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01-Text | 1.47 MB |
Contents
Checking power distribution or power supply environment
Mounting the switch on a DIN rail
Mounting the switch on a DIN rail
Connecting the grounding cable
Connecting the grounding cable
Verifying the connection after grounding the switch
Connecting cables to the alarm input and alarm output connections and RS485 port
Connecting a serial console cable
Connecting a DB9-to-RJ45 console cable
Connecting a USB-to-RJ45 console cable
1 Product overview
H3C IE4500-G DIN-rail mount switch series includes the following models:
· IE4500-14S-G—Provides eight 10/100/1000BASE-T copper ports, six 100M/1G/10GBASE-X SFP+ ports, and one 1-channel RS485 port.
· IE4500-14S-UPWR-G—Provides eight 10/100/1000BASE-T PoE++ copper ports, six 100M/1G/10GBASE-X SFP+ ports, and one 1-channel RS485 port.
2 Chassis views
IE4500-14S-G
Figure2-1 Front panel
(1) Diag LED (Diag) |
(2) Power supply 1 status LED |
(3) Power supply 2 status LED |
(4) Alarm LED (Alarm) |
(5) 10/100/1000BASE-T copper port |
(6) 10/100/1000BASE-T copper port LEDs |
(7) SFP+ port LED |
(8) SFP+ port |
(9) RS485 port |
(10) Alarm output connection (DO) |
(11) Alarm input connection (DI) |
Figure2-2 Top panel
(1) Grounding screw |
(2) Power supply 1 |
(3) Power supply 2 |
(4) Reset button (RESET) |
(5) USB port |
(6) Console port |
(7) Management Ethernet port |
|
NOTE: To reboot the switch, press and hold the reset button for more than 5 seconds. |
IE4500-14S-UPWR-G
Figure2-3 Front panel
(1) Diag LED (Diag) |
(2) Power supply 1 status LED |
(3) Power supply 1 status LED |
(4) Alarm LED (Alarm) |
(5) 10/100/1000BASE-T PoE++ copper port |
(6) 10/100/1000BASE-T PoE++ copper port LEDs |
(7) SFP+ port LED |
(8) SFP+ port |
(9) RS485 port |
(10) Alarm output connection (DO) |
(11) Alarm input connection (DI) |
(1) Grounding screw |
(2) Power receptacle 1 |
(3) Power receptacle 2 |
(4) Reset button (RESET) |
(5) USB port |
(6) Console port |
(7) Management Ethernet port |
|
NOTE: To reboot the switch, press and hold the reset button for more than 5 seconds. |
3 Chassis dimensions
The IE4500-G DIN-rail mount switches have the same dimensions. The following uses the IE4500-14S-G switch as an example. Select an appropriate installation position for the switch based on its dimensions.
Figure3-1 Chassis dimensions
4 Installing the switch
WARNING! When you operate the switch, always wear an ESD wrist strap or ESD gloves and make sure they make good skin contact and are reliably grounded. Do not touch the components on the switch. |
Safety recommendations
To avoid bodily injury or damage to the switch, read the following safety recommendations carefully before working with the switch. Note that the recommendations do not cover every possible hazardous condition.
· Before cleaning the switch, remove all power cords and alarm input and output wires from the switch. Do not clean the switch with wet cloth or liquid.
· Do not place the switch near water or in a damp environment. Prevent water or moisture from entering the switch chassis.
· Do not place the switch on an unstable case or desk.
· Ensure adequate ventilation for the switch and keep the protective vents of the switch unblocked.
· Make sure the power source voltage meets the requirements of the switch.
· To avoid electrical shocks, do not open the chassis while the switch is operating. As a best practice, do not open the chassis even if the switch is powered off.
· When installing the switch, always wear an ESD wrist strap. Make sure the wrist strap makes good skin contact and is reliably grounded.
· Do not hot swap the terminal blocks.
Checking power distribution or power supply environment
Table4-1 Requirements for power distribution or power supply environment
Item |
Requirements |
Preparation |
The power supply must be available before you install the switch. |
Voltage |
The voltage provided to the switch must be within the operating voltage range. |
Power receptacle and cables |
The switch came with a terminal block connected to each power receptacle. No power cord is provided with the switch. Prepare compatible copper power wires yourself as required. Make sure the copper power wires meet the following requirements: · Minimum conductor cross-sectional area: 0.5 mm2 or 20 AWG. · Maximum conductor cross-sectional area: 3 mm2 or 12 AWG. |
Mounting the switch on a DIN rail
As a best practice, place the switch in an environment with the mechanical class not above 4M4. Use a cabinet with an IP rating of IPX1 or higher for installing the switch.
