Tables (continued)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 7-14:

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Set FRU LED State Command.

Table 7-15:

Get FRU LED State Command

. .7-22

Table 7-16:

Vendor Command Summary

. .7-24

Table 7-17:

Get Status Command

. .7-25

Table 7-18:

Get Serial Interface Properties Command

. .7-27

Table 7-19:

Set Serial Interface Properties Command

. .7-28

Table 7-20:

Get Debug Level Command

. .7-29

Table 7-21:

Set Debug Level Command

. .7-29

Table 7-22:

Get Hardware Address Command

. .7-30

Table 7-23:

Set Hardware Address Command

. .7-30

Table 7-24:

Get Handle Switch Command

. .7-31

Table 7-25:

Set Handle Switch Command

. .7-31

Table 7-26:

Get Payload Communication Time-Out Command . . .

. .7-32

Table 7-27:

Set Payload Communication Time-Out Command . . .

. .7-32

Table 7-28:

Enable Payload Control Command

. .7-32

Table 7-29:

Disable Payload Control Command

. .7-33

Table 7-30:

Reset IPMC Command

. .7-33

Table 7-31:

Hang IPMC Command

. .7-33

Table 7-32:

Bused Resource Command

. .7-34

Table 7-33:

Bused Resource Status Command

. .7-35

Table 7-34:

Graceful Reset Command

. .7-36

Table 7-35:

Diagnostic Interrupt Command

. .7-36

Table 7-36:

Get Payload Shutdown Time-Out Command

. .7-37

Table 7-37:

Set Payload Shutdown Time-Out Command

. .7-37

Table 7-38:

Set Local FRU LED State Command

. .7-38

Table 7-39:

Get Local FRU LED State Command

. .7-39

Table 7-40:

Update Discrete Sensor Command

. .7-40

Table 7-41:

Update Threshold Sensor Command

. .7-40

Table 7-42:

Add Message Listener Command

. .7-44

Table 7-43:

Remove Message Listener Command

. .7-44

Table 7-44:

Get Message Listener List Command

. .7-45

Table 7-45:

Update System Firmware Progress Sensor Command .

. .7-46

Table 7-46:

IPMI Threshold Sensors

. .7-48

Table 7-47:

IPMI Discrete Sensors

. .7-48

Table 7-48:

Event Message Format

. .7-49

Table 7-49:

FRU Definition

. .7-50

Table 7-50:

Link Description

. .7-52

Table 7-51:

IPMP CPLD JP1 Pin Assignments

. .7-53

Table 7-52:

IPMP EIA-232 P4 Pin Assignments

. .7-53

Table 8-1:

Zone 1 Connector, P10 Pin Assignments

. .8-1

Table 8-2:

Zone 2 Connector, J23 Pin Assignments

. .8-3

xii

ATCA-9305 User’s Manual

10009109-01

Page 14
Image 14
Emerson ATCA-9305 user manual Tables

ATCA-9305 specifications

The Emerson ATCA-9305 is a high-performance AdvancedTCA (ATCA) chassis designed to meet the demanding requirements of telecommunications and IT infrastructure. With a focus on scalability, reliability, and flexibility, this equipment is ideal for service providers and enterprises looking to deploy robust applications in a variety of environments.

One of the main features of the ATCA-9305 is its support for high-density blade configurations. The chassis can accommodate up to 14 ATCA blades, enabling the deployment of powerful processing units, communication modules, and storage solutions. This level of density not only maximizes space but also minimizes power consumption, which is crucial for reducing operational costs in large-scale deployments.

The ATCA-9305 is built with a focus on advanced thermal management and redundancy. It employs a sophisticated cooling architecture that ensures optimal airflow across the chassis, preventing overheating during operation. Additionally, the chassis features hot-swappable fans and power supplies, which means that components can be replaced without interrupting the overall system performance. This capability enhances uptime and reliability, which is essential for mission-critical applications.

Another notable characteristic of the ATCA-9305 is its support for various interconnect technologies. The chassis provides robust backplane options that facilitate high-bandwidth communication between blades. It supports Ethernet, PCI Express, and Serial RapidIO, allowing for seamless integration with existing infrastructure and future technologies. This flexibility enables organizations to adapt to changing market demands and technological advancements.

Security features are also a prominent aspect of the ATCA-9305. The chassis incorporates hardware-based security modules that enhance data integrity and protect sensitive information. This is particularly important for service providers who must adhere to strict regulatory compliance standards.

In terms of management and monitoring, the ATCA-9305 is equipped with advanced management capabilities. It supports AdvancedTCA Management Interface (IPMI) and other monitoring protocols, allowing administrators to easily oversee the health and performance of the entire system. This level of visibility aids in proactive maintenance and troubleshooting, effectively reducing downtime.

In conclusion, the Emerson ATCA-9305 is a powerful and versatile chassis that stands out due to its high-density configuration, advanced thermal management, diverse interconnect technology support, robust security features, and comprehensive management capabilities. Its design is tailored for the evolving needs of telecommunications and data center environments, making it a valuable asset for any organization looking to enhance its infrastructure.