Edge-Core ECS5610-52S, AS5600-52X, AS5610-52X Installation Manual

ECS5610-52S
48-Port Layer 3
10G Top-of-Rack Switch

Installation Guide

www.edge-core.com

Installation Guide

ECS5610-52S 48-Port 10G Top-of-Rack Switch

with 48 10GBASE SFP+ Ports,
4 40GBASE QSFP+ Ports,
1 1000BASE-T (RJ-45) Management Port,
2 Power Supply Units (F2B and B2F Airflow),
and 1 Fan Tray Module (F2B and B2F Airflow)

E062013-KS-R01
150200000495A

How to Use This Guide

This guide includes detailed information on the switch hardware, including
network ports, power, cabling requirements, as well as plug-in modules and
transceivers. This guide also provides general installation guidelines and
recommended procedures. To deploy this switch effectively and ensure trouble­free operation, you should first read the relevant sections in this guide so that you
are familiar with all its hardware components.

Who Should Read This

Guide?

How This Guide is

Organized

This guide is for network administrators and support personnel that install, operate,
and maintain network equipment. The guide assumes a basic working knowledge
of LANs (Local Area Networks) and can be read by those that are new to network
equipment, or those with more experience.

The organization of this guide is based on the switch’s main hardware components.
Each chapter includes information about a specific component with relevant
specifications and installation procedures. A switch overview section is also
provided.

For Users New to Switches

recommended that you first read all chapters in this guide before installing the
switch.

For Experienced Users

network switches, the Switch Description and Installation Overview chapters
provide you with enough information to install the switch. Other chapters can be
left for reference, when needed.

The guide includes these chapters:

◆ Chapter 1 - Switch Description — Includes a switch overview, key component

identification, key technical specifications, and switch deployment information.

— If you are new to network switches, it is

— If you are already familiar with installing and operating

◆ Chapter 2 - Installation Overview — Includes details of the package contents

and an outline of switch installation tasks.

◆ Chapter 3 - Switch Chassis — Includes switch chassis rack installaion, and

system cooling requirements.

◆ Chapter 4 - Power and Grounding — Includes installation of AC power

modules, switch grounding, and powering on the switch.

– 3 –

How to Use This Guide

◆ Chapter 5 - Port Connections — Includes information on network interfaces,

installing optional transceivers, and cabling specifications.

◆ Chapter 6 - Switch Management — Connecting to the switch for management,

and information on the system status LEDs.

◆ Appendix A - Troubleshooting — Information for troubleshooting switch

installation and operation.

Related

Documentation

This guide focuses on switch hardware and installation, it does not cover software
configuration of the switch. For specific information on how to operate and use the
management functions of the switch, see the following guides:

CLI Command Reference
Administrator’s Guide

For all safety information and regulatory statements, see the following document:

Quick Start Guide
Safety and Regulatory Information

Conventions The following conventions are used throughout this guide to show information:

Note:

Emphasizes important information or calls your attention to related features

or instructions.

Caution:

the system or equipment.

Alerts you to a potential hazard that could cause loss of data, or damage

Warning:

Revision History This section summarizes the changes in each revision of this guide.

April 2013 Revision

This is the first revision of this guide.

Alerts you to a potential hazard that could cause personal injury.

– 4 –

Contents

How to Use This Guide 3

Contents 5

Figures 7

Tables 9

1 Switch Description 10

Overview 10

Key Hardware Components 11

Key Technical Specifications 13

Data Center Deployment 14

Rack Cooling 15

2 Installation Overview 18

Package Contents 18

Switch Installation Tasks 19

3 Switch Chassis 23

General Installation Guidelines 23

How to Install the Switch in a Rack 24

Rack-Mounting Items 24

Rack-Mount Procedure 24

Switch Cooling Requirements 26

Rack Cooling 27

Fan Tray Module 27

How to Replace a Fan Tray 28

4 Power and Grounding 29

Power Supply Modules 29

Grounding the Chassis 31

How to Connect to AC Power 31

– 5 –

Contents

5 Port Connections 33

Cable Labeling and Connection Records 34

Understanding the Port Status LEDs 35

How to Install an SFP/SFP+/QSFP+ Transceiver 36

How to Connect to the Twisted-Pair Copper Management Port 37

Copper Cabling Guidelines 38

1000BASE-T Pin Assignments 38

Connection Procedure 39

How to Connect to SFP/SFP+ Fiber Optic Ports 39

Connection Procedure 40

How to Connect to QSFP+ Fiber Optic Ports 42

Connection Procedure 42

DAC Connections 44

Making DAC Connections 44

6 Switch Management 47

Understanding the System Status LEDs 48

How to Connect to the Management Port 49

How to Connect to the Console Port 50

How to Connect to the USB Port 52

How to Reset the Switch 53

A Troubleshooting 54

Diagnosing LED Indicators 54

System Self-Diagnostic Test Failure 54

Power and Cooling Problems 55

Installation 55

In-Band Access 55

Index 56

– 6 –

Figures

Figure 1: Front Panel 11

Figure 2: Rear Panel 12

Figure 3: Cloud Data Center Deployment 14

Figure 4: Converged Ethernet Data Center Deployment 15

Figure 5: F2B Airflow Cooling 15

Figure 6: B2F Airflow Cooling 16

Figure 7: Installing the Switch in a Rack 19

Figure 8: Connecting AC Power 20

Figure 9: System LEDs 21

Figure 10: Console Port 21

Figure 11: Making a Connection to a QSFP+ Transceiver 22

Figure 12: Attaching the Brackets 25

Figure 13: Installing the Switch in a Rack 25

Figure 14: Switch Cooling 26

Figure 15: Fan Tray 28

Figure 16: AC Power Supply Module 30

Figure 17: Power Supply Module LED 30

Figure 18: AC PSU and Power Socket 32

Figure 19: Port Status LEDs 35

Figure 20: Port Status LEDs 35

Figure 21: Inserting an SFP/SFP+/QSFP+ Transceiver into a Slot 37

Figure 22: RJ-45 Connector 38

Figure 23: Making Connections to an SFP+ Transceiver 41

Figure 24: Connecting to a QSFP+ Transceiver 43

Figure 25: Making DAC Connections 45

Figure 26: System LEDs 48

Figure 27: Management Port 49

Figure 28: Console Port 50

Figure 29: Console Port Connection 51

– 7 –

Figures

Figure 30: USB Port 52

Figure 31: Reset Button 53

– 8 –

Tables

Table 1: Key Technical Specifications 13

Table 2: Fan Tray Specifications 28

Table 3: AC Power Supply Module Specifications 30

Table 4: Maximum Twisted-Pair Copper Cable Lengths 37

Table 5: 1000BASE-T MDI and MDI-X Port Pinouts 38

Table 6: Maximum 10 Gigabit Ethernet Fiber Cable Lengths 39

Table 7: Maximum Gigabit Ethernet Fiber Cable Lengths 40

Table 8: Maximum 40 Gigabit Ethernet Fiber Cable Lengths 42

Table 9: Maximum 10GBASE-CR 10 Gigabit Ethernet Cable Lengths 44

Table 10: Maximum 40GBASE-CR4 40 Gigabit Ethernet Cable Lengths 44

Table 11: System Status LEDs 48

Table 12: RJ-45 Management Port Status LEDs 49

Table 13: Console Cable Wiring 51

Table 14: Troubleshooting Chart 54

– 9 –

1 Switch Description

This chapter includes these sections:

◆ “Overview” on page 10

◆ “Key Technical Specifications” on page 13

◆ “Data Center Deployment” on page 14

Overview

Thank you for choosing the ECS5610-52S switch system. This switch is built with
leading-edge technology to deliver reliable high-performance connectivity for
your data network.

