XC3030L-8VQ64C Xilinx Inc, XC3030L-8VQ64C Datasheet - Page 6

XC3030L-8VQ64C

Manufacturer Part Number

XC3030L-8VQ64C

Description

IC FPGA C-TEMP 3.3V 64-VQFP

Manufacturer

Xilinx Inc

Series

XC3000A/Lr

Datasheet

1.XC3190A-3PC84C.pdf (76 pages)

Specifications of XC3030L-8VQ64C

Number Of Labs/clbs

100

Total Ram Bits

22176

Number Of I /o

Number Of Gates

2000

Voltage - Supply

3 V ~ 3.6 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

64-TQFP

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Number Of Logic Elements/cells

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XC3000 Series Field Programmable Gate Arrays

The input-buffer portion of each IOB provides threshold

detection to translate external signals applied to the pack-

age pin to internal logic levels. The global input-buffer

threshold of the IOBs can be programmed to be compatible

with either TTL or CMOS levels. The buffered input signal

drives the data input of a storage element, which may be

configured as either a flip-flop or a latch. The clocking

polarity (rising/falling edge-triggered flip-flop, High/Low

transparent latch) is programmable for each of the two

clock lines on each of the four die edges. Note that a clock

line driving a rising edge-triggered flip-flop makes any latch

driven by the same line on the same edge Low-level trans-

parent and vice versa ( falling edge, High transparent). All

Xilinx primitives in the supported schematic-entry pack-

ages, however, are positive edge-triggered flip-flops or

High transparent latches. When one clock line must drive

flip-flops as well as latches, it is necessary to compensate

for the difference in clocking polarities with an additional

inverter either in the flip-flop clock input or the latch-enable

input. I/O storage elements are reset during configuration

or by the active-Low chip RESET input. Both direct input

(from IOB pin I) and registered input (from IOB pin Q) sig-

nals are available for interconnect.

For reliable operation, inputs should have transition times

of less than 100 ns and should not be left floating. Floating

CMOS input-pin circuits might be at threshold and produce

oscillations. This can produce additional power dissipation

and system noise. A typical hysteresis of about 300 mV

reduces sensitivity to input noise. Each user IOB includes a

programmable high-impedance pull-up resistor, which may

be selected by the program to provide a constant High for

otherwise undriven package pins. Although the Field Pro-

grammable Gate Array provides circuitry to provide input

protection for electrostatic discharge, normal CMOS han-

dling precautions should be observed.

Flip-flop loop delays for the IOB and logic-block flip-flops

are short, providing good performance under asynchro-

nous clock and data conditions. Short loop delays minimize

the probability of a metastable condition that can result

from assertion of the clock during data transitions. Because

of the short-loop-delay characteristic in the Field Program-

mable Gate Array, the IOB flip-flops can be used to syn-

chronize external signals applied to the device. Once

synchronized in the IOB, the signals can be used internally

without further consideration of their clock relative timing,

except as it applies to the internal logic and routing-path

delays.

IOB output buffers provide CMOS-compatible 4-mA

source-or-sink drive for high fan-out CMOS or TTL- com-

patible signal levels (8 mA in the XC3100A family). The net-

work driving IOB pin O becomes the registered or direct

data source for the output buffer. The 3-state control signal

(IOB) pin T can control output activity. An open-drain output

may be obtained by using the same signal for driving the

7-8

Product Obsolete or Under Obsolescence

output and 3-state signal nets so that the buffer output is

enabled only for a Low.

Configuration program bits for each IOB control features

such as optional output register, logic signal inversion, and

3-state and slew-rate control of the output.

The program-controlled memory cells of

the following options.

• Logic inversion of the output is controlled by one

• Logic 3-state control of each IOB output buffer is

• Direct or registered output is selectable for each IOB.

• Increased output transition speed can be selected to

• An internal high-impedance pull-up resistor (active by

Unlike the original XC3000 series, the XC3000A,

XC3000L, XC3100A, and XC3100L families include the

Soft Startup feature. When the configuration process is fin-

ished and the device starts up in user mode, the first activa-

tion of the outputs is automatically slew-rate limited. This

feature avoids potential ground bounce when all outputs

are turned on simultaneously. After start-up, the slew rate

of the individual outputs is determined by the individual

configuration option.

Summary of I/O Options

• Inputs

• Outputs

configuration program bit per IOB.

determined by the states of configuration program bits

that turn the buffer on, or off, or select the output buffer

3-state control interconnection (IOB pin T). When this

IOB output control signal is High, a logic one, the buffer

is disabled and the package pin is high impedance.

When this IOB output control signal is Low, a logic zero,

the buffer is enabled and the package pin is active.

Inversion of the buffer 3-state control-logic sense

(output enable) is controlled by an additional

configuration program bit.

The register uses a positive-edge, clocked flip-flop. The

clock source may be supplied (IOB pin OK) by either of

two metal lines available along each die edge. Each of

these lines is driven by an invertible buffer.

improve critical timing. Slower transitions reduce

capacitive-load peak currents of non-critical outputs

and minimize system noise.

default) prevents unconnected inputs from floating.

- Direct

- Flip-flop/latch

- CMOS/TTL threshold (chip inputs)

- Pull-up resistor/open circuit

- Direct/registered

- Inverted/not

- 3-state/on/off

- Full speed/slew limited

- 3-state/output enable (inverse)

November 9, 1998 (Version 3.1)

Figure 4

control

XC3030L-8VQ64C Xilinx Inc, XC3030L-8VQ64C Datasheet - Page 6

XC3030L-8VQ64C

Specifications of XC3030L-8VQ64C

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