KSZ8842-16MQL Micrel Inc, KSZ8842-16MQL Datasheet - Page 32

KSZ8842-16MQL

Manufacturer Part Number

KSZ8842-16MQL

Description

IC SWITCH 10/100 16BIT 128PQFP

Manufacturer

Micrel Inc

Datasheets

1.KSZ8841-PMQLI.pdf (2 pages)

2.KSZ8842-16MQL.pdf (126 pages)

3.KSZ8842-16MQL.pdf (141 pages)

Specifications of KSZ8842-16MQL

Data Rate

100Mbps

Controller Type

Ethernet Switch Controller

Interface

PCI

Voltage - Supply

3.1 V ~ 3.5 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

128-MQFP, 128-PQFP

No. Of Ports

Ethernet Type

IEEE 802.3u

Supply Current

122mA

Supply Voltage Range

3.1V To 3.5V

Operating Temperature Range

0Â°C To +70Â°C

Digital Ic Case Style

QFP

No. Of

RoHS Compliant

Number Of Primary Switch Ports

Internal Memory Buffer Size

Operating Supply Voltage (typ)

3.3V

Fiber Support

Yes

Integrated Led Drivers

Yes

Phy/transceiver Interface

MII

Power Supply Type

Analog/Digital

Package Type

PQFP

Data Rate (typ)

10/100Mbps

Vlan Support

Yes

Operating Temperature (max)

70C

Operating Temperature (min)

Pin Count

128

Mounting

Surface Mount

Jtag Support

Operating Supply Voltage (max)

3.5V

Operating Supply Voltage (min)

3.1V

Operating Temperature Classification

Commercial

Interface Type

PCI

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

576-1634 - BOARD EVALUATION KSZ8842-16MQL

Current - Supply

Lead Free Status / RoHS Status

Compliant, Lead free / RoHS Compliant

Other names

576-1478-5

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

KSZ8842-16MQL

Manufacturer:

Micrel Inc

Quantity:

10 000

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

KSZ8842-16MQLI

Manufacturer:

MICREL

Quantity:

760

Current page: 32 of 126
Download datasheet (2Mb)

Regardless of whether the transfer is synchronous or asynchronous, if the address latch is required, use the rising edge of

ADSN to latch the incoming signals A [15:1], AEN, BE3N, BE2N, BE1N, and BE0N.

Note: Whether the transfer is synchronous or asynchronous, if the local device decoder is used, LDEVN will be asserted

to indicate that the KSZ8842M is successfully targeted. Basically, signal LDEVN is a combinatorial decode of AEN and

A[15:4].

Asynchronous Interface

For asynchronous transfers, the asynchronous dedicated signals RDN (for read) or WRN (for write) toggle, but the

synchronous dedicated signals BCLK, CYCLEN, SWR, and RDYRTNN are de-asserted and stay at the same logic level

throughout the entire asynchronous transfer.

There is no data burst support for asynchronous transfer. All asynchronous transfers are single-data transfers. The BIU,

however, provides flexible asynchronous interfacing to communicate with various applications and architectures. Three

major ways of interfacing with the system (host) are.

1. Interfacing with the system/host relying on local device decoding and having stable address throughout the whole

2. Interfacing with the system/host relying on local device decoding but not having stable address throughout the entire

3. Interfacing with the system/host relying on central decoding (KSZ8842-32 mode only).

Micrel Confidential

November 2005

transfer:

The typical example for this application is ISA-like bus interface using latched address signals as shown in the Figure

16. No additional address latch is required, therefore ADSN should be connected Low. The BIU decodes A[15:4] and

qualifies with AEN (Address Enable) to determine if the KSZ8842M switch is the intended target. The host utilizes the

rising edge of RDN to latch read data and the BIU will use rising edge of WRN to latch write data.

transfer: the typical example for this application is EISA-like bus (non-burst) interface as shown in the Figure 17. This

type of interface requires ADSN to latch the address on the rising edge. The BIU decodes latched A[15:4] and

qualifies with AEN to determine if the KSZ8842M switch is the intended target. The data transfer is the same as the

first case.

CYCLEN

SWR

SRDYN

RDYRTNN

BCLK

Asynchronous Transfer Signals

RDN

WRN

ARDY

Note 1: I = Input. O = Output. I/O = Bi-directional.

VLBUSN = 1, burst cycle (both host/system and KSZ8842 can insert wait state)

For VLBus-like access: used to sample SWR when asserted.

For burst access: used to connect to IOWC# bus signal to indicate burst write.

Write/Read

For VLBus-like access: used to indicate write (High) or read (Low) transfer.

For burst access: used to connect to IORC# bus signal to indicate burst read.

Synchronous Ready

For VLBus-like access: exactly the same signal definition of nSRDY in VLBus.

For burst access: insert wait state by the KSZ8842M whenever necessary

during the Data Register access.

Ready Return

For VLBus-like access: exactly like RDYRTNN signal in VLBus to end the

cycle.

For burst access: exactly like EXRDY signal in EISA to insert wait states. Note

that the wait states are inserted by system logic (memory) not by KSZ8842M.

Bus Clock

Asynchronous Read

Asynchronous Write

Asynchronous Ready

This signal is asserted (low) to insert wait states.

Table 2. Bus Interface Unit Signal Grouping

KSZ8842-16/32 MQL/MVL

Rev. 1.4

KSZ8842-16MQL Micrel Inc, KSZ8842-16MQL Datasheet - Page 32

KSZ8842-16MQL

Specifications of KSZ8842-16MQL

Available stocks

Related parts for KSZ8842-16MQL