LAN9211-ABZJ SMSC, LAN9211-ABZJ Datasheet - Page 31

LAN9211-ABZJ

Manufacturer Part Number

LAN9211-ABZJ

Description

IC ETHERNET CTLR SGL CHIP 56-QFN

Manufacturer

SMSC

Type

Single Chip MAC and PHY Controllerr

Datasheet

1.LAN9211-ABZJ.pdf (147 pages)

Specifications of LAN9211-ABZJ

Controller Type

Ethernet Controller

Interface

Serial EEPROM

Voltage - Supply

3.3V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

56-QFN

Product

Ethernet Controllers

Number Of Transceivers

Standard Supported

IEEE 802.3 or IEEE 802.3u

Data Rate

10 Mbps or 100 Mbps

Supply Voltage (max)

5 V

Supply Voltage (min)

3.3 V

Supply Current (max)

86 mA

Maximum Operating Temperature

+ 70 C

Ethernet Connection Type

100BASE-TX or 10BASE-T

Minimum Operating Temperature

0 C

Mounting Style

SMD/SMT

No. Of Ports

Ethernet Type

IEEE 802.3 / 802.3u

Interface Type

HBI

Supply Current

86mA

Supply Voltage Range

2.97V To 3.63V

Operating Temperature Range

0Â°C To +70Â°C

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Supply

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

638-1049-6

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High-Performance Small Form Factor Single-Chip Ethernet Controller with HP Auto-MDIX Support

Datasheet

SMSC LAN9211

3.6.1.1

3.6.2

RX Checksum Calculation

The checksum is calculated 16 bits at a time. In the case of an odd sized frame, an extra byte of zero

is used to pad up to 16 bits.

Consider the following packet: DA, SA, Type, B0, B1, B2 … BN, FCS

Let [A, B] = A*256 + B;

If the packet has an even number of octets then

checksum = [B1, B0] + C0 + [B3, B2] + C1 + … + [BN, BN-1] + CN-1

Where C0, C1, ... CN-1 are the carry out results of the intermediate sums.

If the packet has an odd number of octets then

checksum = [B1, B0] + C0 + [B3, B2] + C1 + … + [0, BN] + CN-1

Transmit Checksum Offload Engine (TXCOE)

The transmit checksum offload engine provides assistance to the CPU by calculating a 16-bit

checksum, typically for TCP, for a transmit Ethernet frame. The TXCOE calculates the checksum and

inserts the results back into the data stream as it is transferred to the MAC.

To activate the TXCOE and perform a checksum calculation, the host must first set the TX checksum

offload engine enable bit (TXCOE_EN) in the

The host then pre-pends a 3 DWORD buffer to the data that will be transmitted. The pre-pended buffer

includes a TX Command ‘A’, TX Command ‘B’, and a 32-bit TX checksum preamble. When bit 14 (CK)

of the TX Command ‘B’ is set in conjunction with bit 13 (FS) of TX Command ‘A’ and bit 16

(TXCOE_EN) of the COE_CR register, the TXCOE will perform a checksum calculation on the

associated packet. When these three bits are set, a 32-bit TX checksum preamble must be pre-pended

to the beginning of the TX packet (refer to

on the handling of the associated packet. Bits 11:0 of the TX checksum preamble define the byte offset

at which the data checksum calculation will begin (TXCSSP). The checksum calculation will begin at

this offset and will continue until the end of the packet. The data checksum calculation must not begin

in the MAC header (first 14 bytes) or in the last 4 bytes of the TX packet. When the calculation is

complete, the checksum will be inserted into the packet at the byte offset defined by bits 27:16 of the

TX checksum preamble (TXCSLOC). The TX checksum cannot be inserted in the MAC header (first

14 bytes) or in the last 4 bytes of the TX packet. If the CK bit is not set in the first TX Command ‘B’

of a packet, the packet is passed directly through the TXCOE without modification, regardless if the

TXCOE_EN is set. An example of a TX packet with a pre-pended TX checksum preamble can be

found in

ethernet controller in four fragments, the first containing the TX Checksum Preamble.

shows how these fragments are loaded into the TX Data FIFO. For more information on the TX

Command ‘A’ and TX Command ‘B’, refer to

If the TX packet already includes a partial checksum calculation (perhaps inserted by an upper layer

protocol), this checksum can be included in the hardware checksum calculation by setting the TXCSSP

field in the TX checksum preamble to include the partial checksum. The partial checksum can be

replaced by the completed checksum calculation by setting the TXCSLOC pointer to point to the

location of the partial checksum.

Section 3.12.6.3, "TX Example

DATASHEET

Table

3". In this example the host writes the packet data to the

Section 3.12.2, "TX Command

COE_CR—Checksum Offload Engine Control

3.7). The TX checksum preamble instructs the TXCOE

Format".

Revision 2.7 (03-15-10)

Figure 3.17

LAN9211-ABZJ SMSC, LAN9211-ABZJ Datasheet - Page 31

LAN9211-ABZJ

Specifications of LAN9211-ABZJ

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