HI5714EVAL Intersil, HI5714EVAL Datasheet - Page 9

HI5714EVAL

Manufacturer Part Number

HI5714EVAL

Description

EVALUATION PLATFORM HI5714

Manufacturer

Intersil

Datasheets

1.HI57144CBZ.pdf (14 pages)

2.HI5714EVAL.pdf (11 pages)

Specifications of HI5714EVAL

Number Of Adc's

Number Of Bits

Sampling Rate (per Second)

75M

Data Interface

Parallel

Inputs Per Adc

1 Single Ended

Input Range

2.7 Vpp

Power (typ) @ Conditions

325mW @ 75MSPS

Voltage Supply Source

Analog and Digital

Operating Temperature

0°C ~ 70°C

Utilized Ic / Part

HI5714

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Detailed Description

Theory of Operation

The HI5714 design utilizes a folding and interpolating

architecture. This architecture reduces the number of

comparators, reference taps, and latches, thereby reducing

power requirements, die size and cost.

subranging converter by using 2 lower resolution converters

to do a course and subranged fine conversion. A more

complete description is given in the application note “Using

the HI5714 Evaluation Module” (AN9517).

Reference Input, V

The HI5714 requires an external reference to be connected

to pins 4 and 9, V

It is recommended that adequate high frequency decoupling

be provided at the reference input pin in order to minimize

overall converter noise. A 0.1µF and a 1nF capacitor as

close as possible to the reference pins work well.

within 1.2V to 1.6V. If the reference voltages go outside their

respective ranges, the input folding amplifiers may saturate

giving erroneous digital data. The range for (V

1.9V to 2.7V, which defines the analog input range.

Digital Control and Clock Requirements

The HI5714 provides a standard high-speed interface to

external TTL logic families.

The outputs can be three-stated by setting the OE input (pin

22) high.

The clock input operates at standard TTL levels as well as a

low level sine wave around the threshold level. The HI5714

can operate with clock frequencies from DC to 75MHz. The

clock duty cycle should be 50% ±10% to ensure rated

performance. Duty cycle variation, within the specified

range, has little effect on performance. Due to the clock

speed it is important to remember that clock jitter will affect

the quality of the digital output data.

The clock can be stopped at any time and restarted at a later

time. Once restarted the digital data will be valid at the

second rising edge of the clock plus the data delay time.

Digital Outputs and O/UF Output

The digital outputs are standard TTL type outputs. The

HI5714 can drive 1 to 3 TTL inputs depending on the input

current requirements.

Should the analog input exceed the top or bottom reference

the over/underflow output (pin 11) will go high. Should the

analog input exceed the top reference voltage, V

digital outputs will remain at all 1s until the analog input goes

below V

A folding A/D converter operates basically like a 2 step

must be kept within the range of 3.5V to 3.9V and V

. Also, should the analog input go below the

and V

- V

, the

) is

HI5714

bottom reference voltage, V

remain at all 0s until the analog input goes above V

Analog Input

The analog input will accept a voltage within the reference

voltage levels, V

is specified in the Electrical Specifications table.

The analog input is relatively high impedance (10kΩ) but

should be driven from a low impedance source. The input

capacitance is low (14pF) and there is little kickback from the

input, so a series resistance is not necessary but it may help

to prevent the driving amplifier from oscillating.

The input bandwidth is typically 18MHz. Exceeding 18MHz

will result in sparkle at the digital outputs. The bandwidth

remains constant at clock rates up to 75MHz.

Supply and Ground Considerations

In order to keep digital noise out of the analog signal path,

the HI5714 has separate analog and digital supply and

ground pins. The part should be mounted on a board that

provides separate low impedance connections for the analog

and digital supplies and grounds.

The analog and digital grounds should be tied together at

one point near the HI5714. The grounds can be connected

directly, through an inductor (ferrite bead), or a low valued

resistor. DGND and AGND can be tied together. To help

minimize noise, tie pin 5 (NC) to AGND and pins 3 (NC) and

10 (NC) to DGND.

For best performance, the supplies to the HI5714 should be

driven by clean, linear regulated supplies. The board should

also have good high frequency leaded decoupling capacitors

mounted as close as possible to the converter. Capacitor

leads must be kept as short as possible (less than

total length). A 0.1µF and a 1nF capacitor as close as

possible to the pin works well. Chip capacitors will provide

better high frequency decoupling but leaded capacitors

appear to be adequate.

If the part is to be powered by a single supply, then the

analog supply pins should be isolated by ferrite beads from

the digital supply pins. This should help minimize noise on

the analog power pins.

Refer to Application Note AN9214, “Using Intersil High

Speed A/D Converters”, for additional considerations when

using high speed converters.

Increased Accuracy

Further calibration of the ADC can be done to increase

absolute level accuracy. First, a precision voltage equal to

the ideal VIN

until the 0 to 1 transition occurs on the digital output. Next, a

voltage equal to the ideal VIN

the digital output.

is then adjusted until the 254 to 255 transition occurs on

-FS

+ 0.5 LSB is applied at V

and V

, minus some offset. The offset

+FS

, the digital outputs will

- 1.5 LSB is applied at V

. Adjust V

inch

HI5714EVAL Intersil, HI5714EVAL Datasheet - Page 9

HI5714EVAL

Specifications of HI5714EVAL

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