The ECS5610-52S switch is a high-performance top-of-rack switch, designed for
data center operating environments. The switch provides 48 10G Ethernet Small
Form Factor Pluggable Plus (SFP+) transceiver slots, and four 40G Quad-SFP+
(QSFP+) ports. The switch also includes replaceable dual power supply units and a
fan tray module.

The switch supports a full set of Layer 2 switching, data center bridging, and Layer 3
routing features. The switch can be deployed as a top-of-rack (TOR) or distributed
spine switch to form a network fabric that can reduce infrastructure expenses and
power consumption in the data center. This network fabric can be used to
interconnect tens of thousands of servers delivering cloud computing services.

The switch also offers an option of front-to-back (F2B) or back-to-front (B2F) airflow
cooling for rack deployment with either blade servers or other switches, allowing
cool aisles to be maintained without creating “hot loops.”

– 10 –

Chapter 1

1

7

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4

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8

1526374

8

| Switch Description

Overview

Key Hardware

Components

Figure 1: Front Panel

Port LEDs RJ-45 Management Port

10G SFP+ Slots USB Port

The ECS5610-52S switch consists of several key hardware components. This manual
describes each specific component, or related components, together with their
installation requirements and procedures in each chapter. To understand each
component in detail, refer to the relevant section.

40G QSFP+ Slots System LEDs

Reset Button RJ-45 Console Port

10G SFP+ Slots

The switch contains 48 Small Form Factor Pluggable Plus (SFP+) transceiver slots
that support 10G Ethernet SFP+ transceivers, or 1G Ethernet SFP transceivers. For
more information, see “How to Connect to SFP/SFP+ Fiber Optic Ports” on page 39.

40G QSFP+ Slots

The switch contains four Quad Small Form Factor Pluggable Plus (QSFP+)
transceiver slots that operate up to 40 Gbps full duplex. For more information, see

“How to Connect to QSFP+ Fiber Optic Ports” on page 42.

Management Port

The RJ-45 port labeled “Management” provides a dedicated 1000BASE-T
management interface. For more information, see “How to Connect to the

Management Port” on page 49.

Console Port

The RJ-45 port labeled “Console” provides an out-of-band serial connection to a
terminal or a PC running terminal emulation software. The port can be used for
performing switch monitoring and configuration. For more information, see “How

to Connect to the Console Port” on page 50.

– 11 –

Chapter 1

21

2

1

2

Overview

| Switch Description

USB Port

A USB port is provided on the switch front panel. This port is for transferring
configuration files from a USB storage device to the switch’s flash memory. For
more information, see “How to Connect to the USB Port” on page 52.

Reset Button

Pressing the reset button on the front panel causes the switch to preform a hard
reset. For more information, see “How to Reset the Switch” on page 53.

System LEDs

For information on system status LED indicators, see “Understanding the System

Status LEDs” on page 48.

Port LEDs

For information on port status LED indicators, see “Understanding the Port Status

LEDs” on page 35.

Figure 2: Rear Panel

Fan Tray Module Power Supply Modules

Power Supply Modules

The switch supports dual hot-swappable AC power supply units (PSUs). You can
install up to two PSUs with matching airflow direction in the switch. For more
information on the switch power supplies, how to install them, and how to power­on the switch, see “Power Supply Modules” on page 29.

Fan Tray Module

The fan tray module provides air cooling for the switch system. For more
information, see “Switch Cooling Requirements” on page 26.

– 12 –

Key Technical Specifications

The following table contains key system specifications for the switch.

Table 1: Key Technical Specifications

Item Specification

Ports 48 10 Gbps SFP+ transceiver slots

Network Interface Ports 1~48: SFP+

Chapter 1

| Switch Description

Key Technical Specifications

4 40 Gbps QSFP+ transceiver slots
1 10/100/1000 Mbps RJ-45 Management port

◆

10 Gbps SFP+ transceivers: 10GBASE-CR, 10GBASE-SR,
10GBASE-LR, 10GBASE-LRM

◆

1 Gbps SFP transceivers: 1000BASE-SX, 1000BASE-LX

Ports 49~52: QSFP+

◆

40 Gbps QSFP+ transceivers: 40GBASE-CR4, 40GBASE-SR4

Management Port

◆

10/100/1000BASE-T, RJ-45 connector

Buffer Architecture 32 Mbit packet buffer

Aggregate Bandwidth 1280 Gbps

Switching Database 128K MAC address entries

LEDs System: PS1, PS2, Diag (Diagnostic), Fan, Loc (Locator)

Ports 1~52:

Status (link and activity)

Power Supply Module 100-240 VAC, 50-60 Hz, auto-sensing; hot pluggable

350 Watts@ 240V/100V per module

Power Consumption 258 Watts maximum

Weight 8.5 kg (18.7 lb), with two installed power supply modules

Size W x D x H: 440 x 473 x 44 mm (17.32 x 18.62 x 1.75 inches)

Temperature Operating: 0 °C to 40 °C (32 °F to 104 °F)

Storage: -40 °C to 70 °C (-40 °F to 158 °F)

Humidity Operating: 5% to 95% (non-condensing)

Out-of-Band Management RS-232 RJ-45 console port

In-Band Management SSH, Telnet, SNMP, or HTTP

Software Loading HTTP, FTP/TFTP in-band

Forwarding Mode Store-and-forward

Throughput Wire speed

Flow Control Full Duplex: IEEE 802.3x

Half Duplex: Back pressure

– 13 –

Chapter 1

Data Center Deployment

| Switch Description

Data Center Deployment

The switch is designed for high-availability data center environments with a high
port density. The switch includes redundant, hot-swappable, load-sharing AC PSUs,
a hot-swappable fan tray, and port-to-power and power-to-port airflow direction
options. Meeting the network scaling requirements of enterprise and cloud data
centers, the switch can be deployed as a top-of-rack switch or as part of a
distributed spine network, providing full line-rate switching at Layer 2 or Layer 3
across all ports.

Figure 3: Cloud Data Center Deployment

Non-Blocking Distributed Spine Network

. . .

…

. . .

Spine Cluster 1

TOR or Leaf Switch

1GbE or 10GbE

Servers or

Storage Nodes

L2

…

vSwi tch

Server Rack 1

…

OSFP/BGP

ECMP

…

vSwi tch

Server Rack n

Spine Cluster x

…

Core Router Racks

…

In many data center configurations, Ethernet connections link servers and data
networks, and Fibre Channel connections link servers to storage networks. This
switch enables the creation of a converged network, which employs lossless
Ethernet connections between FCOE storage, servers, and other data network
switches.

– 14 –

Chapter 1

FCoE Storage

Servers Servers

ToR Switch ToR Switch

Core Switch

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Front of Rack

Rear of Rack

Cool Aisle

Hot Aisle

Servers

ToR Switch

Figure 4: Converged Ethernet Data Center Deployment

| Switch Description

Data Center Deployment

Rack Cooling The top-of-rack switch is a high-performance, high-density unit that generates a

substantial amount of heat. When mounted in a rack with other equipment, it is
important that the switch has the same airflow direction to avoid “hot loops” in the
data center aisles. Hot loops increase cooling requirements since warm air is drawn
into rack devices instead of cool air.

