XC3S1600E-5FG320C Xilinx Inc, XC3S1600E-5FG320C Datasheet - Page 32

XC3S1600E-5FG320C

Manufacturer Part Number

XC3S1600E-5FG320C

Description

PROGRAMMABLE MICROCHIP

Manufacturer

Xilinx Inc

Datasheet

1.XC3S1600E-5FG320C.pdf (193 pages)

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Table 15: Dual-Port RAM Function

Table 16: Distributed RAM Signals

DS312-2 (v1.1) March 21, 2005

Advance Product Specification

Notes:

WE (mode)

WCLK

1 (write)

0 (read)

1 (read)

data_a = word addressed by bits A3-A0.

data_d = word addressed by bits DPRA3-DPRA0.

Signal

Figure 24: Dual-Port RAM Component

Inputs

WCLK

DPRA0

DPRA1

DPRA2

DPRA3

WCLK

↑

↓

The clock is used for synchronous

writes. The data and the address input

pins have setup times referenced to the

WCLK pin. Active on the positive edge

by default with built-in programmable

polarity.

The enable pin affects the write

functionality of the port. An inactive

Write Enable prevents any writing to

memory cells. An active Write Enable

causes the clock edge to write the data

input signal to the memory location

pointed to by the address inputs. Active

High by default with built-in

programmable polarity.

RAM16X1D

DS312-2_42_021305

Description

SPO

DPO

data_a

SPO

Outputs

data_d

DPO

www.xilinx.com

Table 16: Distributed RAM Signals (Continued)

The INIT attribute can be used to preload the memory with

data during FPGA configuration. The default initial contents

for RAM is all zeros. If the WE is held Low, the element can

be considered a ROM. The ROM function is possible even

in the SLICEL.

The global write enable signal, GWE, is asserted automati-

cally at the end of device configuration to enable all writable

elements. The GWE signal guarantees that the initialized

distributed RAM contents are not disturbed during the con-

figuration process.

The distributed RAM is useful for smaller amounts of mem-

ory. Larger memory requirements can use the dedicated

18Kbit RAM blocks (see

For more information on distributed RAM, see XAPP464:

"Using Look-Up Tables as Distributed RAM in Spartan-3

FPGAs".

Shift Registers

It is possible to program each SLICEM LUT as a 16-bit shift

delay serial data anywhere from 1 to 16 clock cycles without

using any of the dedicated flip-flops. The resulting program-

mable delays can be used to balance the timing of data

pipelines.

The SLICEM LUTs cascade from the G-LUT to the F-LUT

through the DIFMUX (see

SHIFTOUT lines cascade a SLICEM to the SLICEM below

to form larger shift registers. The four SLICEM LUTs of a

single CLB can be combined to produce delays up to 64

clock cycles. It is also possible to combine shift registers

across more than one CLB.

A0, A1, A2, A3

(A4, A5)

O, SPO, and

DPO

Signal

Figure

The address inputs select the memory

cells for read or write. The width of the

port determines the required address

inputs.

The data input provides the new data

value to be written into the RAM.

The data output O on single-port RAM

or the SPO and DPO outputs on

dual-port RAM reflects the contents of

the memory cells referenced by the

address inputs. Following an active

write clock edge, the data out (O or

SPO) reflects the newly written data.

25). Used in this way, each LUT can

Block

RAM).

Figure

Description

Functional Description

12). SHIFTIN and

XC3S1600E-5FG320C Xilinx Inc, XC3S1600E-5FG320C Datasheet - Page 32

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