XQ2V1000 Datasheet, PDF(42/127 Page) Xilinx, Inc – QPro Virtex-II 1.5V Military QML Platform FPGAs

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XQ2V1000 Datasheet, PDF (42/127 Pages) Xilinx, Inc – QPro Virtex-II 1.5V Military QML Platform FPGAs

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QPro Virtex-II 1.5V Military QML Platform FPGAs

Design Implementation

The ISE Series development systems include Xilinx tim-

ing-driven implementation tools, frequently called âplace

and routeâ or âfittingâ software. This robust suite of tools

enables the creation of an intuitive, flexible, tightly inte-

grated design flow that efficiently bridges âlogicalâ and

âphysicalâ design domains. This simplifies the task of defin-

ing a design, including its behavior, timing requirements,

and optional layout (or floorplanning), as well as simplifying

the task of analyzing reports generated during the imple-

mentation process.

The Virtex-II implementation process is comprised of Syn-

thesis, translation, mapping, place and route, and configu-

ration file generation. While the tools can be run individually,

many designers choose to run the entire implementation

process with the click of a button. To assist those who prefer

to script their design flows, Xilinx provides Xflow, an auto-

mated single command line process.

Design Verification

In addition to conventional design verification using static

timing analysis or simulation techniques, Xilinx offers pow-

erful in-circuit debugging techniques using ChipScope ILA

(Integrated Logic Analysis). The reconfigurable nature of

Xilinx FPGAs means that designs can be verified in real

time without the need for extensive sets of software simula-

tion vectors.

For simulation, the system extracts post-layout timing infor-

mation from the design database, and back-annotates this

information into the netlist for use by the simulator. The back

annotation features a variety of patented Xilinx techniques,

resulting in the industryâs most powerful simulation flows.

Alternatively, timing-critical portions of a design can be ver-

ified using the Xilinx static timing analyzer or a third party

static timing analysis tool like Synopsys Prime Time, by

exporting timing data in the STAMP data format.

For in-circuit debugging, ChipScope ILA enables designers

to analyze the real-time behavior of a device while operating

at full system speeds. Logic analysis commands and cap-

tured data are transferred between the ChipScope software

and ILA cores within the Virtex-II FPGA, using industry

standard JTAG protocols. These JTAG transactions are

driven over an optional download cable (MultiLINX or

JTAG), connecting the Virtex device in the target system to

a PC or workstation.

ChipScope ILA was designed to look and feel like a logic

analyzer, making it easy to begin debugging a design imme-

diately. Modifications to the desired logic analysis can be

downloaded directly into the system in a matter of minutes.

Other Unique Features of Virtex-II Design

Flow

Xilinx design flows feature a number of unique capabilities.

Among these are efficient incremental HDL design flows,

which are robust capabilities enabled by Xilinx exclusive

hierarchical floorplanning capabilities. Another powerful

design capability only available in the Xilinx design flow is

âModular Designâ, part of the Xilinx suite of team design

tools, which enables autonomous design, implementation,

and verification of design modules.

Incremental Synthesis

Xilinx unique hierarchical floorplanning capabilities enable

designers to create a programmable logic design by isolat-

ing design changes within one hierarchical âlogic blockâ,

and perform synthesis, verification, and implementation

processes on that specific logic block. By preserving the

logic in unchanged portions of a design, Xilinx incremental

design makes the high-density design process more effi-

cient.

Xilinx hierarchical floorplanning capabilities can be speci-

fied using the high-level floorplanner or a preferred RTL

floorplanner (see the Xilinx website for a list of supported

EDA partners). When used in conjunction with one of the

EDA partnersâ floorplanners, higher performance results

can be achieved, as many synthesis tools use this more

predictable detailed physical implementation information to

establish more aggressive and accurate timing estimates

when performing their logic optimizations.

Modular Design

Xilinx innovative modular design capabilities take the incre-

mental design process one step further by enabling the

designer to delegate responsibility for completing the

design, synthesis, verification, and implementation of a hier-

archical âlogic blockâ to an arbitrary number of designers -

assigning a specific region within the target FPGA for exclu-

sive use by each of the team members.

This team design capability enables an autonomous

approach to design modules, changing the hand-off point to

the lead designer or integrator from âmy module works in

simulationâ to âmy module works in the FPGAâ. This unique

design methodology also leverages the Xilinx hierarchical

floorplanning capabilities and enables the Xilinx (or EDA

partner) floorplanner to manage the efficient implementa-

tion of very high-density FPGAs.

Configuration

Virtex-II devices are configured by loading application-spe-

cific configuration data into the internal configuration mem-

ory. Configuration is carried out using a subset of the device

pins, some of which are dedicated, while others can be

re-used as general purpose inputs and outputs once config-

uration is complete.

Depending on the system design, several configuration

modes are supported, selectable via mode pins. The mode

pins M2, M1, and M0 are dedicated pins. An additional pin,

HSWAP_EN, is used in conjunction with the mode pins to

select whether user I/O pins have pull-ups during configura-

www.xilinx.com

DS122 (v1.1) January 7, 2004

1-800-255-7778

Product Specification

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