PDI1394L40BEGA ST-Ericsson Inc, PDI1394L40BEGA Datasheet - Page 18
PDI1394L40BEGA
Manufacturer Part Number
PDI1394L40BEGA
Description
IC IEEE 1394 LINK CTRLR 144-LQFP
Manufacturer
ST-Ericsson Inc
Datasheet
1.PDI1394L40BEGA.pdf
(81 pages)
Specifications of PDI1394L40BEGA
Applications
AV,TV, VTR
Interface
IEEE 1394
Voltage - Supply
3 V ~ 3.6 V
Package / Case
144-LQFP
Mounting Type
Surface Mount
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
568-1176
PDI1394L40BE,551
PDI1394L40BE-S
PDI1394L40BE,551
PDI1394L40BE-S
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
PDI1394L40BEGA
Manufacturer:
ST-Ericsson Inc
Quantity:
10 000
1. It is not required to write all 4 bytes, or both words of a register: those bytes that are either reserved (undefined) or don’t care do not have
2. The update control line does not necessarily have to be connected to the CPU address line HIF A8. This input could also be controlled by
3. Writing the bytes or words of the shadow register can be done in any order and as often as needed (new writes simply overwrite the old
4. It is now possible to read/modify/write a register using the shadow register (0x0F4) without rewriting all 4 bytes. For example, to modify an
The RDI register contains control, status and interrupt bits. Operation of the status and interrupt bits in the RDI register differs slightly from these
Philips Semiconductors
12.5.2 Write accesses
To write to an internal register the host interface must collect the 4 byte values (8 bit mode) or 2 word values (16 bit mode) into a 32 bit value
and then write the result to the target register in a single clock tick. This requires a register to hold the 32 bit value being compiled until it is
ready to be written to the actual target register. This temporary register inside the host interface is called the shadow register. In 8 bit mode,
address lines HIF A0 and HIF A1 are used to select which of the 4 bytes of the shadow register is to be written with the value on the CPU data
bus. In 16 bit mode, HIF A1 is used to select which half of the shadow register is to be written with the value on the CPU data bus. Only one
byte (8 bit mode) or one word (16 bit mode) can be written in a single write access cycle.
Not all registers can be accessed in Direct Address Space. Some of the registers are in an indirect address space, these registers control the
FIFO size and content protection system. The correct internal register space has to be selected through the host interface, using directly
addressable registers INDADDR (0x0F8) and INDDATA (0x0FC).
NOTES:
12.5.3 Accessing the RDI register (Power–down, Power–up)
Accessing the RDI register is a special situation, but software written to access all other link base registers can still be used. This register can
be read and written with the link chip in power–down mode; this means that there is no system clock present within the link chip. The system
clock is required to access all other link registers due to the fact that multiple clock cycles are required to fetch data to the shadow register or
write data from the shadow register to the targeted internal register. Reading and writing to the RDI register is done through purely combinatoral
logic, there is no access through the shadow register. The RDI register is accessed directly through the host interface using the same method of
access required by other link base registers.
types of bits in other registers. Operation falls into four categories: (1) pure status bit, (2) interrupt/status bit, (3) control bit, (4) interrupt control
bit.
LPSTAT is a pure status bit; this means that LPSTAT continually reflects the status of the LPS signal on the link–phy interface. If LPSTAT = 1,
the LPS signal is active. If LPSTAT = 0, the LPS signal to the phy chip is inactive. It should be noted here that the LPSTAT bit should NOT be
used as an indicator of link chip activity because the LPS signal may be inactive for short (25 uS) periods of time if the link chip is performing a
phy–link interface reset function. SCI is also a pure status bit when it is not enabled as an interrupt. SCI will reflect the INVERSE status of the
system clock at all times. When the system clock (SCLK) is active, SCI = 0. When the SCLK is inactive, SCI = 1. The SCI bit can also be used
as an interrupt bit by setting ESCI = 1. In this mode of operation when the SCI = 1, an interrupt will be generated to indicate that the SCLK has
become inactive. This interrupt is serviced in the same manner as all other link register interrupts... write a “1” back to the SCI bit position in
order to acknowledge the interrupt.
PLI, LOA and SCA are interrupt/status bits. These bits may be enabled as interrupts (by setting the corresponding interrupt control bit EPLI,
ELOA, or ESCA =1). These bits are ALSO status bits when the corresponding interrupt enabling bit is = 0. However, if any of these bits sets
(=1) while in the status bit mode, it must be written with a “1” to be reset... similar operation to interrupt bit operation elsewhere in the link
registers. Also, like other interrupt bits in the link registers, in order to acknowledge an interrupt of any of these bits, it is necessary to write a “1”
back to the bit position to acknowledge the interrupt; this resets the bit to “0”. [Please bear in mind that the functions represented by these bits
2000 Dec 15
1394 enhanced AV link layer controller
to be written in which case they will be assigned the value that was left in the corresponding byte of the shadow register from a previous
write access. For example, to acknowledge an interrupt for the isochronous receiver in 8 bit mode, a single byte write to location
0x100+(0x4C)+3 = 0x14F is sufficient. The value 256 represents setting HIF A8=1. The host interface cannot directly access the FIFOs, but
instead reads from/writes into a transfer register (shown as TR in the Figures above). Data is moved between FIFO and TR by internal logic
as soon as possible without CPU intervention.
other means, for example a combinatorial circuit that activates the update control line whenever a write access is done for byte 3 or the
upper 16 bits. This makes the internal updating automatic for quadlet writing.
value).
enable bit in the fourth byte of the Asynchronous Interrupt Enable (0x0A4), a read of location 0x100+0x0A0+3=0x1A3, followed by a write of
the modified byte to the same location 0x100+0x0A0+3=0x1A3 is sufficient. The other bytes remain unchanged.
HIF A0..1 (8 BIT MODE)
HIF A1 (16 BIT MODE)
CPU
HIF A2..7
HIF A8
8/16
MUX
UPDATE/COPY CONTROL
32
14
MUX
TR
32
Q
Q
REGISTERS
PDI1394L40
Preliminary specification
SV01035
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