EP1S20F780I6N Altera, EP1S20F780I6N Datasheet - Page 502

EP1S20F780I6N

Manufacturer Part Number

EP1S20F780I6N

Description

IC STRATIX FPGA 20K LE 780-FBGA

Manufacturer

Altera

Series

Stratix®r

Datasheets

1.EP1S10F484I6N.pdf (864 pages)

2.EP1S20F780I6N.pdf (276 pages)

Specifications of EP1S20F780I6N

Number Of Logic Elements/cells

18460

Number Of Labs/clbs

1846

Total Ram Bits

1669248

Number Of I /o

586

Voltage - Supply

1.425 V ~ 1.575 V

Mounting Type

Surface Mount

Operating Temperature

-40°C ~ 100°C

Package / Case

780-FBGA

Family Name

Stratix

Number Of Logic Blocks/elements

18460

# I/os (max)

586

Frequency (max)

450.05MHz

Process Technology

0.13um (CMOS)

Operating Supply Voltage (typ)

1.5V

Logic Cells

18460

Ram Bits

1669248

Operating Supply Voltage (min)

1.425V

Operating Supply Voltage (max)

1.575V

Operating Temp Range

-40C to 100C

Operating Temperature Classification

Industrial

Mounting

Surface Mount

Pin Count

780

Package Type

FC-FBGA

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Number Of Gates

Lead Free Status / Rohs Status

Compliant

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Part Number:

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Part Number:

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Source-Synchronous Timing Budget

Source-

Synchronous

Timing Budget

5–30

Stratix Device Handbook, Volume 2

■

This section discusses the timing budget, waveforms, and specifications

for source-synchronous signaling in Stratix devices. LVDS, LVPECL,

PCML, and HyperTransport I/O standards enable high-speed data

transmission. This high data-transmission rate results in better overall

system performance. To take advantage of fast system performance, you

must understand how to analyze timing for these high-speed signals.

Timing analysis for the differential block is different from traditional

synchronous timing analysis techniques.

Rather than focusing on clock-to-output and setup times, source-

synchronous timing analysis is based on the skew between the data and

the clock signals. High-speed differential data transmission requires you

to use timing parameters provided by IC vendors and to consider board

skew, cable skew, and clock jitter. This section defines the source-

synchronous differential data orientation timing parameters, and timing

budget definitions for Stratix devices, and explains how to use these

timing parameters to determine a design's maximum performance.

Differential Data Orientation

There is a set relationship between an external clock and the incoming

data. For operation at 840 Mbps and W = 10, the external clock is

multiplied by 10 and phase-aligned by the PLL to coincide with the

sampling window of each data bit. The third falling edge of high-

frequency clock is used to strobe the incoming high-speed data.

Therefore, the first two bits belong to the previous cycle.

shows the data bit orientation of the ×10 mode as defined in the

Quartus II software.

After the pattern detection state machine, use another synchronizing

the

Since the skew in the path from the output of this synchronizing

pulse that is high for two

Since the SYNC generator circuitry only generates a single fast clock

period pulse for each SYNC pulse, you cannot generate additional

SYNC pulses until the comparator signal is reset low.

To guarantee the pattern detection state machine does not incorrectly

generate multiple SYNC pulses to shift a single bit, the state machine

must hold the SYNC signal low for at least three

between pulses.

1 clock.

1 clock periods.

1 clock periods

Altera Corporation

Figure 5–23

July 2005

EP1S20F780I6N Altera, EP1S20F780I6N Datasheet - Page 502

EP1S20F780I6N

Specifications of EP1S20F780I6N

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