Most rack-mounted blade servers draw cool air from the front and expel hot air at
the rear. The top-of-rack switch includes power supply units and a fan tray module
that have a front-to-back (F2B) airflow direction that maintains cool aisles in the
data center.

Figure 5: F2B Airflow Cooling

– 15 –

Chapter 1

Servers

ToR Switch

Front of Rack

Rear of Rack

Cool Aisle

Hot Aisle

| Switch Description

Data Center Deployment

When mounted in a rack with other network equipment that may have a back-to­front (B2F) airflow direction, the top-of-rack switch includes power supply and fan
tray modules that reverse the airflow direction through the switch. This enables
various deployment options for the switch in the data center.

Figure 6: B2F Airflow Cooling

– 16 –

Chapter 1

Data Center Deployment

| Switch Description

– 17 –

2 Installation Overview

This chapter includes these sections:

◆ “Package Contents” on page 18

◆ “Switch Installation Tasks” on page 19

Package Contents

After unpacking the switch, check the contents to be sure you have received all the
components.

◆ ECS5610-52S 10G Top-of-Rack Switch

◆ Rack Mounting Kit containing two brackets and eight screws for attaching the

brackets to the switch

◆ Power cord—either US, Continental Europe or UK

◆ Console cable (RJ-45 to DB-9)

◆ Quick Start Guide

◆ Regulatory and Safety Information

◆ Documentation CD—includes Installation Guide and Management Guide

– 18 –

Switch Installation Tasks

Task 1

Task 2

2

1

1

2

Follow these tasks to install the switch in your network. For full details on each task,
go to the relevant chapter or section by clicking on the link.

Chapter 2

| Installation Overview

Switch Installation Tasks

Caution:

Before installing your switch, first review all the safety statements and

guidelines in the Regulatory and Safety Information document.

Unpack package and check contents

Unpack your switch and check the package contents to be sure you have received
all the items. See “Package Contents” on page 18.

Install the Chassis

The switch is designed to be installed in a standard 19-inch equipment rack. Plan
your rack installation and install the switch chassis in the rack. Be sure to take into
account switch cooling requirements.

Go to the chapter “Switch Chassis”

Figure 7: Installing the Switch in a Rack

Attach the brackets to the switch, Use the rack mounting screws supplied

with the rack to secure the switch in the
rack.

– 19 –

Chapter 2

Task 3

1

2

1

2

Task 4

Switch Installation Tasks

| Installation Overview

Install Power Modules and Power On

Install power modules, then power on. The switch supports up to two PSUs that
have a matching airflow direction as the installed fan tray.

Caution:

The switch includes plug-in power supply and fan tray modules that are
installed into its chassis. All installed modules must have a matching airflow
direction. That is, all modules must have a front-to-back (F2B) airflow direction, or
all modules must have a back-to-front (B2F) airflow direction. The airflow direction
of PSUs and fan trays is indicated by labels on the modules.

Go to the chapter “Power and Grounding”

Figure 8: Connecting AC Power

Verify Switch Operation

Verify basic switch operation by checking the system LEDs.

When operating normally, the PSU1/PSU2, Diag, and Fan LEDs should all be on
green. If any of the LEDs are on amber, see “Diagnosing LED Indicators” on page 54

Install one or two universal AC power
modules in the switch.

Connect an external AC power source
to the modules.

Go to the section “Understanding the System Status LEDs”

– 20 –

Figure 9: System LEDs

1

1

Task 5

1

1

System Status LEDs.

Chapter 2

| Installation Overview

Switch Installation Tasks

Make Initial Configuration Changes

At this point you may need to make a few basic switch configuration changes
before connecting to the network. It is suggested to connect to the switch console
port to perform this task.

The serial port’s configuration requirements are as follows: 9600 bps, 8 characters,
no parity, one stop bit, 8 data bits, and no flow control.

You can log in to the command-line interface (CLI) using default settings: User
“admin” with no password.

Go to “How to Connect to the Console Port”

Figure 10: Console Port

Console Port

– 21 –

Chapter 2

Task 6

1

2

1

2

Switch Installation Tasks

| Installation Overview

For information on initial switch configuration:

Refer to the Administrator’s Guide.

Install Transceivers and Connect Cables

Install SFP+ or QSFP+ transceivers and connect network cables to port interfaces:

◆ Connect DAC cables to the SFP+/QSFP+ slots. Or first install SFP+/QSFP+

transceivers and then connect fiber optic cabling to the transceiver ports.

◆ For the RJ-45 Management port, use 100-ohm Category 5, 5e or better cable for

1000BASE-T connections.

As connections are made, check the port status LEDs to be sure the links are valid.

Go to the chapter “Port Connections”

Figure 11: Making a Connection to a QSFP+ Transceiver

Install QSFP+ transceivers. Connect fiber optic cabling to the ports.

– 22 –

3 Switch Chassis

The switch is designed to be installed in a standard 19-inch equipment rack.

Before continuing with switch installation, first review the general guidelines and
switch cooling requirements in this chapter.

This chapter includes these sections:

◆ “General Installation Guidelines” on page 23

◆ “How to Install the Switch in a Rack” on page 24

◆ “Switch Cooling Requirements” on page 26

General Installation Guidelines

Be sure to follow the guidelines below when choosing a location.

◆ The installation location should:

■

be able to maintain its temperature within -40 to 70 °C (-40 to 158 °F) and
its humidity within 5% to 95%, non-condensing.

■

provide adequate space (approximately five centimeters or two inches) on
all sides for proper air flow.

■

be accessible for installing, cabling and maintaining the device.

■

allow the status LEDs to be clearly visible.

◆ Make sure twisted-pair cable is always routed away from power lines,

fluorescent lighting fixtures and other sources of electrical interference, such as
radios and transmitters.

◆ Make sure that the unit is connected to a separate grounded power outlet and

is powered from an independent circuit breaker. As with any equipment, using
a filter or surge suppressor is recommended. Verify that the external power
requirements for the switch can be met as listed under “Power Supply

Modules” on page 29.

– 23 –

Chapter 3

How to Install the Switch in a Rack

| Switch Chassis

How to Install the Switch in a Rack

When rack mounting the switch, pay particular attention to the following factors:

◆ Rack Types: You can use any standard EIA 19-inch equipment rack with either

two or four posts. The bracket hole pattern should be spaced 1U (1.75 in. or

4.45 cm) apart.

◆ Rack Stability: Whenever possible, secure the rack to the building ceiling or

floor, particularly if you are located in a region where earthquakes are common.

◆ Rack Planning: When installing equipment in a rack, first plan how units can

be best arranged. Try to always mount the heaviest equipment at the bottom
of the rack.

◆ Te mp e ra t u re : Since the temperature within a rack assembly may be higher

than the ambient room temperature, check that the rack-environment
temperature is within the specified operating temperature range. See “Switch

Cooling Requirements” on page 26.

◆ Mechanical Loading: Do not place any equipment on top of a rack-mounted

unit.

◆ Circuit Overloading: Be sure that the supply circuit to the rack assembly is not

overloaded.

◆ Grounding: Rack-mounted equipment should be properly grounded.