DIN bracket and DIN rail
The switch came with a DIN bracket installed on it.
(1) Metal spring |
(2) Screw hole |
Table4-2 shows the dimensions of the DIN rails applicable to the DIN bracket. Prepare the DIN rails as required.
Table4-2 Applicable DIN rail dimensions
Switch model |
DIN rail dimensions (H × W × D) |
· IE4500-14S-G · IE4500-14S-UPWR-G |
48.2 × 47 × 9.2 mm (1.90 × 1.85 × 0.36 in) |
Mounting the switch on a DIN rail
1. Wear an ESD wrist strap and make sure it makes good skin contact and is reliably grounded.
2. As shown by callout 1 in Figure4-3, position the switch so that the spring of the DIN bracket compresses against the upper edge of the DIN rail.
3. As shown by callout 2 in Figure4-3, rotate the switch down toward the DIN rail until the DIN bracket clicks.
Figure4-3 Mounting the switch on a DIN rail (IE4500-14S-G)
Connecting the grounding cable
Connecting the grounding cable
WARNING! · Correctly connecting the grounding cable for the switch is crucial to lightning protection, ESD, and EMI protection. · Connect the grounding cable to the grounding strip in the equipment room. Do not connect it to a fire main or lightning rod. |
|
NOTE: The power and grounding terminals in this section are for illustration only. |
To protect against the following types of problems, use a grounding cable to connect the switch to the earthing facility at the installation site:
· Bodily injury from electric shocks.
· Device and power and data line damages.
· Electrical fires, lightning strokes, electromagnetic coupling interference, and ESD damages.
Select a grounding method based on the installation environment.
1. Remove the grounding screw from the grounding hole in the chassis.
2. Attach the grounding screw to the ring terminal of the provided grounding cable.
3. Use a screwdriver to fasten the grounding screw into the grounding screw hole.
4. Connect the other end of the grounding cable to the grounding point or grounding strip.
Figure4-4 Connecting the grounding cable to the chassis (IE4500-14S-G)
(1) Grounding screw |
(2) Ring terminal |
(3) Grounding hole |
(4) Grounding sign |
(5) Grounding cable |
Verifying the connection after grounding the switch
Verify the connection after grounding the switch as follows:
· If you ground the switch by using a grounding strip, perform the following tasks:
a. Use a multimeter to measure the resistance between the switch grounding terminal and grounding point, and make sure the resistance is less than 0.1W
b. Use a grounding resistance tester to measure the grounding resistance of the grounding strip, and make sure the grounding resistance is less than 1W.
· If you ground the switch with a grounding conductor buried in the earth ground, perform the following tasks:
a. Use a multimeter to measure the resistance between the switch grounding terminal and grounding point, and make sure the resistance is less than 0.1W.
b. Use a grounding resistance tester to measure the grounding resistance of the angle iron in the ground, and make sure the grounding resistance is less than 10W. For locations with high soil resistivity, sprinkle some resistance reducer to reduce soil resistivity or replace soil around the grounding strip with soil with lower resistance.
For information about resistance measurement, see H3C Network Devices Lightning Protection Guide.
Connecting power cords
CAUTION: · Make sure each power cord has a separate circuit breaker. · Turn off the circuit breaker before connecting the power cord. |
The switch came with a terminal block connected to each power receptacle. No power cord is provided with the switch. Prepare compatible copper power wires yourself as required. Table4-3 shows the specifications of power cords.
Table4-3 Power cord specifications
Switch model |
Minimum conductor cross-sectional area |
Maximum conductor cross-sectional area |
· IE4500-14S-G · IE4500-14S-UPWR-G |
0.5 mm2 or 20 AWG |
3 mm2 or 12 AWG |
Both the IE4500-14S-G and IE4500-14S-UPWR-G switches support DC power cord connection. The following uses the IE4500-14S-G switch as an example.
To connect a DC power cord:
1. Use a wire stripper to strip the heat-shrink tubes off the two-wire power cord on one end, and then strip the electrical insulation off to make sure about 7 mm (0.28 in) of the wire reaches out. Repeat this step for the other end.
