AM79C973BKC\W AMD (ADVANCED MICRO DEVICES), AM79C973BKC\W Datasheet - Page 71

AM79C973BKC\W

Manufacturer Part Number

AM79C973BKC\W

Description

Manufacturer

AMD (ADVANCED MICRO DEVICES)

Datasheet

1.AM79C973BKCW.pdf (304 pages)

Specifications of AM79C973BKC\W

Operating Supply Voltage (typ)

3.3V

Operating Supply Voltage (min)

3/3.135V

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Pin Count

160

Lead Free Status / RoHS Status

Not Compliant

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Destination Address Handling

The first 6 bytes of information after SFD will be inter-

preted as the destination address field. The MAC en-

gine provides facilities for physical (unicast), logical

(multicast), and broadcast address reception.

Error Detection

The MAC engine provides several facilities which re-

port and recover from errors on the medium. In addi-

tion, it protects the network from gross errors due to

inability of the host to keep pace with the MAC engine

activity.

On completion of transmission, the following transmit

status is available in the appropriate Transmit Message

Descriptor (TMD) and Control and Status Register

(CSR) areas:

In addition to the reporting of network errors, the MAC

engine will also attempt to prevent the creation of any

network error due to the inability of the host to service

the MAC engine. During transmission, if the host fails

to keep the transmit FIFO filled sufficiently, causing an

underflow, the MAC engine will guarantee the message

is either sent as a runt packet (which will be deleted by

the receiving station) or as an invalid FCS (which will

also cause the receiver to reject the message).

The status of each receive message is available in the

appropriate Receive Message Descriptor (RMD) and

CSR areas. All received frames are passed to the host

The number of transmission retry attempts (ONE,

MORE, RTRY, and TRC).

Whether the MAC engine had to Defer (DEF) due to

channel activity.

Excessive deferral (EXDEF), indicating that the

transmitter experienced Excessive Deferral on this

transmit frame, where Excessive Deferral is defined

in the ISO 8802-3 (IEEE/ANSI 802.3) standard.

Loss of Carrier (LCAR), indicating that there was an

interruption in the ability of the MAC engine to mon-

itor its own transmission. Repeated LCAR errors in-

dicate a potentially faulty transceiver or network

connection.

Late Collision (LCOL) indicates that the transmis-

sion suffered a collision after the slot time. This is in-

dicative of a badly configured network. Late

collisions should not occur in a normal operating

network.

Collision Error (CERR) indicates that the trans-

ceiver did not respond with an SQE Test message

within the first 4 ms after a transmission was com-

pleted. This may be due to a failed transceiver, dis-

connected or faulty transceiver drop cable, or

because the transceiver does not support this fea-

ture (or it is disabled). SQE Test is only valid for 10-

Mbps networks.

P R E L I M I N A R Y

Am79C973/Am79C975

regardless of any error. The FRAM error will only be re-

ported if an FCS error is detected and there is a non-

integral number of bytes in the message.

During the reception, the FCS is generated on every

nibble (including the dribbling bits) coming from the ca-

ble, although the internally saved FCS value is only up-

dated on the eighth bit (on each byte boundary). The

MAC engine will ignore up to 7 additional bits at the end

of a message (dribbling bits), which can occur under

normal network operating conditions. The framing error

is reported to the user as follows:

Counters are provided to report the Receive Collision

Count and Runt Packet Count, for network statistics

and utilization calculations.

Media Access Management

The basic requirement for all stations on the network is

to provide fairness of channel allocation. The IEEE

802.3/Ethernet protocols define a media access mech-

anism which permits all stations to access the channel

with equality. Any node can attempt to contend for the

channel by waiting for a predetermined time (Inter

Packet Gap) after the last activity, before transmitting

on the media. The channel is a multidrop communica-

tions media (with various topological configurations

permitted), which allows a single station to transmit and

all other stations to receive. If two nodes simulta-

neously contend for the channel, their signals will inter-

act causing loss of data, defined as a collision. It is the

responsibility of the MAC to attempt to avoid and

recover from a collision, to guarantee data integrity for

the end-to-end transmission to the receiving station.

Medium Allocation

The IEEE/ANSI 802.3 standard (ISO/IEC 8802-3 1990)

requires that the CSMA/CD MAC monitor the medium

for traffic by watching for carrier activity. When carrier is

detected, the media is considered busy, and the MAC

should defer to the existing message.

The ISO 8802-3 (IEEE/ANSI 802.3) standard also al-

lows optionally a two-part deferral after a receive mes-

sage.

If the number of dribbling bits are 1 to 7 and there is

no FCS error, then there is no Framing error (FRAM

= 0).

If the number of dribbling bits are 1 to 7 and there is

a FCS error, then there is also a Framing error

(FRAM = 1).

If the number of dribbling bits is 0, then there is no

Framing error. There may or may not be a FCS er-

ror.

If the number of dribbling bits is EIGHT, then there

is no Framing error. FCS error will be reported and

the receive message count will indicate one extra

byte.

AM79C973BKC\W AMD (ADVANCED MICRO DEVICES), AM79C973BKC\W Datasheet - Page 71

AM79C973BKC\W

Specifications of AM79C973BKC\W

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