R

IEEE

Institute of Electrical and Electronics Engineers.Pronounced I triple E.

IFD

IFD is an IOB flip-flop.

impedance

Impedance is the sum of all resistance and reactance of a circuit to the flow of alternating current.

implementation

Implementation is the mapping, placement and routing of a design. A phase in the design process during which the design is placed and routed.

incremental design

Incremental design refers to the implementation and verification of a small design change using a guide file.

indexes

Indexes are the left-most and right-most bits of a bus defining the bus range and precision.

inertial delay

If the pulse width of a signal is smaller than the path delay (from an input port to an output port) then an inertial delay does not propogate the pulse event through to the output port. This is known as pulse swallowing.

input

An input is the symbol port through which data is sourced.

input pad registers and latches

Input pad registers and latches are D-type registers located in the I/O pad sections of the device. Input pad registers can be used instead of macrocell resources.

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Development System Reference Guide

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Xilinx 8.2i manual Ieee, Ifd

8.2i specifications

Xilinx 8.2i is a significant version of the Xilinx ISE (Integrated Software Environment) that emerged in the early 2000s, marking an important milestone in the world of FPGA (Field-Programmable Gate Array) development. This version introduced a slew of advanced features, technologies, and characteristics that made it an indispensable tool for engineers and developers in designing, simulating, and implementing digital circuits.

One of the standout features of Xilinx 8.2i is its enhanced design entry capabilities. This version supports multiple design entry methods, including schematic entry, VHDL, and Verilog HDL, giving engineers the flexibility to choose their preferred approach. The integrated environment provides user-friendly graphical interfaces, making it accessible for both novice and experienced users.

Xilinx 8.2i's synthesis tools have been improved to enable more efficient design compilation and optimization. The new algorithms used in this version facilitate faster synthesis times while reducing power consumption and improving performance. Furthermore, it features support for advanced FPGA architectures, which allows for the implementation of more complex designs with greater efficiency.

The implementation tools in Xilinx 8.2i include advanced place and route capabilities, utilizing state-of-the-art algorithms for optimized resource usage. These tools enable designers to make better use of FPGA resources, ensuring that designs fit within the constraints of the target device while maximizing performance.

Another key characteristic of Xilinx 8.2i is its extensive support for various Xilinx devices such as the Spartan, Virtex, and CoolRunner series. This compatibility ensures that developers can leverage the powerful features of these FPGA families, including high-speed transceivers and DSP slices.

Xilinx 8.2i also places a strong emphasis on simulation and verification. The version integrates with various simulation tools, allowing for thorough testing of the designs before implementation. This reduces the risk of errors and ensures that the final product meets specifications.

In addition, this version includes support for design constraints, enabling engineers to specify timing, area, and other critical design parameters. By accommodating constraints, Xilinx 8.2i helps in achieving reliable and efficient designs tailored to project needs.

In summary, Xilinx 8.2i is a robust software development tool that enhances the design process for FPGAs. Its comprehensive features, including multiple design entry options, advanced synthesis and implementation tools, extensive device support, and strong simulation capabilities, make it a valuable resource for engineers and developers striving for innovation in digital design.