2. Orient the terminal block with upside up and identify the positive (+) and negative (-) connections on the terminal block.
If you orient the terminal block upside down, you cannot insert it into the power receptacle.
3. As shown by callout 1 in Figure4-5, insert the wires into the terminal block, with the positive wire (red) to the positive connection and negative wire (blue) to the negative connection.
4. As shown by callout 2 in Figure4-5, use a flat-head screwdriver to fasten the screws at the top of the terminal block to secure the wires to the terminal block.
5. As shown by callout 3 in Figure4-5, connect the terminal block to a DC power receptacle. Use a flat-head screwdriver to fasten the screws on the terminal block to secure the terminal block to the DC power receptacle.
6. Connect the other ends of the wires to a DC power source.
Figure4-5 Connecting a DC power cord for the switch (IE4500-14S-G)
Connecting cables to the alarm input and alarm output connections and RS485 port
CAUTION: Before you connect cables to the alarm input and alarm output connections and RS485 port, make sure the switch is reliably grounded and is powered off. |
Use alarm input and alarm output wires to connect the alarm input connection (DI) and alarm output connection (DO), respectively. The RS485 port is used for industrial control and communication.
No interface cables are provided with the switch. Prepare compatible copper wires yourself as required.
Table4-4 Alarm input and alarm output wire specifications
Switch model |
Minimum conductor cross-sectional area |
Maximum conductor cross-sectional area |
· IE4500-14S-G · IE4500-14S-UPWR-G |
0.08 mm2 or 28 AWG |
0.5 mm2 or 20 AWG |
The switch came with a terminal block connected to the alarm input and alarm output connections and RS485 port.
The switch provides an alarm input connection, an alarm output connection, and an RS485 port on the front panel. The following uses the IE4500-14S-G switch as an example.
To connect cables to the alarm input and alarm output connections and RS485 port:
1. Remove the terminal block. Choose copper wires based on the installation site requirements.
2. Use a wire stripper to strip the heat-shrink tubes off the wires on one end, and then strip the electrical insulation off the wires to make sure about 7 mm (0.28 in) of the wire reaches out. Repeat this step for the other end.
Identify the following marks for correct connections:
¡ +/-: Positive/negative connection.
¡ O: Normally open contact.
¡ C: Normally closed contact.
¡ M: Common terminal.
¡ SG: Grounding cable.
¡ D-: Negative differential signal.
¡ D+: Positive differential signal.
3. As shown by callout 1 in Figure4-6, use a flat-head screwdriver to press down the white button on the terminal block.
4. As shown by callout 2 in Figure4-6, insert the wire ends into the terminal block.
5. As shown by callout 3 in Figure4-6, connect the terminal block to the switch.
6. Connect the other ends of the wires to external devices.
Verifying the installation
After you complete the installation, verify the following information:
· There is enough space around the switch for heat dissipation.
· The rack or workbench is stable.
· The grounding cable is connected correctly.
· The power source is as required by the switch.
· The power cord is correctly connected.
· If part of the network cable for a port is routed outdoors, verify that a network port lightning protector is used for the port.
· If a power line is routed from outdoors, verify that a surge protected power strip is used for the switch.
Connecting a serial console cable
In Figure4-7, the switch is connected to a configuration terminal (PC as an example) from the console port through a console cable (optional).
Figure4-7 Connecting the switch to a configuration terminal (IE4500-14S-G)
The switch is not provided with a serial console cable. The signal pinout for the RJ-45 connector of a serial console cable varies by vendor. To avoid abnormal configuration terminal display, use the recommended H3C DB9-to-RJ45 console cable (part number: 04042967) or H3C USB-to-RJ45 console cable (part number: 0404A1EE). To prepare a serial console cable yourself, make sure the signal pinout for the RJ-45 connector is the same as that shown in Table4-6.
Table4-5 Connection methods and console cables
Connection method |
Console cable type |
Configuration terminal-side connector |
Switch-side connector |
Using the serial console port for connection |
DB9-to-RJ45 console cable |
DB-9 female connector |
RJ-45 |
USB-to-RJ45 console cable |
USB port |
RJ-45 |
Connecting a DB9-to-RJ45 console cable
CAUTION: Follow these guidelines when you connect a DB9-to-RJ45 console cable: · Identify the mark on the serial console port and make sure you are connecting to the correct port. · The serial ports on PCs do not support hot swapping. To connect a PC to an operating switch, first connect the PC end. To disconnect a PC from an operating switch, first disconnect the switch end. |
A DB9-to-RJ45 serial console cable is an 8-core shielded cable, with a crimped RJ-45 connector at one end for connecting to the serial console port of the switch, and a DB-9 female connector at the other end for connecting to the serial port on a configuration terminal.