Rack-Mounting Items Before you start to rack-mount the switch, be sure to have the following items

available:

◆ Four mounting screws for each device you plan to install in a rack—these are

not included. Be sure to use the rack mounting screws that are supplied with
the rack.

◆ A screwdriver (Phillips or flathead, depending on the type of screws used).

Rack-Mount

To rack mount the switch, follow these steps:

Procedure

Caution:

the switch in the rack, while the other secures it using the mounting screws.

Installing the switch in a rack requires two people: One should position

– 24 –

Chapter 3

1

1

1

1

How to Install the Switch in a Rack

| Switch Chassis

1. Attach the brackets to the device using the screws provided in the Rack

Mounting Kit.

Figure 12: Attaching the Brackets

Use the screws provided in the Bracket
Mounting Kit.

2. Following your rack plan, mark the holes in the rack where the switch will be

installed.

3. One person should lift the switch into the rack so that it is aligned with the

marked holes.

4. The second person should secure the switch in the rack, using four rack-

mounting screws (not provided).

Figure 13: Installing the Switch in a Rack

Use the rack mounting screws supplied
with the rack.

– 25 –

Chapter 3

1

2

1

2

Switch Cooling Requirements

| Switch Chassis

5. If installing a single switch only, go to “Power and Grounding” on page 29.

6. If installing multiple switches, repeat steps 1 to 4 to mount the switches

following your rack plan.

Switch Cooling Requirements

Wherever the switch is located, be sure to pay close attention to switch cooling
requirements. The location should be well ventilated and provide unrestricted air
flow at the front, back, and sides of the switch. If the air flow is insufficient, it may
cause the switch to overheat and possibly fail.

The switch includes a removable fan tray module located in the rear of the switch.
The module options may have either a front-to-back (F2B) airflow direction or a
back-to-front (B2F) airflow direction. The switch’s plug-in power supply modules
also include a fan, which can be either F2B or B2F airflow direction. For proper
switch cooling, all installed modules must have a matching airflow direction.

The following figure shows the airflow through the switch.

Figure 14: Switch Cooling

B2F Airflow F2B Airflow

– 26 –

Chapter 3

Switch Cooling Requirements

| Switch Chassis

Rack Cooling When mounting the switch in an enclosed rack or cabinet, be sure to check the

following guidelines to prevent overheating:

◆ Make sure that enough cool air can flow into the enclosure for the equipment it

contains.

◆ Check that the rack or cabinet allows the hot air to exit the enclosure (normally

from the top) without circulating back into equipment.

◆ If the enclosure has sides or doors with ventilation holes, make sure they are

not blocked by cables or other obstructions.

◆ Route cables within the rack or cabinet to maximize the air flow.

◆ When possible, do not completely fill the rack or cabinet with equipment, allow

some unused space within the enclosure for better air flow.

Fan Tray Module The fan tray module is an important part of the switch air cooling system. A fan tray

module must be installed in the switch at all times. If a fan should fail, the whole fan
tray module must be replaced as soon as possible.

You must install the fan tray module in the switch that matches the airflow
direction of the installed power supply units. The available fan tray modules are
listed below:

◆ ECS5610-52SS-FANTRAY (front-to-back airflow)

◆ ECS5610-52SSR-FANTRAY (back-to-front airflow)

Caution:

The switch includes plug-in power supply and fan tray modules that are
installed into its chassis. All installed modules must have a matching airflow
direction. That is, all modules must have a front-to-back (F2B) airflow direction, or
all modules must have a back-to-front (B2F) airflow direction. The airflow direction
of PSUs and fan trays is indicated by labels on the modules.

The removable fan tray, located in the rear of the switch, includes four fixed fans
and supports fan speed control. The fan speed is dynamically controlled as a
function of temperature: the higher the internal temperature, the faster the speed
of the fans. The fan tray module does not include LED indicators.

– 27 –

Chapter 3

1

1

Switch Cooling Requirements

| Switch Chassis

The following figure shows the fan tray removed from the switch.

Figure 15: Fan Tray

How to Replace a Fan

Tray

Label indicates airflow direction

Table 2: Fan Tray Specifications

Item Description

Power Consumption 12 VDC @ 2.8 A, 37 Watts maximum

Airflow 76.4 CFM minimum

90.4 CFM maximum

Dimensions W x D x H: 207 x 94.25 x 40.4 mm (8.15 x 3.71 x 1.59 inches)

The switch system is shipped with a fan tray module installed. If a fan failure is
detected (see “Understanding the System Status LEDs” on page 48), the module
should be replaced immediately.

Follow this procedure to replace a fan tray:

1. Loosen the two retaining screws on the front panel of the fan tray.

2. Pull firmly on the screws until the fan tray is free.

3. Slide the fan tray out of the switch.

4. Insert the replacement fan tray into the slot and slide it slowly into the chassis.

5. Push firmly until the fan tray clicks into place. The fans should immediately start

to operate.

6. Tighten the retaining screws to secure the fan tray in the chassis.

– 28 –

4 Power and Grounding

This chapter focuses on the switch power supplies, how to intall them, and how to
power-on the switch. Connecting the switch to ground is also covered.

This chapter includes these sections:

◆ “Power Supply Modules” on page 29

◆ “Grounding the Chassis” on page 31

◆ “How to Connect to AC Power” on page 31

Power Supply Modules

The switch supports hot-swappable power supply units (PSUs). You can install up
to two PSUs with matching airflow direction in the switch. The PSUs operate in a
load-sharing mode and provide 1+1 redundancy.

Note:

1+1 redundancy is a system where a switch power supply is backed up by
another switch power supply in a load-sharing mode. If one power supply fails, the
other power supply takes over the full load of the switch.

The switch provides two AC power supply module options, which are listed below:

◆ ECS5610-52S-ACPWR (front-to-back airflow)

◆ ECS5610-52SR-ACPWR (back-to-front airflow)

Caution:

installed into its chassis. All installed modules must have a matching airflow
direction. That is, all modules must have a front-to-back (F2B) airflow direction, or
all modules must have a back-to-front (B2F) airflow direction. The airflow direction
of PSUs and fan trays is indicated by labels on the modules.

The AC Power Supply Modules require power from an external AC power supply
that can provide 100 to 240 VAC, 50-60 Hz. A standard AC power socket is located
on the rear panel of the PSU. The power socket is for the AC power cord.

The switch includes plug-in power supply and fan tray modules that are

– 29 –

Chapter 4

1

2

3

4

132

4

| Power and Grounding

Power Supply Modules

Figure 16: AC Power Supply Module

AC Power Socket Release Lever

Power Supply Module LED Label indicates airflow direction of PSU

Table 3: AC Power Supply Module Specifications

Item Description

AC Input 100-240 VAC, 50-60 Hz, 6-3 A

DC Output +5 Vsb @ 3 A

12 Vdc @ 33 A

Power Supply 100-240 VAC, 50-60 Hz, auto-sensing; hot pluggable

350 Watts@ 220V/110V per module

Power Consumption 258 Watts maximum

Maximum Current 6 A @ 100 VAC

3 A @ 240 VAC

Size W x D x H: 220 x 54.5 x 40.25 mm (8.66 x 2.15 x 1.58 inches)

The PSU also includes an AC power status LED. This LED is described in the
following table.

Figure 17: Power Supply Module LED

LED Condition Status

AC Green External AC power is connected to the module.

Off External power is not connected or has failed.

