LFXP6C-5F256C LATTICE SEMICONDUCTOR, LFXP6C-5F256C Datasheet - Page 25

LFXP6C-5F256C

Manufacturer Part Number

LFXP6C-5F256C

Description

FPGA LatticeXP Family 6000 Cells 400MHz 130nm (CMOS) Technology 1.8V/2.5V/3.3V 256-Pin FBGA Tray

Manufacturer

LATTICE SEMICONDUCTOR

Datasheet

1.LFXP3C-3QN208C.pdf (130 pages)

Specifications of LFXP6C-5F256C

Package

256FBGA

Family Name

LatticeXP

Device Logic Units

6000

Maximum Internal Frequency

400 MHz

Typical Operating Supply Voltage

1.8|2.5|3.3 V

Maximum Number Of User I/os

188

Ram Bits

73728

Re-programmability Support

Yes

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Architecture

Lattice Semiconductor

LatticeXP Family Data Sheet

Polarity Control Logic

In a typical DDR Memory interface design, the phase relation between the incoming delayed DQS strobe and the

internal system Clock (during the READ cycle) is unknown.

The LatticeXP family contains dedicated circuits to transfer data between these domains. To prevent setup and

hold violations at the domain transfer between DQS (delayed) and the system Clock a clock polarity selector is

used. This changes the edge on which the data is registered in the synchronizing registers in the input register

block. This requires evaluation at the start of the each READ cycle for the correct clock polarity.

Prior to the READ operation in DDR memories DQS is in tristate (pulled by termination). The DDR memory device

drives DQS low at the start of the preamble state. A dedicated circuit detects this transition. This signal is used to

control the polarity of the clock to the synchronizing registers.

sysIO Buffer

Each I/O is associated with a flexible buffer referred to as a sysIO buffer. These buffers are arranged around the

periphery of the device in eight groups referred to as Banks. The sysIO buffers allow users to implement the wide

variety of standards that are found in today’s systems including LVCMOS, SSTL, HSTL, LVDS and LVPECL.

sysIO Buffer Banks

LatticeXP devices have eight sysIO buffer banks; each is capable of supporting multiple I/O standards. Each sysIO

bank has its own I/O supply voltage (V

), and two voltage references V

and V

resources allowing each

CCIO

REF1

REF2

bank to be completely independent from each other. Figure 2-28 shows the eight banks and their associated sup-

plies.

In the LatticeXP devices, single-ended output buffers and ratioed input buffers (LVTTL, LVCMOS, PCI and PCI-X) are

powered using V

. LVTTL, LVCMOS33, LVCMOS25 and LVCMOS12 can also be set as a fixed threshold input

CCIO

independent of V

In addition to the bank V

supplies, the LatticeXP devices have a V

core logic power sup-

CCIO.

CCIO

ply, and a V

supply that power all differential and referenced buffers.

CCAUX

Each bank can support up to two separate VREF voltages, VREF1 and VREF2 that set the threshold for the refer-

enced input buffers. In the LatticeXP devices, a dedicated pin in a bank can be configured to be a reference voltage

supply pin. Each I/O is individually configurable based on the bank’s supply and reference voltages.

2-22

LFXP6C-5F256C LATTICE SEMICONDUCTOR, LFXP6C-5F256C Datasheet - Page 25

LFXP6C-5F256C

Specifications of LFXP6C-5F256C

Available stocks

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