3: white/orange stripe, pin 4: blue solid, pin 5: white/blue stripe, pin 6: orange solid, pin 7: white/brown stripe, pin 8: brown solid.
· Standard 568B—pin 1: white/orange stripe, pin 2: orange solid, pin 3: white/green stripe, pin 4: blue solid, pin 5: white/blue stripe, pin 6: green solid, pin 7: white/brown stripe, pin 8: brown solid.
Cable type
Based on performance
Table1-2 Ethernet cable description
Type |
Description |
Category 5 |
Transmits data at a maximum speed of 100 Mbps, with a bandwidth of 100 MHz. |
Category 5e |
Transmits data at a maximum speed of 1000 Mbps, with a bandwidth of 100 MHz. |
Category 6 |
Transmits data at a speed higher than 1 Gbps, with a bandwidth of 250 MHz. |
Category 6A |
Transmits data at a speed higher than 10 Gbps, with a bandwidth of 500 MHz. |
Category 7 |
Transmits data at a speed higher than 10 Gbps, with a bandwidth of 600 MHz. |
|
NOTE: Connect 10-Gigabit RJ-45 ports on the device by using category 6A or category 7 twisted pair cables. Connect other RJ-45 ports on the device by using category 5 or above twisted pair cables. |
Based on pinouts
Ethernet twisted pair cables can be classified into straight through and crossover cables based on their pinouts.
· Straight-through—The pinouts at both ends comply with standard 568B, as shown in Figure1-3.
· Crossover—The pinouts at one end comply with standard 568B, and those at the other end comply with standard 568A, as shown in Figure1-4.
Figure1-3 Straight-through cable
Pin assignments
Select an Ethernet twisted pair cable according to the RJ-45 Ethernet interface type on your device. An RJ-45 Ethernet interface can be MDI (for routers and PCs) or MDIX (for devices). For the pinouts of RJ-45 Ethernet interfaces, see Table1-3 and Table1-4.
Table1-3 RJ-45 MDI interface pinouts
10BASE-T/100BASE-TX |
1000BASE-T |
|||
Signal |
Function |
Signal |
Function |
|
1 |
Tx+ |
Send data |
BIDA+ |
Bi-directional data cable A+ |
2 |
Tx- |
Send data |
BIDA- |
Bi-directional data cable A- |
3 |
Rx+ |
Receive data |
BIDB+ |
Bi-directional data cable B+ |
4 |
Reserved |
N/A |
BIDC+ |
Bi-directional data cable C+ |
5 |
Reserved |
N/A |
BIDC- |
Bi-directional data cable C- |
6 |
Rx- |
Receive data |
BIDB- |
Bi-directional data cable B- |
7 |
Reserved |
N/A |
BIDD+ |
Bi-directional data cable D+ |
8 |
Reserved |
N/A |
BIDD- |
Bi-directional data cable D- |
Table1-4 RJ-45 MDI-X interface pinouts
Pin |
10BASE-T/100BASE-TX |
1000BASE-T |
||
Signal |
Function |
Signal |
Function |
|
1 |
Rx+ |
Receive data |
BIDB+ |
Bi-directional data cable B+ |
2 |
Rx- |
Receive data |
BIDB- |
Bi-directional data cable B- |
3 |
Tx+ |
Send data |
BIDA+ |
Bi-directional data cable A+ |
4 |
Reserved |
N/A |
BIDD+ |
Bi-directional data cable D+ |
5 |
Reserved |
N/A |
BIDD- |
Bi-directional data cable D- |
6 |
Tx- |
Send data |
BIDA- |
Bi-directional data cable A- |
7 |
Reserved |
N/A |
BIDC+ |
Bi-directional data cable C+ |
8 |
Reserved |
N/A |
BIDC- |
Bi-directional data cable C- |
To ensure normal communication, the pins for sending data on one port should correspond to the pins for receiving data on the peer port. To connect two ports of the same connection type (MDI to MDI or MDIX to MDIX), use a crossover Ethernet cable. A cross-over cable connects devices of the same type. To connect two ports of different connection types (MDI to MDIX), use a straight-through Ethernet cable. A straight-through cable connects devices of different types.
An RJ-45 Ethernet interface with MDI/MDIX autosensing enabled can automatically negotiate pin roles. The S12500R-2L RJ-45 Ethernet interfaces support MDI/MDIX. By default, MDI/MDIX is enabled on a port.