Figure4-8 DB9-to-RJ45 console cable
Table4-6 DB9-to-RJ45 console cable signal pinout
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 |
To connect the switch to a configuration terminal (for example, a PC) by using a DB9-to-RJ45 console cable:
1. Plug the DB-9 female connector of the DB9-to-RJ45 console cable to the serial port on the PC.
2. Connect the RJ-45 connector to the serial console port on the switch.
Connecting a USB-to-RJ45 console cable
IMPORTANT: · To use a USB-to-RJ45 console cable to connect the switch to a configuration terminal, first download and install the USB-to-RJ45 console driver on the configuration terminal and then connect the USB-to-RJ45 console cable to the configuration terminal. · If you have connected a USB-to-RJ45 console cable to the configuration terminal before driver installation, you must reconnect the USB-to-RJ45 console cable to the configuration terminal. |
Figure4-9 USB-to-RJ45 console cable
For information about the signal pinout for the RJ-45 connector of a USB-to-RJ45 console cable, see Table4-6.
The following describes driver installation on the Windows system. To install the driver on other operating systems, see the installation guide in the folder (named according to the operating system type) in the driver compression package.
To connect the switch to a configuration terminal by using a USB-to-RJ45 console cable:
1. Click the following link, or copy it to the address bar on your browser and download the USB-to-RJ45 console driver.
http://www.h3c.com/en/home/USB_to_RJ45_Console/
2. View the Read me.txt file in the Windows folder to identify whether the Windows system of the configuration terminal supports the driver.
3. If the Windows system supports the driver, install PL23XX-M_LogoDriver_Setup_v200_20190815.exe.
4. Click Next on the welcome page of the driver installation wizard.
Figure4-10 Driver installation wizard
5. Click Finish after the driver installation is completed.
Figure4-11 Finishing the driver installation
6. Connect the standard USB connector of the cable to the USB port of the configuration terminal.
7. Connect the RJ-45 connector of the cable to the console port on the switch.
5 LEDs
Table5-1 LED description
LED |
Mark |
Status |
Description |
PWR1 PWR2 |
On |
A power cord has been connected to the power supply and the power supply is operating correctly. |
|
Off |
No power cord is connected to the power supply or the power supply is operating incorrectly. |
||
Alarm LED |
Alarm |
Steady red |
An exception has been detected on the switch. |
Off |
The switch is operating correctly. |
||
Diag LED |
Diag |
Steady green |
The switch is operating correctly. |
Off |
The switch has failed. |
||
Management port LED |
LINK/ACT |
On |
A link is present on the port. |
Flashing |
The port is receiving or sending data. |
||
Off |
No link is present on the port. |
||
10/100/1000BASE-T port LED |
N/A |
Steady green |
A link is present on the port and the port is operating at 1000 Mbps. |
Flashing green |
The port is receiving or sending data at 1000 Mbps. |
||
Steady yellow |
A link is present on the port and the port is operating at 10/100 Mbps. |
||
Flashing yellow |
The port is receiving or sending data at 10/100 Mbps. |
||
Off |
No link is present on the port. |
||
SFP+ LED |
N/A |
Steady green |
A link is present on the port and the port is operating at 10 Gbps. |
Flashing green |
The port is receiving or sending data at 10 Gbps. |
||
Steady yellow |
A link is present on the port and the port is operating at 100 Mbps or 1 Gbps. |
||
Flashing yellow |
The port is receiving or sending data at 100 Mbps or 1 Gbps. |
||
Off |
No link is present on the port. |
6 Accessing the switch
To configure and manage the switch through the console port, you must run a terminal emulator program, such as TeraTermPro, on your configuration terminal. You can use the emulator program to connect a network device, a Telnet site, or an SSH site. For more information about the terminal emulator programs, see the user guides for these programs.
Turn on the PC. On the PC, launch the terminal emulation program and configure the port properties. Configure the terminal parameters as follows:
· Baud rate—9600.