– 30 –

Grounding the Chassis

The switch chassis must be connected to ground to ensure proper operation and to
meet electromagnetic interference (EMI) and safety requirements.

The switch chassis is connected internally to 0 V, which is then grounded through
an installed AC PSU when it is connected to a grounded AC power outlet by an AC
power cord.

There are no grounding points on the switch that require a connection to a rack
ground or other earth ground.

How to Connect to AC Power

To supply AC power to the switch, first verify that the external AC power supply can
provide 100 to 240 VAC, 50-60 Hz, 6-3 A minimum.

Chapter 4

| Power and Grounding

Grounding the Chassis

Note:

For electrical safety purposes, please pay attention to the following warning
notices, printed on the switch unit.

To connect the switch to a power source:

1. Install one or two AC PSU modules. Slide them into the PSU slots at the rear of

the switch until they click into place. (Push the red release lever to remove a
module from the switch.)

– 31 –

Chapter 4

2

1

1

2

How to Connect to AC Power

| Power and Grounding

Figure 18: AC PSU and Power Socket

AC Power Cord AC PSU

2. Plug the power cord into a grounded, 3-pin, AC power source.

Note:

For international use, you may need to change the AC power cord. You must
use a cord set that has been approved for the socket type in your country.

3. Insert the plug on the other end of the power cord directly into the socket on

the AC PSU.

4. Check the LED indicators on the PSU and switch front panel as the unit is

powered on to verify that power is being received. If not, recheck the PSU and
power cord connections at the AC supply source and PSU.

5. If you have installed a second PSU, repeat steps 2 to 4.

– 32 –

5 Port Connections

This chapter focuses on making connections to switch network interfaces,
including how to install optional transceivers, and details on network cable
specifications.

The switch features 48 SFP+ transceiver slots and four 40 Gigabit QSFP+ transceiver
slots. The sections that follow describe these interfaces.

Note:

The switch also has one 10/100/1000BASE-T port for dedicated management
access. This port is described in “How to Connect to the Management Port” on

page 49.

This chapter includes these sections:

◆ “Cable Labeling and Connection Records” on page 34

◆ “Understanding the Port Status LEDs” on page 35

◆ “How to Install an SFP/SFP+/QSFP+ Transceiver” on page 36

◆ “How to Connect to the Twisted-Pair Copper Management Port” on page 37

◆ “How to Connect to SFP/SFP+ Fiber Optic Ports” on page 39

◆ “How to Connect to QSFP+ Fiber Optic Ports” on page 42

– 33 –

Chapter 5

Cable Labeling and Connection Records

| Port Connections

Cable Labeling and Connection Records

When planning a network installation, it is essential to label the opposing ends of
cables and to record where each cable is connected. Doing so will enable you to
easily locate inter-connected devices, isolate faults and change your topology
without need for unnecessary time consumption.

To best manage the physical implementations of your network, follow these
guidelines:

◆ Clearly label the opposing ends of each cable.

◆ Using your building’s floor plans, draw a map of the location of all network-

connected equipment. For each piece of equipment, identify the devices to
which it is connected.

◆ Note the length of each cable and the maximum cable length supported by the

switch ports.

◆ For ease of understanding, use a location-based key when assigning prefixes to

your cable labeling.

◆ Use sequential numbers for cables that originate from the same equipment.

◆ Differentiate between racks by naming accordingly.

◆ Label each separate piece of equipment.

◆ Display a copy of your equipment map, including keys to all abbreviations at

each equipment rack.

– 34 –

Understanding the Port Status LEDs

1

2

1

2

The switch includes LED indicators for each port to indicate link status and network
activity. The port LEDs are shown below and described in the following table.

Figure 19: Port Status LEDs

Chapter 5

| Port Connections

Understanding the Port Status LEDs

Port 1-48 Link/Activity LEDs Port 49-52 Link/Activity LEDs

Figure 20: Port Status LEDs

LED Condition Status

10G SFP+ Ports (1-48)

Link/Activity On/Flashing Green Port has a valid 10G link. Flashing indicates

On/Flashing Amber Port has a valid 1G link. Flashing indicates activity

Off The link is down.

40G QSFP+ Ports (49-52)

Link/Activity On Green Port has a valid 40G link.

Flashing Green Flashing indicates activity on the port.

Off The link is down.

activity on the port.

on the port.

– 35 –

Chapter 5

| Port Connections

How to Install an SFP/SFP+/QSFP+ Transceiver

How to Install an SFP/SFP+/QSFP+ Transceiver

The switch provides slots for optional SFP, SFP+, and QSFP+ transceivers. The
supported transceiver types are listed below:

◆ 40 Gbps Ethernet QSFP+ transceivers

■

40GBASE-CR4

■

40GBASE-SR4

◆ 10 Gbps Ethernet SFP+ transceivers

■

10GBASE-CR

■

10GBASE-SR

■

10GBASE-LR

■

10GBASE-LRM

◆ 1000 Mbps Ethernet SFP transceivers

■

1000BASE-SX

■

1000BASE-LX

Note:

SFP/SFP+/QSFP+ transceivers are hot-swappable. The switch does not need
to be powered off before installing or removing a transceiver.

Note:

SFP/SFP+/QSFP+ transceivers are not provided in the switch package.

To install an SFP/SFP+/QSFP+ transceiver, do the following:

1. Consider network and cabling requirements to select an appropriate

transceiver type that is also compatible with the switch transceiver support.

2. If the SFP/SFP+/QSFP+ slot is covered with a rubber protective cap, remove the

cap and keep it for later replacement.

3. Insert the transceiver with the optical connector facing outward and the slot

connector facing down. Note that SFP/SFP+/QSFP+ transceivers are keyed so
they can only be installed in the correct orientation.

4. Slide the transceiver into the slot until it clicks into place. If you do not

immediately connect a cable to the port, use a rubber protective cap to keep
the transceiver optics clean.

– 36 –

Chapter 5

1

1

How to Connect to the Twisted-Pair Copper Management Port

Figure 21: Inserting an SFP/SFP+/QSFP+ Transceiver into a Slot

QSFP+ Transceiver

| Port Connections

Note:

To uninstall a transceiver: First disconnect the network cable, then release
and pull the wire bail to remove the transceiver from the slot.

How to Connect to the Twisted-Pair Copper Management Port

The RJ-45 management port on the switch supports automatic MDI/MDI-X pinout
configuration, so you can use standard straight-through twisted-pair cables to
connect to any other network device (PCs, servers, switches, routers, or hubs).

The connection requires an unshielded twisted-pair (UTP) cable with RJ-45
connectors at both ends. Use Category 5, 5e or 6 cable for 1000BASE-T connections,
Category 5 or better for 100BASE-TX connections, and Category 3 or better for
10BASE-T connections.

Table 4: Maximum Twisted-Pair Copper Cable Lengths

Cable Type Maximum Cable Length Connector

1000BASE-T

Category 5, 5e, or 6 100-ohm UTP or STP 100 m (328 ft) RJ-45

100BASE-TX

Category 5 or better 100-ohm UTP or STP 100 m (328 ft) RJ-45

10BASE-T

Category 3 or better 100-ohm UTP 100 m (328 ft) RJ-45

– 37 –

Chapter 5

1

1

How to Connect to the Twisted-Pair Copper Management Port

| Port Connections

Copper Cabling

Guidelines

1000BASE-T Pin

Assignments

To ensure proper operation when installing the switch into a network, make sure
that the current cable is suitable for 10BASE-T, 100BASE-TX or 1000BASE-T
operation. Check the following criteria against the current installation of your
network:

◆ Cable type: Unshielded twisted pair (UTP) or a shielded twisted pair (STP) cable

with RJ-45 connectors; Category 3 or better for 10BASE-T, Category 5 or better
for 100BASE-TX, and Category 5, 5e or 6 for 1000BASE-T.