Making an Ethernet twisted pair cable
1. Cut the cable to length with the crimping pliers.
2. Strip off an appropriate length of the cable sheath. The length is typically that of the RJ-45 connector.
3. Untwist the pairs so that they can lie flat, and arrange the colored wires based on the wiring specifications.
4. Cut the top of the wires even with one another. Insert the wires into the RJ-45 end and make sure the wires extend to the front of the RJ-45 end and make good contact with the metal contacts in the RJ-45 end and in the correct order.
5. Crimp the RJ-45 connector with the crimping pliers until you hear a click.
6. Repeat the above steps with the other end of the cable.
7. Use a cable tester to verify the connectivity of the cable.
Optical fiber
CAUTION: Use the same types of transceiver modules, pigtail cords, patch cords, and fiber cables. If you use single-mode optical fibers, the transceiver modules, pigtail cords, patch cords, and fiber cables must be single-mode. |
Optical fiber
Optical fibers are widely used in fiber-optic communications, which are advantageous for long-distance communications.
Optical fibers can be classified into the following types:
· Single mode fiber—It has a core size of 10 µm or smaller, and has a lower modal dispersion. It carries only a single ray of light. It is mostly used for communication over longer distances.
· Multi-mode fiber—It has a core size of 50 µm or 62.5 µm or higher, and has a higher modal dispersion than single-mode optical fiber. It is mostly used for communication over shorter distances.
Table1-5 Allowed maximum tensile force and crush load
Period of force |
Tensile load (N) |
Crush load (N/mm) |
Short period |
150 |
500 |
Long term |
80 |
100 |
Optical fiber cable
An optical fiber cable is a cable containing one or more optical fibers. The optical fiber elements are typically individually coated with plastic layers and contained in a protective tube. Optical fiber cables fall into single-mode and multi-mode.
Patch cord
A fiber that has connectors at both ends is called a patch cord. A patch cord connects one optical device to another for signal routing. Patch cords fall into single-mode and multi-mode patch cords.
· Single-mode patch cord—The jacket is yellow. It permits transmission over longer distances.
· Multi-mode patch cord—The jacket is orange. It permits transmission over shorter distances.
Patch cords are classified into SC, LC, FC, and so on based on interface type. The length of a patch cord can be 0.5 m (1.64 ft), 1 m (3.28 ft), 2 m (6.56 ft), 3 m (9.84 ft), 5 m (16.40 ft), 10 m (32.81 ft), and so on.
Pigtail cord
A pigtail cord is an optical fiber that has an optical connector on one end and a length of exposed fiber on the other. The end of the pigtail is fusion spliced to a fiber, connecting the fiber cable and transceiver.
Pigtail cords fall into single-mode (yellow) and multi-mode (orange), and can also be classified into SC, LC, FC, and so on based on interface type.
Fiber connector
Figure1-5 MPO connector
Precautions
· Make sure the fiber connector and fiber type match the transceiver module type.
· The fiber ports on the device are provided with dust plugs. Insert the dust plugs into the fiber ports that you are not to use, to prevent particles from entering the ports.
· Fiber connectors must be protected under safe and reliable outer packing, and be fitted with dust caps. Fiber connectors must be installed with dust caps when they are not in use. Take care not to scratch their end face. Replace the dust cap if it is loose or polluted.
· Before connecting a fiber, use dust free paper and absolute alcohol to clean the end face of the fiber connector. You can brush the end face only in one direction. You also need to brush the end face of the fiber port.
· If the fiber has to pass through a metallic board hole, the hole must have a sleek and fully filleted surface (the filleting radius must be not less than 2 mm). When passing through a metallic board hole or bending along the acute side of mechanical parts, the fiber must wear jackets or cushions.
· Insert and remove a plug with care. Never exert a fierce force to the fiber or plug; otherwise the plug might be damaged or the fiber might be broken. Never pull, press or extrude the fiber fiercely. For the allowed maximum tensile load and crush load, see Table1-5.
QSFP+ copper cable
You can use QSFP+ copper cables to connect QSFP+ ports.
Figure1-7 QSFP+ copper cable
(1) Connector |
(2) Pull latch |
QSFP28 copper cable
You can use QSFP28 copper cables to connect QSFP28 ports.
Figure1-8 QSFP28 copper cable
(1) Connector |
(2) Pull latch |