· Data bits—8.
· Stop bits—1.
· Parity—None.
· Flow control—None.
7 Technical specifications
Table7-1 Technical specifications
Item |
IE4500-14S-G |
IE4500-14S-UPWR-G |
Dimensions (H × W × D) |
155 × 103 × 135 mm (6.10 × 4.06 × 5.32 in) |
|
Weight |
≤ 2.2 kg (4.85 lb) |
|
Console port |
1 |
|
10/100/1000BASE-T copper port |
8 |
8 (Support for PoE++ power supply) |
SFP+ port |
6 |
|
USB port |
1 |
|
RS485 port |
1 |
|
Management Ethernet port |
1 |
|
Alarm input connection |
The system detects exceptions of the connected device based on the input voltage changes on the alarm input connection. · State: ¡ 1: 13 V to 30 V ¡ 0: –30 V to +3 V · Max input current: 8 mA |
|
Alarm output connection |
Uses a relay for output, with a current carrying capacity of 1 A @ 250 VAC or 60 W @ 220 VDC The relay outputs alarms by opening or closing the contact. |
|
Input voltage |
· Rated voltage range: 24 to 48 VDC, 3 A · Max voltage range: 18 to 60 VDC |
· Rated voltage range: 50 to 57 VDC, 4.5 A · Max voltage range: 18 to 60 VDC |
Power consumption (static) |
Single DC input: 17.76 W Dual DC inputs: 19.837 W |
Single DC input: 20.75 W Dual DC inputs: 19.84 W |
Power consumption (typical) |
Single DC input: 22.8 W Dual DC inputs: 24.06 W |
Single DC input: 25.78 W Dual DC inputs: 24.06 W |
Power consumption (full load) |
Single DC input: 31.2 W Dual DC inputs: 31.29 W |
Single DC input: 200 W Dual DC inputs: 200 W |
Max PoE power per port |
N/A |
90 W |
Total PoE power |
N/A |
Single DC input: 160 W Dual DC inputs: 160 W |
Operating temperature |
–30°C to +60°C (–22°F to +140°F) |
|
Storage temperature |
–40°C to +85°C (–40°F to +185°F) |
|
Melting current of power supply fuse |
10 A |
10 A |
Heat dissipation |
Fanless, passive cooling |
|
Operating altitude |
0 m to 5000 m (0 ft to 16404.20 ft). The allowed maximum temperature decreases by 0.33°C (32.59°F) as the altitude increases by 100 m (328.08 ft) from Tmax@0m. |
|
Operating humidity |
5% to 100%, noncondensing |
|
Ingress protection rating |
IP40 |
|
Safety compliance |
UL62368-1/EN62368-1/IEC62368-1/GB4943.1 |
8 Available transceiver modules and cables
100/1000Base-X SFP port
Table8-1 Non-industrial transceiver modules available for the 100/1000Base-X SFP ports
Transceiver module model |
Central wavelength (nm) |
Connector type |
Cable type and diameter (µm) |
Mode bandwidth (MHz*km) |
Transmission distance |
Transmission rate |
SFP-GE-T-D |
N/A |
RJ-45 |
Category 5e twisted pair cable |
N/A |
100 m (328.08 ft) |
1250 Mbps |
SFP-GE-SX-MM850-A SFP-GE-SX-MM850-D SFP-GE-SX-MM850-S |
850 |
LC |
50/125 µm, MMF |
500 |
550 m (1804.46 ft) |
1250 Mbps |
400 |
500 m (1640.42 ft) |
1250 Mbps |
||||
62.5/125 µm, MMF |
200 |
275 m (902.23 ft) |
1250 Mbps |
|||
160 |
220 m (721.78 ft) |
1250 Mbps |
||||
SFP-GE-LX-SM1310-F |
1310 |
PoDLC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LX-SM1310-D SFP-GE-LX-SM1310-S |
1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LH100-SM1550 |
1550 |
LC |
9/125 µm, SMF |
N/A |
100 km (62.14 miles) |
1250 Mbps |
