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89HPES16NT2ZBBC: 产品描述PCI Bus Controller, PBGA484, 23 X 23 MM, 1 MM PITCH, CABGA-484; 产品类别嵌入式处理器和控制器微控制器和处理器; 文件大小434KB，共29页; 制造商IDT (Integrated Device Technology)

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89HPES16NT2ZBBC概述

PCI Bus Controller, PBGA484, 23 X 23 MM, 1 MM PITCH, CABGA-484

89HPES16NT2ZBBC规格参数

参数名称	属性值
是否无铅	含铅
是否Rohs认证	不符合
厂商名称	IDT (Integrated Device Technology)
零件包装代码	BGA
包装说明	CABGA-484
针数	484
Reach Compliance Code	not_compliant
ECCN代码	EAR99
地址总线宽度
总线兼容性	PCI
最大时钟频率	125 MHz
外部数据总线宽度
JESD-30 代码	S-PBGA-B484
JESD-609代码	e0
长度	23 mm
湿度敏感等级	3
端子数量	484
最高工作温度	70 °C
最低工作温度
封装主体材料	PLASTIC/EPOXY
封装代码	BGA
封装等效代码	BGA484,22X22,40
封装形状	SQUARE
封装形式	GRID ARRAY
峰值回流温度（摄氏度）	225
电源	1,3.3 V
认证状态	Not Qualified
座面最大高度	1.86 mm
最大供电电压	1.1 V
最小供电电压	0.9 V
标称供电电压	1 V
表面贴装	YES
技术	CMOS
温度等级	COMMERCIAL
端子面层	Tin/Lead (Sn63Pb37)
端子形式	BALL
端子节距	1 mm
端子位置	BOTTOM
处于峰值回流温度下的最长时间	20
宽度	23 mm
uPs/uCs/外围集成电路类型	BUS CONTROLLER, PCI

89HPES16NT2ZBBC文档预览

16-Lane 2-Port Non-Transparent

PCI Express® Switch

89HPES16NT2

Data Sheet

Device Overview

The 89HPES16NT2 is a member of the IDT PRECISE™ family of

PCI Express® switching solutions offering the next-generation I/O inter-

connect standard. The PES16NT2 is a 16-lane, 2-port peripheral chip

that provides high-performance switching and non-transparent bridging

(NTB) functions between a PCIe® upstream port and an NTB down-

stream port. The PES16NT2 is a part of the IDT PCIe System Intercon-

nect Products and is intended to be used with IDT PCIe System

Interconnect Switches. Together, the chipset targets multi-host and intel-

ligent I/O applications such as communications, storage, and blade

servers where inter-domain communication is required.

Features

High Performance PCI Express Switch

–

Sixteen PCI Express lanes (2.5Gbps), two switch ports

–

Delivers 64 Gbps (8 GBps) of aggregate switching capacity

–

Low latency cut-through switch architecture

–

Support for Max Payload size up to 2048 bytes

–

Supports one virtual channel and eight traffic classes

–

PCI Express Base specification Revision 1.0a compliant

◆

Flexible Architecture with Numerous Configuration Options

–

Supports automatic per port link width negotiation (x8, x4, x2,

or x1)

–

Static lane reversal on all ports

–

Automatic polarity inversion on all lanes

◆

–

Supports locked transactions, allowing use with legacy soft-

ware

–

Ability to load device configuration from serial EEPROM

–

Ability to control device via SMBus

◆

Non-Transparent Port

–

Crosslink support on NTB port

–

Four mapping windows supported

•

Each may be configured as a 32-bit memory or I/O window

•

May be paired to form a 64-bit memory window

–

Interprocessor communication

•

Thirty-two inbound and outbound doorbells

•

Four inbound and outbound message registers

•

Two shared scratchpad registers

–

Allows up to sixteen masters to communicate through the non-

transparent port

–

No limit on the number of supported outstanding transactions

through the non-transparent bridge

–

Completely symmetric non-transparent bridge operation

allows similar/same configuration software to be run

–

Supports direct connection to a transparent or non-transparent

port of another switch

◆

Highly Integrated Solution

–

Requires no external components

–

Incorporates on-chip internal memory for packet buffering and

queueing

–

Integrates sixteen 2.5 Gbps embedded full duplex SerDes, 8B/

10B encoder/decoder (no separate transceivers needed)

