XCS10XL-5TQ144C Xilinx Inc, XCS10XL-5TQ144C Datasheet - Page 10

XCS10XL-5TQ144C

Manufacturer Part Number

XCS10XL-5TQ144C

Description

IC FPGA 3.3V C-TEMP 144-TQFP

Manufacturer

Xilinx Inc

Series

Spartan™-XLr

Datasheet

1.XCS05XL-4VQG100C.pdf (83 pages)

Specifications of XCS10XL-5TQ144C

Number Of Logic Elements/cells

466

Number Of Labs/clbs

196

Total Ram Bits

6272

Number Of I /o

112

Number Of Gates

10000

Voltage - Supply

3 V ~ 3.6 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

144-LQFP

Case

TQFP144

02+

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Spartan and Spartan-XL FPGA Families Data Sheet

This high value makes them unsuitable as wired-AND

pull-up resistors.

Table 7: Supported Destinations for Spartan/XL

Outputs

After configuration, voltage levels of unused pads, bonded

or unbonded, must be valid logic levels, to reduce noise

sensitivity and avoid excess current. Therefore, by default,

unused pads are configured with the internal pull-up resistor

active. Alternatively, they can be individually configured with

the pull-down resistor, or as a driven output, or to be driven

by an external source. To activate the internal pull-up, attach

the PULLUP library component to the net attached to the

pad. To activate the internal pull-down, attach the PULL-

DOWN library component to the net attached to the pad.

Set/Reset

As with the CLB registers, the GSR signal can be used to

set or clear the input and output registers, depending on the

value of the INIT attribute or property. The two flip-flops can

be individually configured to set or clear on reset and after

configuration. Other than the global GSR net, no user-con-

trolled set/reset signal is available to the I/O flip-flops

(Figure

tial state of the flip-flop and the response to the GSR pulse.

Independent Clocks

Separate clock signals are provided for the input (IK) and

output (OK) flip-flops. The clock can be independently

inverted for each flip-flop within the IOB, generating either

Notes:

Any device,

CMOS-threshold

inputs

Any device,

TTL-threshold inputs

Any device,

CMOS-threshold

inputs

Only if destination device has 5V tolerant inputs.

Destination

= 3.3V,

= 5V,

5). The choice of set or reset applies to both the ini-

3.3V, CMOS

Spartan-XL

Outputs

√

Unreliable

Data

TTL

5V,

√

Spartan

Outputs

Some

CMOS

5V,

√

www.xilinx.com

(1)

falling-edge or rising-edge triggered flip-flops. The clock

inputs for each IOB are independent.

Common Clock Enables

The input and output flip-flops in each IOB have a common

clock enable input (see EC signal in

through configuration, can be activated individually for the

input or output flip-flop, or both. This clock enable operates

exactly like the EC signal on the Spartan/XL FPGA CLB. It

cannot be inverted within the IOB.

Routing Channel Description

All internal routing channels are composed of metal seg-

ments with programmable switching points and switching

matrices to implement the desired routing. A structured,

hierarchical matrix of routing channels is provided to

achieve efficient automated routing.

This section describes the routing channels available in

Spartan/XL devices.

gram of the CLB routing channels. The implementation soft-

ware automatically assigns the appropriate resources

based on the density and timing requirements of the design.

The following description of the routing channels is for infor-

mation only and is simplified with some minor details omit-

ted. For an exact interconnect description the designer

should open a design in the FPGA Editor and review the

actual connections in this tool.

The routing channels will be discussed as follows;

•

CLB Routing Channels

The routing channels around the CLB are derived from

three types of interconnects; single-length, double-length,

and longlines. At the intersection of each vertical and hori-

zontal routing channel is a signal steering matrix called a

Programmable Switch Matrix (PSM).

basic routing channel configuration showing single-length

lines, double-length lines and longlines as well as the CLBs

and PSMs. The CLB to routing channel interface is shown

as well as how the PSMs interface at the channel intersec-

tions.

CLB routing channels which run along each row and

column of the CLB array.

IOB routing channels which form a ring (called a

VersaRing) around the outside of the CLB array. It

connects the I/O with the CLB routing channels.

Global routing consists of dedicated networks primarily

designed to distribute clocks throughout the device with

minimum delay and skew. Global routing can also be

used for other high-fanout signals.

Figure 8

shows a general block dia-

DS060 (v1.8) June 26, 2008

Product Specification

Figure 8

Figure

shows the

5), which

XCS10XL-5TQ144C Xilinx Inc, XCS10XL-5TQ144C Datasheet - Page 10

XCS10XL-5TQ144C

Specifications of XCS10XL-5TQ144C

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