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5.2 Intel ICH6-M South Bridge(3)Serial ATA Interface Signals (Continued)
Name Type Description
SATA[3]GP /
GPI[31] I Serial ATA 3 General Purpose: Same function as SATA[0]GP,
except for SATA Port 3.
If interlock switches are not required, this pin can be configured as
GPI[31].
SATALED# OC O Serial ATA LED: This is an open-collecto r output pin driven d uring
SATA command activity. It is to be connected to external circuitry
that can provide the current to drive a platform LED. When active,
the LED is on. When tri-st ated, the LED is off. An external pull-up
resistor to Vcc3_3 is required.
NOTE: An internal pull-up is enabled only during PLTRST#
assertion.
LAN Connect Interface Signals
Name Type Description
LAN_CLK I LAN I/F Clock: This signal is driven by the LAN Connect
component. The frequency range is 5 MHz to 50 MHz.
LAN_RXD[2:0] I Received Data: The LAN Connect component uses these signals to
transfer data and control information to the integrated LAN
controller. These signals have integrated weak pull-up resistors.
LAN_TXD[2:0] O Transmit Data: The integrated LAN controller uses these signals to
transfer data and control information to the LAN Connect component.
LAN_RSTSYNC O LAN Reset/Sync: The LAN Connect component’s Reset and Sync
signals are multiplexed onto this pin.
Other Clocks
Name Type Description
CLK14 I Oscillator Clock: This clock is used for 8254 timers. It runs at
14.31818 MHz. This clock is permitted to stop during S3 (or lower)
states.
CLK48 I 48 MHz Clock: This clock is used to run the USB controller. IT runs
at 48.000 MHz.
This clock is permitted to stop during S3 (or lower) states.
SATA_CLKP
SATA_CLKN
I 100 MHz Differential Clock: These signals are used to run the
SATA controller. Runs at 100 MHz. This clock is permitted to stop
during S3 (or lower) states.
DMI_CLKP,
DMI_CLKN
I 100 MHz Differential Clock: These signals are used to run the
Direct Media Interface. Runs at 100 MHz.
Interrupt Signals
Name Type Description
SERIRQ I/O Serial Interrupt Request: This pin implements the serial interrupt
protocol.
PIRQ[D:A]# OD I PCI Interrupt Requests: In non-APIC mode the PIRQx# signals can
be routed to interrupts 3, 4, 5, 6, 7, 9, 10, 11, 12, 14 or 15 as described
in the Interrupt Steering section. Each PIRQx# line has a separate
Route Control register.
In APIC mode, these signals are connected to the internal I/O APIC in
the following fashion: PIRQA# is connected to IRQ16, PIRQB# to
IRQ17, PIRQC# to IRQ18, and PIRQD# to IRQ19. This frees the
legacy interrupts.
PIRQ[H:E]# /
GPI[5:2]
OD I PCI Interrupt Requests: In non-APIC mode the PIRQx# signals can
be routed to interrupts 3, 4, 5, 6, 7, 9, 10, 11, 12, 14 or 15 as described
in the Interrupt Steering section. Each PIRQx# line has a separate
Route Control register.
In APIC mode, these signals are connected to the internal I/O APIC in
the following fashion: PIRQE# is connected to IRQ20, PIRQF# to
IRQ21, PIRQG# to IRQ22, and PIRQH# to IRQ23. This frees the
legacy interrupts. If not needed for interrupts, these signals can be
used as GPI.
IDEIRQ I IDE Interrupt Request: This interrupt input is connected to the IDE
drive.
LPC Interface Signals
Name Type Description
LAD[3:0] /
FWH[3:0]
I/O LPC Multiplexed Command, Address, Data: For LAD[3:0],
internal pull-ups are provided.
LFRAME# /
FWH[4]
O LPC Frame: LFRAME# indicates the start of an LPC cycle, or an
abort.
LDRQ[0]#
LDRQ[1]# /
GPI[41]
I LPC Serial DMA/Master Request Inputs: LDRQ[1:0]# are used to
request DMA or bus master access. These signals are typically
connected to external Super I/O device. An internal pull-up resistor is
provided on these signals.
LDRQ[1]# may optionally be used as GPI.
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