PDI1394L40BE,551 NXP Semiconductors, PDI1394L40BE,551 Datasheet - Page 67
PDI1394L40BE,551
Manufacturer Part Number
PDI1394L40BE,551
Description
Manufacturer
NXP Semiconductors
Datasheet
1.PDI1394L40BE551.pdf
(81 pages)
Specifications of PDI1394L40BE,551
Lead Free Status / Rohs Status
Compliant
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Bit 3:
Bit 2:
Bit 1:
Bit 0:
13.3.12 Shadow Register (SHADOW_REG) – Base Address: 0x0F4
Reset Value 0x0F0A0500
Bit 31..0:
2000 Dec 15
1394 enhanced AV link layer controller
R/W
R/W
R/W
R/W
R/W
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
PLI: PHY – link interface initialized interrupt. This interrupt indicates when the PHY – link initialization routine has
been accomplished. This bit will be set upon completion of the initialization; if enabled, it will cause a host interface
interrupt in order to inform the host controller of the completed action. Reset of this interrupt requires the writing of a
(1) to this bit position. When used as a status bit, it will be necessary to first write a “1” to this bit position before
reading the status of this bit. See Section 12.5.3 for a full explanation.
LOA: Link–on active interrupt. This interrupt will become active when a link–on signal is received by the link from the
PHY. This bit will remain active as long as the link–on signal is active. When enabled, this bit will set and cause a
host interface interrupt when the link detects the presence of a link–on signal from the PHY. In practice, the link will
be in the power down state when this interrupt occurs (a link–on packet was sent by another node on the bus which
desires to communicate with this powered down node). Proper servicing of this interrupt will contain a scenario
similar to: this node is in power down mode and the host controller has set the ELOA bit to enable the interrupt and
the PHY of this node received a link–on packet from another node requesting this node to power up; (1) the host
controller gets the interrupt and makes a decision to power up, (2) the host de–asserts SWPD (by hardware or
software means... see SWPD above), (3) the host monitors SCA for a ”1” state, (4) when SCA is true, the host writes
a 0 to the ELOA bit and then writes a 1 to the LOA interrupt bit to cancel the interrupt. The link is now powered up.
When used as a status bit, it will be necessary to first write a “1” to this bit position before reading the status of this
bit. See Section 12.5.3 for a full explanation.
SCA: SCLK active interrupt. When the SCLK signal from the PHY to the link is present, this bit is set. If this interrupt
has been enabled, the host will receive an interrupt when the SCLK becomes active (an example of such use might
be during the recovery from a link power down situation). When used as a status bit, it will be necessary to first write
a “1” to this bit position before reading the status of this bit. See Section 12.5.3 for a full explanation.
SCI: SCLK inactive interrupt. When the SCLK signal is NOT active, this bit sets. If this interrupt is enabled, when the
SCLK ceases to be active, the interrupt will occur. SCLK could become inactive due to the PHY connected to this
link going into power down mode. SCI operates as a true status bit. See Section 12.5.3.
The shadow register is a mechanism that allows a byte (8-bit) or word (16-bit) host interface write quadlets (32-bit)
into the AV Link. Bytes or words can be written into the shadow register in any order and then written to the AV Link
by asserting address line A8 with the desired address. For example, if you want to write to Transmit Request Next
register (TX_RQ_NEXT), and you were using an 8-bit host, then you would write the first three bytes to the shadow
register and the fourth byte to the address 0x188 (or 0x189, or 0x18A, or 0x18B). In practice, any write or read with
address line A8 not asserted will be directed to the shadow register. To verify the settings of LTLEND and DATAINV,
this register is initialized to 0x0F0A0500 on power up. Note, unlike the other registers in this device, access to this
register should not be addressed with address line A8 = 1.
BYTE 0
BYTE 1
63
BYTE 2
9
8
7
6
5
BYTE 3
4
3
2
SV01817
PDI1394L40
1
Preliminary specification
0
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