Block Diagram

2-Port Switch Core

Frame Buffer

Route Table

Port

Arbitration

Scheduler

Transaction Layer

Data Link Layer

Transaction Layer

Data Link Layer

Non-

Transparent

Bridge

Multiplexer / Demultiplexer

Phy

Logical

Layer

Phy

Logical

Layer

Phy

Logical

Layer

Multiplexer / Demultiplexer

Phy

Logical

Layer

Phy

Logical

Layer

Phy

Logical

Layer

...

SerDes

16 PCI Express Lanes

x8 Upstream Port and One x8 Downstream Port

Figure 1 Internal Block Diagram

IDT and the IDT logo are registered trademarks of Integrated Device Technology, Inc.

1 of 29

2009 Integrated Device Technology, Inc.

January 5, 2009

DSC 6925

IDT 89HPES16NT2 Data Sheet

Reliability, Availability, and Serviceability (RAS) Features

–

Internal end-to-end parity protection on all TLPs ensures data

integrity even in systems that do not implement end-to-end

CRC (ECRC)

–

Supports ECRC pass-through

–

Supports Hot-Swap

◆

Power Management

–

Supports PCI Power Management Interface specification,

Revision 1.1 (PCI-PM)

–

Unused SerDes are disabled

◆

Testability and Debug Features

–

Built in SerDes Pseudo-Random Bit Stream (PRBS) generator

–

Ability to read and write any internal register via the SMBus

–

Ability to bypass link training and force any link into any mode

–

Provides statistics and performance counters

◆

Two SMBus Interfaces

–

Slave interface provides full access to all software-visible

registers by an external SMBus master

–

Master interface provides connection for an optional serial

EEPROM used for initialization

–

Master and slave interfaces may be tied together so the switch

can act as both master and slave

◆

Eight General Purpose Input/Output pins

◆

Packaged in a 23mm x 23mm 484-ball BCG with 1mm ball

spacing

◆

Switch Configuration

The PES16NT2 is a two port switch that contains sixteen PCI

Express lanes. Each of the two ports is statically allocated eight lanes

with ports labeled as A and C. Port A is the upstream port and port C is

the non-transparent downstream port.

During link training, link width is automatically negotiated. Each

PES16NT2 port is capable of independently negotiating to a x8, x4, x2,

or x1 width. Thus, the PES16NT2 may be used in virtually any two port

switch configuration (e.g., {x8, x8}, {x4, x4}, {x4, x2}, etc.). The

PES16NT2 supports static lane reversal. For example, lane reversal for

upstream port A may be configured by asserting the PCI Express Port A

Lane Reverse (PEALREV) input signal or through serial EEPROM or

SMBus initialization. Lane reversal for port C may be enabled via a

configuration space register, serial EEPROM, or the SMBus.

Product Description

Utilizing standard PCI Express interconnect, the PES16NT2 provides

the most efficient high-performance I/O connectivity solution for applica-

tions requiring high throughput, low latency, and simple board layout

with a minimum number of board layers. With support for non-trans-

parent bridging, the PES16NT2 is part of the IDT PCIe System Intercon-

nect Products that target multi-host and intelligent I/O applications

requiring inter-domain communication. The PES16NT2 provides 64

Gbps (8 GBps) of aggregated, full-duplex switching capacity through 16

integrated serial lanes, using proven and robust IDT technology. Each

lane provides 2.5 Gbps of bandwidth in both directions and is fully

compliant with PCI Express Base specification 1.0a.

