XC2S400E-6FGG456C Xilinx Inc, XC2S400E-6FGG456C Datasheet - Page 28

XC2S400E-6FGG456C

Manufacturer Part Number

XC2S400E-6FGG456C

Description

FPGA Spartan®-IIE Family 400K Gates 10800 Cells 357MHz 0.15um Technology 1.8V 456-Pin FBGA

Manufacturer

Xilinx Inc

Series

Spartan™-IIEr

Datasheet

1.XC2S50E-6TQG144C.pdf (108 pages)

Specifications of XC2S400E-6FGG456C

Package

456FBGA

Family Name

SpartanÂ®-IIE

Device Logic Cells

10800

Device Logic Units

2400

Device System Gates

400000

Maximum Internal Frequency

357 MHz

Typical Operating Supply Voltage

1.8 V

Maximum Number Of User I/os

329

Ram Bits

163840

Number Of Logic Elements/cells

10800

Number Of Labs/clbs

2400

Total Ram Bits

163840

Number Of I /o

329

Number Of Gates

400000

Voltage - Supply

1.71 V ~ 1.89 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

456-BBGA

Case

BGA

05+

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

122-1327

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Spartan-IIE FPGA Family: Functional Description

If CCLK is slower than F

BUSY. In this case, the above handshake is unnecessary,

and data can simply be entered into the FPGA every CCLK

cycle.

A configuration packet does not have to be written in one

continuous stretch, rather it can be split into many write

sequences. Each sequence would involve assertion of CS.

In applications where multiple clock cycles may be required

to access the configuration data before each byte can be

loaded into the Slave Parallel interface, a new byte of data

may not be ready for each consecutive CCLK edge. In such

a case the CS signal may be deasserted until the next byte

is valid on D0-D7. While CS is High, the Slave Parallel inter-

face does not expect any data and ignores all CCLK transi-

Figure 21: Loading Configuration Data for the Slave

CCLK Rising Edge

WRITE and CS

To CRC Check

Byte on Next

Configuration

Driving BUSY

Configuration

User Drives

Goes High

Load One

After INIT

Data File?

Parallel Mode

End of

FPGA

High?

High

Low

CCNH

Yes

, the FPGA will never assert

Yes

DS001_19_032300

www.xilinx.com

tions. However, to avoid aborting configuration, WRITE

must continue to be asserted while CS is asserted during

CCLK transitions.

Abort

To abort configuration during a write sequence, deassert

WRITE while holding CS Low. The abort operation is initi-

ated at the rising edge of CCLK. The device will remain

BUSY until the aborted operation is complete. After aborting

configuration, data is assumed to be unaligned to word

boundaries and the FPGA requires a new synchronization

word prior to accepting any new packets.

Boundary-Scan Configuration Mode

In the boundary-scan mode, no nondedicated pins are

required, configuration being done entirely through the

IEEE 1149.1 Test Access Port (TAP).

Configuration through the TAP uses the special CFG_IN

instruction. This instruction allows data input on TDI to be

converted into data packets for the internal configuration

bus.

The following steps are required to configure the FPGA

through the boundary-scan port.

1. Load the CFG_IN instruction into the boundary-scan

2. Enter the Shift-DR (SDR) state

3. Shift a standard configuration bitstream into TDI

4. Return to Run-Test-Idle (RTI)

5. Load the JSTART instruction into IR

6. Enter the SDR state

7. Clock TCK (if selected) through the startup sequence

8. Return to RTI

Configuration and readback via the TAP is always available.

The boundary-scan mode simply locks out the other modes.

The boundary-scan mode is selected by a <10x> on the

mode pins (M0, M1, M2). Note that the PROGRAM pin must

be pulled High prior to reconfiguration. A Low on the PRO-

GRAM pin resets the TAP controller and no boundary scan

operations can be performed. See Xilinx Application Note

XAPP188

ration.

Readback

The configuration data stored in the Spartan-IIE FPGA con-

figuration memory can be read back for verification. Along

with the configuration data it is possible to read back the

contents of all flip-flops/latches, LUT RAMs, and block

RAMs. This capability is used for real-time debugging.

For more detailed information see Xilinx Application Note

XAPP176, Configuration and Readback of the Spartan-II

and Spartan-IIE FPGA Families.

instruction register (IR)

(the length is programmable)

for more information on boundary-scan configu-

DS077-2 (v2.3) June 18, 2008

Product Specification

XC2S400E-6FGG456C Xilinx Inc, XC2S400E-6FGG456C Datasheet - Page 28

XC2S400E-6FGG456C

Specifications of XC2S400E-6FGG456C

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