SL811HS
mode described in Auto Address Increment Mode, where direct
addressing is used to READ/WRITE to an individual address.
Data Port, Microprocessor Interface
The SL811HS microprocessor interface provides an 8-bit
bidirectional data path along with appropriate control lines to
interface to external processors or controllers. Programmed I/O
or memory mapped I/O designs are supported through the 8-bit
interface, chip select, read and write input strobes, and a single
address line, A0.
USB transactions are automatically routed to the memory buffer
that is configured for that transfer. Control registers are provided
so that pointers and block sizes in buffer memory are determined
and allocated.
Figure 1. Memory Map
Access to memory and control register space is a simple two
step process, requiring an address Write with A0 = ’0’, followed
by a register/memory Read or Write cycle with address line A0 =
’1’.
0x00 – 0x0F Control
and status registers
0x00 – 0x39
16 bytes
64 bytes
Control/status registers
and endpoint
control/status registers
In addition, a DMA bidirectional interface in slave mode is
available with handshake signals such as nDRQ, nDACK, nWR,
nRD, nCS and INTRQ.
0x10 – 0xFF
USB data buffer
0x40 – 0xFF
USB data buffer
240 bytes
192 bytes
The SL811HS WRITE or READ operation terminates when
either nWR or nCS goes inactive. For devices interfacing to the
SL811HS that deactivate the Chip Select nCS before the Write
nWR, the data hold timing must be measured from the nCS and
is the same value as specified. Therefore, both Intel®- and
Motorola-type CPUs work easily with the SL811HS without any
external glue logic requirements.
Host Mode Memory Map
Peripheral Mode Memory Map
DMA Controller (slave mode only)
Auto Address Increment Mode
In applications that require transfers of large amounts of data
such as scanner interfaces, the SL811HS provides a DMA inter-
face. This interface supports DMA READ or WRITE transfers to
the SL811HS internal RAM buffer, it is done through the micro-
processor data bus via two control lines (nDRQ - Data Request
and nDACK - Data Acknowledge), along with the nWR line and
controls the data flow into the SL811HS. The SL811HS has a
count register that allows selection of programmable block sizes
for DMA transfer. The control signals, both nDRQ and nDACK,
are designed for compatibility with standard DMA interfaces.
The SL811HS supports auto increment mode to reduce READ
and WRITE memory cycles. In this mode, the microcontroller
needs to set up the address only once. Whenever any subse-
quent DATA is accessed, the internal address counter advances
to the next address location.
Auto Address Increment Example. To fill the data buffer that is
configured for address 10h, follow these steps:
1. Write 10h to SL811HS with A0 LOW. This sets the memory
address that is used for the next operation.
Interrupt Controller
2. Write the first data byte into address 10h by doing a write
operation with A0 HIGH. An example is a Get Descriptor; the
first byte that is sent to the device is 80h (bmRequestType) so
you would write 80h to address 10h.
The SL811HS interrupt controller provides a single output signal
(INTRQ) that is activated by a number of programmable events
that may occur as result of USB activity. Control and status
registers are provided to allow the user to select single or
multiple events, which generate an interrupt (assert INTRQ) and
let the user view interrupt status. The interrupts are cleared by
writing to the Interrupt Status Register.
3. Now the internal RAM address pointer is set to 11h. So, by
doing another write with A0 HIGH, RAM address location 11h
is written with the data. Continuing with the Get Descriptor
example, a 06h is written to address 11h for the bRequest
value.
Buffer Memory
4. Repeat Step 3 until all the required bytes are written as
necessary for a transfer. If auto-increment is not used, you
write the address value each time before writing the data as
shown in Step 1.
The SL811HS contains 256 bytes of internal memory used for
USB data buffers, control registers, and status registers. When
in master mode (host mode), the memory is defined where the
first 16 bytes are registers and the remaining 240 bytes are used
for USB data buffers. When in slave mode (peripheral mode), the
first 64 bytes are used for the four endpoint control and status
registers along with the various other registers. This leaves 192
bytes of endpoint buffer space for USB data transfers.
The advantage of auto address increment mode is that it reduces
the number of required SL811HS memory READ/WRITE cycles
to move data to/from the device. For example, transferring 64
bytes of data to/from SL811HS, using auto increment mode,
reduces the number of cycles to 1 address WRITE and 64
READ/WRITE data cycles, compared to 64 address writes and
64 data cycles for random access.
Access to the registers and data memory is through the 8-bit
external microprocessor data bus, in either indexed or direct
addressing. Indexed mode uses the Auto Address Increment
Document 38-08008 Rev. *F
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