◆ Protection from radio frequency interference emissions

◆ Electrical surge suppression

◆ Separation of electrical wires (switch related or other) and electromagnetic

fields from data based network wiring

◆ Safe connections with no damaged cables, connectors or shields

The 1000BASE-T management port supports automatic MDI/MDI-X operation, so
you can use straight-through cables for all network connections to PCs, servers, or
switches.

Figure 22: RJ-45 Connector

RJ-45 Pin Numbers

The table below shows the 1000BASE-T MDI and MDI-X port pinouts for the RJ-45
connector shown in Figure 22. The port require that all four pairs of wires be
connected. Note that for 1000BASE-T operation, all four pairs of wires are used for
both transmit and receive.

Table 5: 1000BASE-T MDI and MDI-X Port Pinouts

Pin MDI Signal Name MDI-X Signal Name

1 Bi-directional Pair A Plus (BI_DA+) Bi-directional Pair B Plus (BI_DB+)

2 Bi-directional Pair A Minus (BI_DA-) Bi-directional Pair B Minus (BI_DB-)

– 38 –

Chapter 5

How to Connect to SFP/SFP+ Fiber Optic Ports

| Port Connections

Table 5: 1000BASE-T MDI and MDI-X Port Pinouts (Continued)

Pin MDI Signal Name MDI-X Signal Name

3 Bi-directional Pair B Plus (BI_DB+) Bi-directional Pair A Plus (BI_DA+)

4 Bi-directional Pair C Plus (BI_DC+) Bi-directional Pair D Plus (BI_DD+)

5 Bi-directional Pair C Minus (BI_DC-) Bi-directional Pair D Minus (BI_DD-)

6 Bi-directional Pair B Minus (BI_DB-) Bi-directional Pair A Minus (BI_DA-)

7 Bi-directional Pair D Plus (BI_DD+) Bi-directional Pair C Plus (BI_DC+)

8 Bi-directional Pair D Minus (BI_DD-) Bi-directional Pair C Minus (BI_DC-)

1000BASE-T Cable Requirements

All Category 5 UTP cables that are used for a 100BASE-TX connection should also
work for 1000BASE-T, providing that all four wire pairs are connected. However, it is
recommended that for all critical connections, or any new cable installations,
Category 5e (enhanced Category 5) or Category 6 cable should be used. The
Category 5e and 6 specifications include test parameters that are only
recommendations for Category 5. Therefore, the first step in preparing existing
Category 5 cabling for running 1000BASE-T is a simple test of the cable installation
to be sure that it complies with the IEEE 802.3-2008 standards.

Connection Procedure To make a connection to the switch’s management port follow the procedure

described in “How to Connect to the Management Port” on page 49.

How to Connect to SFP/SFP+ Fiber Optic Ports

The switch provides 48 slots for SFP/SFP+ fiber-optic transceivers. Note that all 10G
SFP+ fiber optic ports operate at 10 Gbps full duplex. All 1000 Mbps SFP fiber optic
ports operate at 1 Gbps full duplex.

Table 6: Maximum 10 Gigabit Ethernet Fiber Cable Lengths

Fiber Size Fiber Bandwidth Maximum Cable Length Connector

10GBASE-SR

62.5/125 micron multimode 160 MHz/km 2-26 m (7-85 ft.) LC

62.5/125 micron multimode 200 MHz/km 2-33 m (7-108 ft.) LC

50/125 micron multimode 400 MHz/km 2-66 m (7-216 ft.) LC

50/125 micron multimode 500 MHz/km 2-82 m (7-269 ft.) LC

50/125 micron multimode 2000 MHz/km 2-300 m (7-984 ft.) LC

10GBASE-LR

9/125 micron single-mode N/A 10 km (6.2 miles) LC

– 39 –

Chapter 5

How to Connect to SFP/SFP+ Fiber Optic Ports

| Port Connections

Table 6: Maximum 10 Gigabit Ethernet Fiber Cable Lengths (Continued)

Fiber Size Fiber Bandwidth Maximum Cable Length Connector

10GBASE-LRM

62.5/125 micron multimode N.A 220 m (722 ft.) LC

50/125 micron multimode N/A 220 m (722 ft.) LC

9/125 micron single-mode N/A 300 m (722 ft.) LC

Table 7: Maximum Gigabit Ethernet Fiber Cable Lengths

Cable Type Fiber Bandwidth Maximum Cable Length Connector

1000BASE-SX

62.5/125 micron multimode 160 MHz/km 2-220 m (7-722 ft) LC

50/125 micron multimode 400 MHz/km 2-500 m (7-1641 ft) LC

200 MHz/km 2-275 m (7-902 ft) LC

500 MHz/km 2-550 m (7-1805 ft) LC

1000BASE-LX

9/125 micron single-mode N/A 2 m - 10 km

Note:

The length of fiber optic cable for a single switched link should not exceed

(7 ft - 6.2 miles)

the relevant standards specified in this section. However, power budget constraints
should also be considered when calculating the maximum fiber optic cable length
for a particular link.

Connection Procedure Follow these steps to connect cables to SFP/SFP+ transceiver ports.

Warning:

lasers are compliant with the requirements of a Class 1 Laser Product and are
inherently eye safe in normal operation. However, you should never look directly at
a transmit port when it is powered on.

Warning:

sure that it can function at a temperature that is not less than the recommended
maximum operational temperature of the product. You must also use an approved
Laser Class 1 SFP/SFP+ transceiver.

This switch uses lasers to transmit signals over fiber optic cable. The

When selecting a fiber SFP/SFP+ device, considering safety, please make

LC

1. Remove and keep the fiber port’s rubber cover. When not connected to a fiber

cable, the rubber cover should be replaced to protect the optics.

– 40 –

Chapter 5

2

1

1

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How to Connect to SFP/SFP+ Fiber Optic Ports

| Port Connections

2. Check that the fiber terminators are clean. You can clean the cable plugs by

wiping them gently with a clean tissue or cotton ball moistened with a little
ethanol. Dirty fiber terminators on fiber cables will impair the quality of the
light transmitted through the cable and lead to degraded performance on the
port.

3. Connect one end of the cable to the LC connector on one of the switch’s SFP

transceivers and the other end to the LC port on the other device. Since both LC
connectors are keyed, the cable can only be attached in the correct orientation.

Figure 23: Making Connections to an SFP+ Transceiver

SFP+ Transceiver Fiber Optic Cable

4. As a connection is made, check the Link LED on the switch corresponding to

the port to be sure that the connection is valid.

Note:

Be sure to secure cables properly and route them away from the switch
without exceeding the minimum bending radius for fiber cables (typically a few
inches). Use cable ties to bundle cables together and secure coiled loops of excess
cable. Do not let cables hang free supporting their own weight or pull in any way
that puts stress on the connectors.

