EPF10K10QC208-3N Altera, EPF10K10QC208-3N Datasheet - Page 10

EPF10K10QC208-3N

Manufacturer Part Number

EPF10K10QC208-3N

Description

IC PLD 576 MACROCELL 60MHZ QFP-208

Manufacturer

Altera

Series

FLEX 10Kr

Datasheet

1.EPF10K10ATC100-3.pdf (128 pages)

Specifications of EPF10K10QC208-3N

No. Of Macrocells

576

No. Of I/o's

134

Global Clock Setup Time

1.3ns

Frequency

60MHz

Supply Voltage Range

4.75V To 5.25V

Operating Temperature Range

0Â°C To +70Â°C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Part Number:

EPF10K10QC208-3N

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Company:

BOSTOCK HK LIMITED

Part Number:

EPF10K10QC208-3N

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FLEX 10K Embedded Programmable Logic Device Family Data Sheet

Logic functions are implemented by programming the EAB with a read-

only pattern during configuration, creating a large LUT. With LUTs,

combinatorial functions are implemented by looking up the results, rather

than by computing them. This implementation of combinatorial functions

can be faster than using algorithms implemented in general logic, a

performance advantage that is further enhanced by the fast access times

of EABs. The large capacity of EABs enables designers to implement

complex functions in one logic level without the routing delays associated

with linked LEs or field-programmable gate array (FPGA) RAM blocks.

For example, a single EAB can implement a 4 4 multiplier with eight

inputs and eight outputs. Parameterized functions such as LPM functions

can automatically take advantage of the EAB.

The EAB provides advantages over FPGAs, which implement on-board

RAM as arrays of small, distributed RAM blocks. These FPGA RAM

blocks contain delays that are less predictable as the size of the RAM

increases. In addition, FPGA RAM blocks are prone to routing problems

because small blocks of RAM must be connected together to make larger

blocks. In contrast, EABs can be used to implement large, dedicated blocks

of RAM that eliminate these timing and routing concerns.

EABs can be used to implement synchronous RAM, which is easier to use

than asynchronous RAM. A circuit using asynchronous RAM must

generate the RAM write enable (WE) signal, while ensuring that its data

and address signals meet setup and hold time specifications relative to the

WE signal. In contrast, the EAB’s synchronous RAM generates its own WE

signal and is self-timed with respect to the global clock. A circuit using the

EAB’s self-timed RAM need only meet the setup and hold time

specifications of the global clock.

When used as RAM, each EAB can be configured in any of the following

sizes: 256 8, 512

4, 1,024 2, or 2,048

1. See

Figure

Figure 2. EAB Memory Configurations

2,048 1

256

512

1,024 2

Altera Corporation

EPF10K10QC208-3N Altera, EPF10K10QC208-3N Datasheet - Page 10

EPF10K10QC208-3N

Specifications of EPF10K10QC208-3N

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