EPM7160SQC160-10N Altera, EPM7160SQC160-10N Datasheet - Page 11

IC PLD EEPROM 160 MACROCELL 10NS QFP-160

EPM7160SQC160-10N

Manufacturer Part Number

EPM7160SQC160-10N

Description

IC PLD EEPROM 160 MACROCELL 10NS QFP-160

Manufacturer

Altera

Series

MAX 7000Sr

Datasheet

1.EPM7064STC44-10.pdf (66 pages)

Specifications of EPM7160SQC160-10N

Cpld Type

EEPROM

No. Of Macrocells

160

No. Of I/o's

104

Propagation Delay

10ns

Global Clock Setup Time

3.4ns

Frequency

149.3MHz

Supply Voltage Range

4.75V To 5.25V

Family Name

MAX 7000S

Memory Type

EEPROM

# Macrocells

160

Number Of Usable Gates

3200

Frequency (max)

125MHz

Propagation Delay Time

10ns

Number Of Logic Blocks/elements

# I/os (max)

104

Operating Supply Voltage (typ)

In System Programmable

Yes

Operating Supply Voltage (min)

4.75V

Operating Supply Voltage (max)

5.25V

Operating Temp Range

0C to 70C

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Pin Count

160

Package Type

PQFP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

EPM7160SQC160-10N

Manufacturer:

Altera

Quantity:

10 000

Company:

BOSTOCK HK LIMITED

Part Number:

EPM7160SQC160-10N

Manufacturer:

ALTERA

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Each programmable register can be clocked in three different modes:

■

In EPM7032, EPM7064, and EPM7096 devices, the global clock signal

is available from a dedicated clock pin, GCLK1, as shown in

In MAX 7000E and MAX 7000S devices, two global clock signals are

available. As shown in

true or the complement of either of the global clock pins, GCLK1 or

GCLK2.

Each register also supports asynchronous preset and clear functions.

As shown in

product terms to control these operations. Although the

product-term-driven preset and clear of the register are active high,

active-low control can be obtained by inverting the signal within the

logic array. In addition, each register clear function can be

individually driven by the active-low dedicated global clear pin

(GCLRn). Upon power-up, each register in the device will be set to a

low state.

All MAX 7000E and MAX 7000S I/O pins have a fast input path to a

macrocell register. This dedicated path allows a signal to bypass the

PIA and combinatorial logic and be driven to an input D flipflop with

an extremely fast (2.5 ns) input setup time.

Expander Product Terms

Although most logic functions can be implemented with the five

product terms available in each macrocell, the more complex logic

functions require additional product terms. Another macrocell can

be used to supply the required logic resources; however, the

MAX 7000 architecture also allows both shareable and parallel

expander product terms (“expanders”) that provide additional

product terms directly to any macrocell in the same LAB. These

expanders help ensure that logic is synthesized with the fewest

possible logic resources to obtain the fastest possible speed.

By a global clock signal. This mode achieves the fastest clock-to-

output performance.

By a global clock signal and enabled by an active-high clock

enable. This mode provides an enable on each flipflop while still

achieving the fast clock-to-output performance of the global

clock.

By an array clock implemented with a product term. In this

mode, the flipflop can be clocked by signals from buried

macrocells or I/O pins.

Figures 3

MAX 7000 Programmable Logic Device Family Data Sheet

and 4, the product-term select matrix allocates

Figure

2, these global clock signals can be the

Figure

EPM7160SQC160-10N Altera, EPM7160SQC160-10N Datasheet - Page 11

EPM7160SQC160-10N

Specifications of EPM7160SQC160-10N

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