EPF10K200SBC356-2 Altera, EPF10K200SBC356-2 Datasheet - Page 18

EPF10K200SBC356-2

Manufacturer Part Number

EPF10K200SBC356-2

Description

FLEX 10KE

Manufacturer

Altera

Datasheets

1.EPF10K50STC144-2.pdf (100 pages)

2.EPF10K50STC144-2.pdf (100 pages)

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FLEX 10KE Embedded Programmable Logic Devices Data Sheet

The programmable flipflop in the LE can be configured for D, T, JK, or SR

operation. The clock, clear, and preset control signals on the flipflop can

be driven by global signals, general-purpose I/O pins, or any internal

logic. For combinatorial functions, the flipflop is bypassed and the output

of the LUT drives the output of the LE.

The LE has two outputs that drive the interconnect: one drives the local

interconnect and the other drives either the row or column FastTrack

Interconnect routing structure. The two outputs can be controlled

independently. For example, the LUT can drive one output while the

improve LE utilization because the register and the LUT can be used for

unrelated functions.

The FLEX 10KE architecture provides two types of dedicated high-speed

data paths that connect adjacent LEs without using local interconnect

paths: carry chains and cascade chains. The carry chain supports

high-speed counters and adders and the cascade chain implements

wide-input functions with minimum delay. Carry and cascade chains

connect all LEs in a LAB as well as all LABs in the same row. Intensive use

of carry and cascade chains can reduce routing flexibility. Therefore, the

use of these chains should be limited to speed-critical portions of a design.

Carry Chain

The carry chain provides a very fast (as low as 0.2 ns) carry-forward

function between LEs. The carry-in signal from a lower-order bit drives

forward into the higher-order bit via the carry chain, and feeds into both

the LUT and the next portion of the carry chain. This feature allows the

FLEX 10KE architecture to implement high-speed counters, adders, and

comparators of arbitrary width efficiently. Carry chain logic can be

created automatically by the Altera Compiler during design processing,

or manually by the designer during design entry. Parameterized functions

such as LPM and DesignWare functions automatically take advantage of

carry chains.

Carry chains longer than eight LEs are automatically implemented by

linking LABs together. For enhanced fitting, a long carry chain skips

alternate LABs in a row. A carry chain longer than one LAB skips either

from even-numbered LAB to even-numbered LAB, or from odd-

numbered LAB to odd-numbered LAB. For example, the last LE of the

first LAB in a row carries to the first LE of the third LAB in the row. The

carry chain does not cross the EAB at the middle of the row. For instance,

in the EPF10K50E device, the carry chain stops at the eighteenth LAB and

a new one begins at the nineteenth LAB.

Altera Corporation

EPF10K200SBC356-2 Altera, EPF10K200SBC356-2 Datasheet - Page 18

EPF10K200SBC356-2

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