– 41 –

Chapter 5

How to Connect to QSFP+ Fiber Optic Ports

| Port Connections

How to Connect to QSFP+ Fiber Optic Ports

The switch includes four slots for 40 Gigabit Ethernet QSFP+ fiber-optic
transceivers. Note that 40G fiber optic ports can provide either one 40 Gbps full­duplex link, four independent 10G fiber optic links. Connecting a 40G QSFP+ port
to four 10G SFP+ ports requires the use of a breakout cable.

Table 8: Maximum 40 Gigabit Ethernet Fiber Cable Lengths

Fiber Size Fiber Bandwidth Maximum Cable Length Connector

40GBASE-SR4

62.5/125 micron multimode 160 MHz/km 2-26 m (7-85 ft.) LC

62.5/125 micron multimode 200 MHz/km 2-33 m (7-108 ft.) LC

50/125 micron multimode 400 MHz/km 2-66 m (7-216 ft.) LC

50/125 micron multimode 500 MHz/km 2-82 m (7-269 ft.) LC

50/125 micron multimode 2000 MHz/km 2-300 m (7-984 ft.) LC

Note:

The length of fiber optic cable for a single switched link should not exceed
the relevant standards specified in this section. However, power budget constraints
should also be considered when calculating the maximum fiber optic cable length
for a particular link.

Connection Procedure Follow these steps to connect cables to QSFP+ transceiver ports.

Warning:

lasers are compliant with the requirements of a Class 1 Laser Product and are
inherently eye safe in normal operation. However, you should never look directly at
a transmit port when it is powered on.

Warning:

sure that it can function at a temperature that is not less than the recommended
maximum operational temperature of the product. You must also use an approved
Laser Class 1 QSFP+ transceiver.

This switch uses lasers to transmit signals over fiber optic cable. The

When selecting a fiber QSFP+ device, considering safety, please make

1. Remove and keep the port’s protective cover. When not connected to a fiber

cable, the cover should be replaced to protect the optics.

2. Check that the fiber terminators are clean. You can clean the cable plugs by

wiping them gently with a clean tissue or cotton ball moistened with a little
ethanol. Dirty fiber terminators on fiber cables will impair the quality of the
light transmitted through the cable and lead to degraded performance on the
port.

– 42 –

Chapter 5

1

2

1

2

How to Connect to QSFP+ Fiber Optic Ports

| Port Connections

3. Connect one end of the cable to the QSFP+ port on the switch and the other

end to the QSFP+ port on the other device. Since QSFP+ connectors are keyed,
the cable can only be attached in the correct orientation.

Figure 24: Connecting to a QSFP+ Transceiver

QSFP+ Transceiver Port QSFP+ Fiber Optic Cable

4. As a connection is made, check the Link LED on the switch to be sure that the

connection is valid.

Note:

Be sure to secure cables properly and route them away from the switch
without exceeding the minimum bending radius for fiber cables (typically a few
inches). Use cable ties to bundle cables together and secure coiled loops of excess
cable. Do not let cables hang free supporting their own weight or pull in any way
that puts stress on the connectors.

– 43 –

Chapter 5

DAC Connections

| Port Connections

DAC Connections

Direct Attach Cable (DAC) is a method of connecting two SFP+/QSFP+ interfaces
without using optics and fiber cable. A fixed length of twinax copper cable is
terminated at each end with physically-compliant SFP+/QSFP+ transceivers that do
not include all their normal electronic and optical components. The result is a low
cost, low-latency, 10G/40G Ethernet solution for short distances, ideal for
connections within the data center.

A 10G DAC connection is also known as twinax copper or 10GBASE-CR. DAC copper
cables are available in pre-terminated lengths up to 10 m (32.8 ft).

For 40G DAC, or 40GBASE-CR4, copper cables are also available in pre-terminated
lengths up to 10 m (30 ft).

Table 9: Maximum 10GBASE-CR 10 Gigabit Ethernet Cable Lengths

Cable Type Cable Lengths Connector

Making DAC

Connections

Pre-terminated Direct Attach Cable
(DAC) — (twinax copper cable)

1 m (3.28 ft)
2 m (6.56 ft)
3 m (9.8 ft)
5 m (16.4 ft)

SFP+

Table 10: Maximum 40GBASE-CR4 40 Gigabit Ethernet Cable Lengths

Cable Type Cable Lengths Connector

Pre-terminated Direct Attach Cable
(DAC) — (twinax copper cable)

Up to 10 M QSFP+

1. Plug the SFP+/QSFP+ transceiver connector on one end of a twinax copper

cable segment into an SFP+/QSFP+ slot on the link device.

– 44 –

Figure 25: Making DAC Connections

1

1

10G SFP+ DAC Cable

Chapter 5

| Port Connections

DAC Connections

2. Plug the other end of the twinax cable into an SFP+/QSFP+ slot on the switch.

3. Check that the Link LED on the switch turns on green to indicate that the

connection is valid.

Note:

Connecting a 40G QSFP+ port to four 10G SFP+ ports requires the use of a
breakout DAC cable.

– 45 –

Chapter 5

| Port Connections

DAC Connections

– 46 –

6 Switch Management

The switch includes a management agent that allows you to configure or monitor
the switch using its embedded management software. To manage the switch, you
can make a direct connection to the console port (out-of-band), or you can manage
it through a network connection (in-band) using Telnet, Secure Shell (SSH), a web
browser, or SNMP-based network management software.

The switch’s Management port (RJ-45) provides a dedicated management channel
that operates outside of the data transport network. This makes it possible to re­configure or troubleshoot the switch over either a local or remote connection to
the Management port when access through the data channel is not possible or
deemed insecure.

For a detailed description of the switch’s software features, refer to the
Administrator’s Guide.

This chapter includes these sections:

◆ “Understanding the System Status LEDs” on page 48

◆ “How to Connect to the Management Port” on page 49

◆ “How to Connect to the Console Port” on page 50

◆ “How to Connect to the USB Port” on page 52

◆ “How to Reset the Switch” on page 53

– 47 –

Chapter 6

1

1

| Switch Management

Understanding the System Status LEDs

Understanding the System Status LEDs

The switch includes a display panel of key system LED indicators. The LEDs, which
are located on the front panel, are shown below and described in the following
table.

Figure 26: System LEDs

System Status LEDs.

Table 11: System Status LEDs

LED Condition Status

PSU1/PSU2 On Green Power supply 1/2 is installed and operating normally.

On Amber The power supply has detected a fault.

Off The power supply unit is not installed.

Diag On Green The system diagnostic test has completed successfully.

On Amber The system self-diagnostic test has detected a fault.

Fan On Green Fans are operating normally.

On Amber A fan failure has been detected.

Loc Flashing Amber Activated through remote software to assist identification

of the switch unit within a rack.

– 48 –

How to Connect to the Management Port

3

1

2

132

The 10/100/1000BASE-T port labeled “Mgmt” provides a dedicated management
interface which is segregated from the data traffic crossing the other ports.

This port supports auto-negotiation, so the optimum transmission mode (half or
full duplex) and data rate (10, 100, or 1000 Mbps) can be selected automatically, if
this feature is also supported by the attached device.

Figure 27: Management Port

Chapter 6

How to Connect to the Management Port

| Switch Management

Link/Activity LED RJ-45 Management Port

Speed LED

Table 12: RJ-45 Management Port Status LEDs

LED Condition Status

Link/Activity On/Flashing Green Port has established a valid network connection.

Off There is no valid link on the port.

