Texas Instruments specifications Duplex wrap test, PHY TNETX4090

Page 59

TNETX4090

ThunderSWITCH II9-PORT 100-/1000-MBIT/S ETHERNETSWITCH

SPWS044E ± DECEMBER 1997 ± REVISED AUGUST 1999

internal wrap test (continued)

08

 

 

 

 

07

 

 

 

 

06

 

TNETX4090

 

NM

 

 

 

 

05

 

 

 

 

04

03

02

01

00

Figure 13. Internal Wrap Example

The operational status of the PHYs or external connections to the device do not have to be considered or assumed good, when in internal loopback mode.

duplex wrap test

Duplex wrap test is similar to internal wrap mode (see Figure 13). The ports can be set to accept frame data that is wrapped at the PHY. This permits network connections between the device and the PHY to be verified. Any port can be the source port (not just the NM port as shown in Figure 14). By using multicast/broadcast frames, traffic can be routed selectively between ports involved in the test or return the frame directly before retransmission on the uplink. Software control of the external PHYs is required to configure them for loopback.

If the internal PCS is in use (port configured in PMA mode) loopback in PCSxControl also must be asserted. This causes Mxx_EWRAP to be high, forcing external PMD into loopback mode.

Duplex frame-wrap test mode is selected by setting dpwrap in SysTest. When selected, the port is forced into full duplex, allowing it to receive frames it transmits.

The switch is configured in the same manner as internal wrap.

PHY

PHY

08

 

 

 

 

07

 

 

 

 

06

 

TNETX4090

 

NM

05

 

 

 

 

04

03

02

01

00

Figure 14. Duplex Wrap Example

POST OFFICE BOX 655303 DALLAS, TEXAS 75265

59

Image 59
Contents Description DMA MIIMAC MII MAC Eeprom CPU I/FPCS Duplex LED Rdram Interface Jtag Interface GGP Package Bottom View Signal Ball Name Signal-to-Ball Mapping Signal Names Sorted AlphabeticallyReset Sdma SAD0 Terminal Internal Description Name RESISTOR² Terminal FunctionsJtag interface Control logic interfaceM08TXD7 M08TXD6 M08TXD5 100-/1000-Mbit/s MAC interface Gmii modeTerminal Internal Description Name Resistor Port to not support pause frames Pulldown 10-/100-Mbit/s MAC interface MII mode ports 0±7M00RENEG M01RENEG M04TCLK M05TCLK M06TCLK M07TCLK AD4 ThunderSWITCH II 9-PORT 100-/1000-MBIT/S ETHERNET SwitchMII management interface Rdram interface Eeprom interface DIO interface100-/1000-Mbit/s port PCS LED interface Power supplyLED interface Byte DIO Address DIO interface descriptionDIO Internal Register Address Map TNETX4090 ThunderSWITCH II 9-PORT 100-/1000-MBIT/S ETHERNETVLAN1QID VLAN0QID VLAN37QID VLAN36QID TNETX4090 PCS8Status PCS8Control 0x0700 DIO interface description Port no Head Statistic Even ODD Ports Port StatisticsTail 0x90Ex Port no Head Statistic TailReceiving/transmitting management frames DMA Interface SignalsSignal Description Address-Lookup StatisticsIeee Std 802.1Q Vlan tags on the NM port State of DIO signal terminals during hardware resetDIO Interface During Hardware Reset DIO Interface State During Hardware ResetCRC Vlan IDFCS Tpid TCITNETX4090 Interrupt processing PHY management interfaceFull-duplex NM port NM bandwidth and priorityMAC interface Receive versus transmit priority Adaptive performance optimization APOInterframe gap enforcement BackoffSpeed, duplex, and flow-control negotiation 10-/100-Mbit/s MII ports 0±7100-Mbit/s Port Negotiation With the TNETE2104 100-/1000-Mbit/s PHY interface port Outcome Port 8 Duplex Negotiation in MII ModePort 8 Pause Negotiation in MII Mode Full-duplex hardware flow controlM08GTCLK M08TXEN Pretagging and extended port awarenessPretag on transmission BIT Name Function Transmit Pretag Bit DefinitionsPretag on reception Learning Format Receive Pretag Bit DefinitionsTNETX4090 RXD Flow COL TXD Directed Format Receive Pretag Bit DefinitionsRing-cascade topology RXD Flow COL TXDM08GTCLK M08TXEN M08RXDV Switch TerminalRing-Topology Connectivity GND SCL SDAEdio TNETX4090 Eclk Summary of Eeprom load outcomes Outcome Stop Load Initd ² Fault LED EclkInteraction of Eeprom load with the SIO register State Display Compatibility with future device revisionsPort LED States Collision LED StatesMulti-LED display PCS duplex LEDLED Status Bit Definitions and Shift Order Lamp testSout SCHAIN0 Txclk Vref Rxclk VDD BUS Enable GND BUS Ctrl Rdram SINBUS Enable GND Rdram BUS Ctrl SIN TNETX4090 VCC NC Txclk Vref Rxclk VDDJtag Bist Status Jtag Instruction OpcodesHighz instruction Racbist instructionIale Frame routingVlan support Spanning-tree support Address maintenanceIeee Std 802.1Q tags ± reception Ieee Std 802.1Q header ± transmissionAging algorithms Frame-Routing Algorithm SPWS044E ± December 1997 ± Revised August Port routing code Removal of source port Port trunking/load sharingExtended port awareness Port trunking exampleTrunk Group 0 Port Membership Trunk0Ports Register Trunk Group 1 Port Membership Trunk1Ports RegisterFlow control System test capabilities Other flow-control mechanismsHardware flow control Multicast limitInternal wrap test Reading RdramPHY TNETX4090 Duplex wrap testMIN NOM MAX Unit Recommended operating conditionsTiming requirements over recommended operating conditions Jtag interface Control signalsReset see Figure PMA receive see Figure Physical medium attachment interface port ReceivePMA transmit see Figure TransmitGmii transmit see Figure Gmii portGmii receive see Figure Gmii Clock PMA and Gmii clock see FigureMII receive see Figure MII ports 0±8MII clock see Figure MII transmit see FigureDbusctrl Dbusen Rdram interfaceRdram see Figure Dtxclk DrxclkSCS Srnw SAD1±SAD0 Sdma SDATA7± SDATA0 Srdy Sint DIO interfaceDIO and DMA writes see Figure SCS Srnw SAD1±SAD0 Sdma SDATA7± SDATA0 Srdy DIO and DMA reads see FigureEeprom reads see Figure Eeprom interfaceEeprom writes see Figure Ledclk Leddata LED interfaceLED see Figure VOL VOHTTL Output Macro Propagation-Delay-Time Voltage Waveforms VOL VDD VDD VOH50% Lvcmos Mechanical Data TBD TNETX4090GGP Obsolete BGAImportant Notice