The PES16NT2 is based on a flexible and efficient layered architec-

ture. The PCI Express layer consists of SerDes, Physical, Data Link,

and Transaction layers in compliance with PCI Express Base specifica-

tion Revision 1.0a. The PES16NT2 can operate either as a store and

forward or cut-through switch depending on the packet size and is

designed to switch memory and I/O transactions. It supports eight Traffic

Classes (TCs) and one Virtual Channel (VC) with sophisticated resource

management.

2 of 29

January 5, 2009

IDT 89HPES16NT2 Data Sheet

CPU

PES16NT2

CPU

PES16NT2

CPU

PES16NT2

PCIe System Interconnect Switch

Embedded

CPU

Embedded

CPU

SATA / SAS

Embedded

CPU

GbE / 10GigE

Figure 2 PCIe System Interconnect Architecture Block Diagram

Pin Description

The following tables list the functions of the pins provided on the PES16NT2. Some of the functions listed may be multiplexed onto the same pin.

The active polarity of a signal is defined using a suffix. Signals ending with an “N” are defined as being active, or asserted, when at a logic zero (low)

level. All other signals (including clocks, buses, and select lines) will be interpreted as being active, or asserted, when at a logic one (high) level.

Signal

PEALREV

Type

Name/Description

PCI Express Port A Lane Reverse.

When this bit is asserted, the lanes of

PCI Express Port A are reversed. This value may be overridden by modify-

ing the value of the PALREV bit in the PA_SWCTL register.

PCI Express Port A Serial Data Receive.

Differential PCI Express receive

pairs for port A.

PCI Express Port A Serial Data Transmit.

Differential PCI Express trans-

mit pairs for port A

PCI Express Port C Lane Reverse.

When this bit is asserted, the lanes of

PCI Express Port C are reversed. This value may be overridden by modify-

ing the value of the PCLREV bit in the PA_SWCTL register.

PCI Express Port C Serial Data Receive.

Differential PCI Express receive

pairs for port C.

PCI Express Port C Serial Data Transmit.

Differential PCI Express trans-

mit pairs for port C

PCI Express Reference Clock.

Differential reference clock pair input. This

clock is used as the reference clock by on-chip PLLs to generate the clocks

required for the system logic and on-chip SerDes. The frequency of the dif-

ferential reference clock is determined by the REFCLKM signal.

PCI Express Reference Clock Mode Select.

These signals select the fre-

quency of the reference clock input.

0x0 - 100 MHz

0x1 - 125 MHz

Table 1 PCI Express Interface Pins

PEARP[7:0]

PEARN[7:0]

PEATP[7:0]

PEATN[7:0]

PECLREV

PECRP[7:0]

PECRN[7:0]

PECTP[7:0]

PECTN[7:0]

PEREFCLKP[1:0]

PEREFCLKN[1:0]

REFCLKM

3 of 29

January 5, 2009

IDT 89HPES16NT2 Data Sheet

Signal

MSMBADDR[4:1]

MSMBCLK

Type

I/O

Name/Description

Master SMBus Address.

These pins determine the SMBus address of the

serial EEPROM from which configuration information is loaded.

Master SMBus Clock.

This bidirectional signal is used to synchronize

transfers on the master SMBus. It is active and generating the clock only

when the EEPROM is being accessed.

Master SMBus Data.

This bidirectional signal is used for data on the mas-

ter SMBus.

Slave SMBus Address.

These pins determine the SMBus address to

which the slave SMBus interface responds.

Slave SMBus Clock.

This bidirectional signal is used to synchronize trans-

fers on the slave SMBus.

Slave SMBus Data.

This bidirectional signal is used for data on the slave

SMBus.

Table 2 SMBus Interface Pins

MSMBDAT

SSMBADDR[5,3:1]

SSMBCLK

SSMBDAT

I/O

Signal

GPIO[0]

GPIO[1]

Type

I/O

Name/Description

General Purpose I/O.