SFP-GE-LH40-SM1310 SFP-GE-LH40-SM1310-I |
1310 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
1250 Mbps |
SFP-GE-LH40-SM1550 |
1550 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
1250 Mbps |
SFP-GE-LH20-SM1310-I |
1310 |
LC |
9/125 µm, SMF |
N/A |
20 km (12.43 miles) |
1250 Mbps |
SFP-GE-LX10-SM1310 |
1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LX-SM1490-BIDI-I SFP-GE-LX-SM1490-BIDI-S |
Tx: 1490 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LX-SM1310-BIDI SFP-GE-LX-SM1310-BIDI-S SFP-GE-LX-SM1310-BIDI-I |
Tx: 1310 Rx: 1490 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LX-SM1490-BIDI |
Tx: 1490 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
1250 Mbps |
SFP-GE-LH40-SM1310-BIDI |
Tx: 1310 Rx: 1550 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
1250 Mbps |
SFP-GE-LH40-SM1550-BIDI |
Tx: 1550 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
1250 Mbps |
SFP-GE-LH70-SM1490-BIDI |
Tx: 1490 Rx: 1550 |
LC |
9/125 µm, SMF |
N/A |
70 km (43.50 miles) |
1250 Mbps |
SFP-GE-LH70-SM1550-BIDI |
Tx: 1550 Rx: 1490 |
LC |
9/125 µm, SMF |
N/A |
70 km (43.50 miles) |
1250 Mbps |
SFP-FE-SX-MM1310-A |
1310 |
LC |
50/125 µm, MMF |
N/A |
2 km (1.24 miles) |
155 Mbps |
62.5/125 µm, MMF |
N/A |
|||||
SFP-FE-LX-SM1310-A |
1310 |
LC |
9/125 µm, SMF |
N/A |
15 km (9.32 miles) |
155 Mbps |
SFP-FE-LH40-SM1310 |
1310 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
155 Mbps |
SFP-FE-BX15-U-SM1310 |
1310 |
LC |
9/125 µm, SMF |
N/A |
15 km (9.32 miles) |
155 Mbps |
SFP-FE-LX-SM1310-BIDI |
Tx: 1310 Rx: 1550 |
LC |
9/125 µm, SMF |
N/A |
15 km (9.32 miles) |
155 Mbps |
SFP-FE-LX-SM1550-BIDI |
Tx: 1550 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
15 km (9.32 miles) |
155 Mbps |
SFP-FE-LH80-SM1550 |
1550 |
LC |
9/125 µm, SMF |
N/A |
80 km (49.71 miles) |
155 Mbps |
Table8-2 Industrial transceiver modules available for the 100/1000Base-X SFP ports
Transceiver module model |
Central wavelength (nm) |
Connector type |
Cable type and diameter (µm) |
Mode bandwidth (MHz*km) |
Transmission distance |
Transmission rate |
SFP-GE-T-I |
N/A |
RJ-45 |
Category 5e twisted pair cable |
N/A |
100 m (328.08 ft) |
1250 Mbps |
SFP-FE-LH40-SM1310-I |
1310 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
155 Mbps |
SFP-GE-SX-MM850-I |
850 |
LC |
50/125 µm, MMF |
500 |
550 m (1804.46 ft) |
1250 Mbps |
400 |
500 m (1640.42 ft) |
|||||
62.5/125 µm, MMF |
200 |
275 m (902.23 ft) |
1250 Mbps |
|||
160 |
220 m (721.78 ft) |
|||||
SFP-GE-LH20-SM1310-BIDI |
Tx: 1310 Rx: 1490 |
LC |
9/125 µm, SMF |
N/A |
20 km (12.43 miles) |
155 Mbps |
SFP-GE-LH20-SM1490-BIDI-I |
Tx: 1490 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
20 km (12.43 miles) |
155 Mbps |
SFP-GE-LH40-SM1310-BIDI-I |
Tx: 1310 Rx: 1490 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
155 Mbps |
SFP-GE-LH40-SM1490-BIDI-I |
Tx: 1490 Rx: 1310 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
155 Mbps |
Table8-3 Non-industrial cables available for the 100/1000Base-X SFP ports
Cable model |
Transmission distance |
Transmission rate |
Cable type |
