Data Sheet
June 1999
ORCA Series 3C and 3T FPGAs
FPGA Configuration Modes (continued)
DOUT
CCLK
TO DAISY-
CHAINED
DEVICES
Asynchronous Peripheral Mode
PRGM
D[7:0]
8
Figure 56 shows the connections needed for the asyn-
chronous peripheral mode. In this mode, the FPGA
system interface is similar to that of a microprocessor-
peripheral interface. The microprocessor generates the
control signals to write an 8-bit byte into the FPGA. The
FPGA control inputs include active-low CS0 and active-
high CS1 chip selects and WR and RD inputs. The chip
selects can be cycled or maintained at a static level
during the configuration cycle. Each byte of data is writ-
ten into the FPGA’s D[7:0] input pins. D[7:0] of the
FPGA can be connected to D[7:0] of the microproces-
sor only if a standard prom file format is used. If a .bit or
.rbt file is used from ORCA Foundry, then the user must
mirror the bytes in the .bit or .rbt file OR leave the .bit or
.rbt file unchanged and connect D[7:0] of the FPGA to
D[0:7] of the microprocessor.
RDY/BUSY
INIT
DONE
MICRO-
PROCESSOR
ORCA
ADDRESS
CS0
DECODE LOGIC
CS1 SERIES
FPGA
BUS
CONTROLLER
RD
WR
VDD
M2
M1
M0
HDC
LDC
Figure 56. Asynchronous Peripheral Configuration
Microprocessor Interface (MPI) Mode
The FPGA provides an RDY/BUSY status output to indi-
cate that another byte can be loaded. A low on RDY/
BUSY indicates that the double-buffered hold/shift reg-
isters are not ready to receive data, and this pin must
be monitored to go high before another byte of data
can be written. The shortest time RDY/BUSY is low
occurs when a byte is loaded into the hold register and
the shift register is empty, in which case the byte is
immediately transferred to the shift register. The long-
est time for RDY/BUSY to remain low occurs when a
byte is loaded into the holding register and the shift
register has just started shifting configuration data into
configuration RAM.
The built-in MPI in Series 3 FPGAs is designed for use
in configuring the FPGA. Figure 57 and Figure 58 show
the glueless interface for FPGA configuration and read-
back from the PowerPC and i960 processors, respec-
tively. When enabled by the mode pins, the MPI
handles all configuration/readback control and hand-
shaking with the host processor. For single FPGA con-
figuration, the host sets the configuration control
register PRGM bit to zero then back to a one and, after
reading that the INIT signal is high in the MPI status
register, transfers data 8 bits at a time to the FPGA’s
D[7:0] input pins.
If configuring multiple FPGAs through daisy-chain
operation is desired, the MP_DAISY bit must be set in
the configuration control register of the MPI. Because
of the latency involved in a daisy-chain configuration,
the MP_HOLD_BUS bit may be set to zero rather than
one for daisy-chain operation. This allows the MPI to
acknowledge the data transfer before the configuration
information has been serialized and transferred on the
FPGA daisy-chain. The early acknowledgment frees
the host processor to perform other system tasks. Con-
figuring with the MP_HOLD_BUS bit at zero requires
that the host microprocessor poll the RDY/BUSY bit of
the MPI status register and/or use the MPI interrupt
capability to confirm the readiness of the MPI for more
configuration data.
The RDY/BUSY status is also available on the D7 pin by
enabling the chip selects, setting WR high, and apply-
ing RD low, where the RD input provides an output
enable for the D7 pin when RD is low. The D[6:0] pins
are not enabled to drive when RD is low and, therefore,
only act as input pins in asynchronous peripheral
mode. Optionally, the user can ignore the RDY/BUSY
status and simply wait until the maximum time it would
take for the RDY/BUSY line to go high, indicating the
FPGA is ready for more data, before writing the next
data byte.
94
Lucent Technologies Inc.