XC4013E-3PQ160I Datasheet, PDF(2/68 Page) Xilinx, Inc – XC4000E and XC4000X Series Field Programmable Gate Arrays

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XC4013E-3PQ160I Datasheet, PDF (2/68 Pages) Xilinx, Inc – XC4000E and XC4000X Series Field Programmable Gate Arrays

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Product Obsolete or Under Obsolescence

XC4000E and XC4000X Series Field Programmable Gate Arrays

XC4000E and XC4000X Series

Compared to the XC4000

For readers already familiar with the XC4000 family of Xil-

inx Field Programmable Gate Arrays, the major new fea-

tures in the XC4000 Series devices are listed in this

section. The biggest advantages of XC4000E and

XC4000X devices are signiï¬cantly increased system

speed, greater capacity, and new architectural features,

particularly Select-RAM memory. The XC4000X devices

also offer many new routing features, including special

high-speed clock buffers that can be used to capture input

data with minimal delay.

Any XC4000E device is pinout- and bitstream-compatible

with the corresponding XC4000 device. An existing

XC4000 bitstream can be used to program an XC4000E

device. However, since the XC4000E includes many new

features, an XC4000E bitstream cannot be loaded into an

XC4000 device.

much as 50% from XC4000 values. See âFast Carry Logicâ

on page 18 for more information.

Select-RAM Memory: Edge-Triggered, Synchro-

nous RAM Modes

The RAM in any CLB can be conï¬gured for synchronous,

edge-triggered, write operation. The read operation is not

affected by this change to an edge-triggered write.

Dual-Port RAM

A separate option converts the 16x2 RAM in any CLB into a

16x1 dual-port RAM with simultaneous Read/Write.

The function generators in each CLB can be conï¬gured as

either level-sensitive (asynchronous) single-port RAM,

edge-triggered (synchronous) single-port RAM, edge-trig-

gered (synchronous) dual-port RAM, or as combinatorial

logic.

Conï¬gurable RAM Content

XC4000X Series devices are not bitstream-compatible with The RAM content can now be loaded at conï¬guration time,

equivalent array size devices in the XC4000 or XC4000E so that the RAM starts up with user-deï¬ned data.

families. However, equivalent array size devices, such as

the XC4025, XC4025E, XC4028EX, and XC4028XL, are H Function Generator

pinout-compatible.

In current XC4000 Series devices, the H function generator

Improvements in XC4000E and XC4000X

is more versatile than in the original XC4000. Its inputs can

come not only from the F and G function generators but

Increased System Speed

XC4000E and XC4000X devices can run at synchronous

system clock rates of up to 80 MHz, and internal perfor-

mance can exceed 150 MHz. This increase in performance

over the previous families stems from improvements in both

also from up to three of the four control input lines. The H

function generator can thus be totally or partially indepen-

dent of the other two function generators, increasing the

maximum capacity of the device.

IOB Clock Enable

device processing and system architecture. XC4000

Series devices use a sub-micron multi-layer metal process.

In addition, many architectural improvements have been

made, as described below.

The two ï¬ip-ï¬ops in each IOB have a common clock enable

input, which through conï¬guration can be activated individ-

ually for the input or output ï¬ip-ï¬op or both. This clock

enable operates exactly like the EC pin on the XC4000

The XC4000XL family is a high performance 3.3V family

based on 0.35Âµ SRAM technology and supports system

speeds to 80 MHz.

CLB. This new feature makes the IOBs more versatile, and

avoids the need for clock gating.

Output Drivers

PCI Compliance

The output pull-up structure defaults to a TTL-like

XC4000 Series -2 and faster speed grades are fully PCI

compliant. XC4000E and XC4000X devices can be used to

implement a one-chip PCI solution.

Carry Logic

totem-pole. This driver is an n-channel pull-up transistor,

pulling to a voltage one transistor threshold below Vcc, just

like the XC4000 family outputs. Alternatively, XC4000

Series devices can be globally conï¬gured with CMOS out-

puts, with p-channel pull-up transistors pulling to Vcc. Also,

The speed of the carry logic chain has increased dramati-

cally. Some parameters, such as the delay on the carry

chain through a single CLB (TBYP), have improved by as

the conï¬gurable pull-up resistor in the XC4000 Series is a

p-channel transistor that pulls to Vcc, whereas in the origi-

nal XC4000 family it is an n-channel transistor that pulls to

a voltage one transistor threshold below Vcc.

May 14, 1999 (Version 1.6)

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