Speed On Amber Valid 1000 Mbps link

On Green Valid 10/100 Mbps link

Flashing indicates activity.

To connect to the management port, use Category 5 or better unshielded twisted­pair (UTP) cable with RJ-45 connectors at both ends. Make sure the twisted-pair
cable does not exceed 100 meters (328 ft) in length. This port supports automatic
MDI/MDI-X pinout configuration, so you can use standard straight-through cables
to connect to any other network device.

– 49 –

Chapter 6

1

1

How to Connect to the Console Port

| Switch Management

Follow these steps to connect to the Management port:

1. Attach one end of a twisted-pair cable to an RJ-45 connector on a management

network device (PC or another switch).

2. Attach the other end of the twisted-pair cable to the Management port on the

switch.

3. As the connection is made, the Mgmt port LEDs (on the switch) will turn on to

indicate that the connection is valid.

How to Connect to the Console Port

The RJ-45 Console port on the switch’s front panel is used to connect to the switch
for out-of-band console configuration. The console device can be a PC or
workstation running a VT-100 terminal emulator, or a VT-100 terminal. An RJ-45-to­DB-9 cable is supplied with the switch for connecting to a PC’s RS-232 serial DB-9
DTE (COM) port.

Note:

To connect to notebooks or other PCs that do not have a DB-9 COM port, use
a USB to male DB-9 adapter cable (not included with the switch).

Figure 28: Console Port

Console Port

– 50 –

Chapter 6

How to Connect to the Console Port

| Switch Management

The following table describes the pin assignments used in the RJ-45-to-DB-9
console cable.

Table 13: Console Cable Wiring

Switch’s 8-Pin
Console Port

6 RXD (receive data) <--------------------- 3 TXD (transmit data)

3 TXD (transmit data) ---------------------> 2 RXD (receive data)

5 SGND (signal ground) ----------------------- 5 SGND (signal ground)

No other pins are used.

Null Modem PC’s 9-Pin

DTE Port

The serial port’s configuration requirements are as follows:

◆ Default Baud rate—9600 bps

◆ Character Size—8 Characters

◆ Parity—None

◆ Stop bit—One

◆ Data bits—8

◆ Flow control—none

Figure 29: Console Port Connection

Follow these steps to connect to the Console port:

1. Attach the DB-9 end of the included RJ-45-to-DB-9 serial cable to a DB-9 COM

port connector on a management PC.

– 51 –

Chapter 6

1

1

How to Connect to the USB Port

| Switch Management

2. Attach the RJ-45 end of the serial cable to the Console port on the switch.

3. Configure the PC’s COM port required settings using VT-100 terminal emulator

software (such as HyperTerminal) running on the management PC.

4. Log in to the command-line interface (CLI) using default settings:

■

User — admin

■

Password — null (there is no default password)

For a detailed description of connecting to the console and using the switch’s
command line interface (CLI), refer to the Administrator’s Guide.

How to Connect to the USB Port

The USB port on the switch front panel is for transferring configuration files from a
USB storage device to the switch’s flash memory.

Figure 30: USB Port

USB Port

– 52 –

How to Reset the Switch

1

1

The Reset button on the switch can be used to restart the device and set the
configuration back to factory default values.

Use a long thin object, such as the end of a paperclip, to depress the Reset button.
One push of the button restarts the system software using default values.

Figure 31: Reset Button

Chapter 6

| Switch Management

How to Reset the Switch

Reset Button

– 53 –

A Troubleshooting

Diagnosing LED Indicators

Table 14: Troubleshooting Chart

Symptom Action

PSU1/PSU2 LED is Off

PSU1/PSU2 LED is on
Amber

Diag LED is on Amber

Fan LED is on Amber

Link/Act LED is Off

◆

Check connections between the PSU, the power cord and the wall
outlet.

◆

Contact your dealer for assistance.

◆

Power cycle the PSU to try and clear the condition.

◆

Replace the PSU.

◆

Power cycle the switch to try and clear the condition.

◆

If the condition does not clear, contact your dealer for assistance.

◆

Check fans in the fan tray.

◆

Replace the fan tray as soon as possible.

◆

Verify that the switch and attached device are powered on.

◆

Be sure the cable is plugged into both the switch and
corresponding device.

◆

Verify that the proper cable type is used and its length does not
exceed specified limits.

◆

Check the attached device and cable connections for possible
defects. Replace the defective cable if necessary.

System Self-Diagnostic Test Failure

If the Diag LED indicates a failure of the system power-on-self-test (POST), you can
use a console connection to view the POST results. The POST results may indicate a
failed component or help troubleshoot the problem. For more information on
connecting to the console port and using the CLI, refer to the Administrator’s Guide.

Note a POST failure normally indicates a serious hardware fault that cannot be
rectified or worked around. If you encounter a POST failure, you should contact
your dealer for assistance.

– 54 –

Power and Cooling Problems

If a power indicator does not turn on when the power cord is plugged in, you may
have a problem with the power outlet, power cord, or PSU. However, if the switch
powers off after running for a while, check for loose power connections, power
losses or surges at the power outlet. If you still cannot isolate the problem, the PSU
may be defective.

Installation

Verify that all system components have been properly installed. If one or more
components appear to be malfunctioning (such as the power cord or network
cabling), test them in an alternate environment where you are sure that all the
other components are functioning properly.

Chapter A

Power and Cooling Problems

| Troubleshooting

In-Band Access

You can access the management agent in the switch through a connection to any
port using Telnet, a web browser, or other network management software tools.
However, you must first configure the switch with a valid IP address, subnet mask,
and default gateway. If you have trouble establishing a link to the management
agent, check to see if you have a valid network connection. Then verify that you
entered the correct IP address. Also, be sure the switch port has not been disabled.
If it has not been disabled, then check the network cabling that runs between your
remote location and the switch.

– 55 –

Index

Numerics

1000BASE-SX fiber cable Lengths 40
1000BASE-T PIN assignments
10GBASE fiber cable lengths
10GBASE-LR fiber cable lengths

38

39, 42

44

A

air flow requirements 23

B

brackets, attaching 25
buffer size

13

C

cable

Ethernet cable compatibility
labeling and connection records

lengths
cleaning fiber terminators
console port

pin assignments
console port, pin assignments
contents of package
cord sets, international
Craft port

39, 42

49, 50

18

32

47

38

40, 42

50

D

diagnosing LED indicators 54

E

electrical interference, avoiding 23
equipment checklist

18

34

installation

power requirements

site requirements
installation troubleshooting
introduction

10, 18

23

23

55

L

laser safety 40, 42
LC port connections
LED indicators

DIAG

48

port

35

power

30

PWR

48

location requirements

39

23

M

management

Craft port

out-of-band

web-based

47

47

47

O

out-of-band management 47

P

package contents 18
pin assignments

console port
power

indicators

modules
power and cooling problems

49, 50

30

29

55

F

fan tray 27

I

in-band access 55
indicators, LED

35, 48

R

rear panel socket 29

S

screws for rack mounting 24
SFP

transceiver connections

– 56 –

39

site selelction 23
specifications

environmental
status LEDs
surge suppressor, using

35, 48

13

23

W

web-based management 47

Index

– 57 –

Declaration of Conformity (DoC) can be obtained from www.edge-core.com

-> support -> download -> declarations & certifications

ECS5610-52S
E062013-KS-R01
150200000495A