SFP-STACK-Kit SFP-STACK-Kit-S |
1.5 m (4.92 ft) |
1250 Mbps |
UTP/STP |
SFP+ port
Table8-4 Non-industrial transceiver modules available for the SFP+ ports
Transceiver module model |
Central wavelength (nm) |
Connector type |
Interface cable specifications |
Mode bandwidth (MHz*km) |
Transmission distance |
Transmission rate |
SFP-XG-SX-MM850-D SFP-XG-SX-MM850-E SFP-XG-SX-MM850-S SFP-XG-SX-MM850-A |
850 |
LC |
50/125 µm, MMF |
4700 |
400 m (1312.34 ft) |
10.31 Gbps |
2000 |
300 m (984.25 ft) |
|||||
500 |
82 m (269.03 ft) |
|||||
400 |
66 m (216.54 ft) |
|||||
62.5/125 µm, MMF |
200 |
33 m (108.27 ft) |
||||
160 |
26 m (85.30 ft) |
|||||
SFP-XG-LX-SM1310 SFP-XG-LX-SM1310-D SFP-XG-LX-SM1310-E SFP-XG-LX-SM1310-S SFP-XG-LX-SM1310-F |
1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
10.31 Gbps |
SFP-XG-LH40-SM1550 SFP-XG-LH40-SM1550-D SFP-XG-LH40-SM1550-S |
1550 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
10.31 Gbps |
SFP-XG-CPRI-IR-SM1310 |
1310 |
LC |
9/125 µm, SMF |
N/A |
1.4 km (0.87 miles) |
10.31 Gbps |
SFP-XG-SX-MM850-H |
850 |
LC |
50/125 µm, MMF |
4700 |
400 m (1312.34 ft) |
10.31 Gbps |
2000 |
300 m (984.25 ft) |
|||||
500 |
82 m (269.03 ft) |
|||||
400 |
66 m (216.54 ft) |
|||||
62.5/125 µm, MMF |
200 |
33 m (108.27 ft) |
||||
160 |
26 m (85.30 ft) |
|||||
SFP-XG-CPRI-LR-SM1310 |
1310 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
4.92 to 10.31 Gbps |
SFP-XG-LX-SM1270-BIDI SFP-XG-LX-SM1270-BIDI-S |
Tx: 1270 Rx: 1330 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
10.31 Gbps |
SFP-XG-LX-SM1330-BIDI SFP-XG-LX-SM1330-BIDI-S |
Tx: 1330 Rx: 1270 |
LC |
9/125 µm, SMF |
N/A |
10 km (6.21 miles) |
10.31 Gbps |
SFP-XG-LH40-SM1270-BIDI |
Tx: 1270 Rx: 1330 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
10.31 Gbps |
SFP-XG-LH40-SM1330-BIDI |
Tx: 1330 Rx: 1270 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
10.31 Gbps |
SFP-XG-LH80-SM1490-BIDI |
Tx: 1490 Rx: 1550 |
LC |
9/125 µm, SMF |
N/A |
80 km (49.71 miles) |
10.31 Gbps |
SFP-XG-LH80-SM1550 SFP-XG-LH80-SM1550-D |
1550 |
LC |
9/125 µm, SMF |
N/A |
80 km (49.71 miles) |
10.31 Gbps |
SFP-XG-LH80-SM1550-BIDI |
Tx: 1550 Rx: 1490 |
LC |
9/125 µm, SMF |
N/A |
80 km (49.71 miles) |
10.31 Gbps |
Table8-5 Industrial transceiver modules available for the SFP+ ports
Transceiver module model |
Central wavelength (nm) |
Connector type |
Interface cable specifications |
Mode bandwidth (MHz*km) |
Transmission distance |
Transmission rate |
SFP-XG-SX-MM850-I |
850 |
LC |
50/125 µm, MMF |
4700 |
400 m (1312.34 ft) |
10.31 Gbps |
2000 |
300 m (984.25 ft) |
|||||
500 |
82 m (269.03 ft) |
|||||
400 |
66 m (216.54 ft) |
|||||
62.5/125 µm, MMF |
200 |
33 m (108.27 ft) |
||||
160 |
26 m (85.30 ft) |
|||||
SFP-XG-LH40-SM1550-I |
1550 |
LC |
9/125 µm, SMF |
N/A |
40 km (24.86 miles) |
10.31 Gbps |
Table8-6 Non-industrial cables available for the SFP+ ports
Cable model |
Cable length |
Transmission rate |
LSWM1STK |
0.65 m (2.13 ft) |
10.31 Gbps |
LSWM2STK |
1.2 m (3.94 ft) |
|
LSWM3STK |
3 m (9.84 ft) |
|
LSTM1STK |
5 m (16.40 ft) |