HI5760EVAL1 Intersil, HI5760EVAL1 Datasheet - Page 2

HI5760EVAL1

Manufacturer Part Number

HI5760EVAL1

Description

EVALUATION PLATFORM SOIC HI5760

Manufacturer

Intersil

Datasheets

1.HI57606IBZ.pdf (18 pages)

2.HI5760EVAL1.pdf (8 pages)

Specifications of HI5760EVAL1

Number Of Dac's

Number Of Bits

Outputs And Type

1, Differential

Sampling Rate (per Second)

125M

Data Interface

Parallel

Settling Time

35ns

Dac Type

Current

Voltage Supply Source

Analog and Digital

Operating Temperature

-40°C ~ 85°C

Utilized Ic / Part

HI5760

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Functional Description

Voltage Reference

The HI5760 has an internal 1.2V voltage reference with a

of the converter. The REFLO pin (16) selects the reference.

Access to pin 16 is provided through the center pin of

Jumper J2. To enable the internal reference, it is necessary

that the jumper be placed such that pin 16 is grounded (if

facing the evaluation board so that the SMAs are on the

user’s left-hand side, then the jumper should be placed in

the ‘right’ position of the three-stemmed jumper). The

REFIO pin (17) provides access to the internal voltage

reference, or can be overdriven if the user wishes to use an

external source for the reference. Notice that a 0.1 F

capacitor is placed as close as possible to the REFIO pin.

This capacitor is necessary for ensuring a noise free

reference voltage. If the user wishes to use an external

reference voltage, jumper J3 must be in place and an

external voltage reference provided via SMA1, labeled

‘EXT REF’. The recommended limits of the external

reference are between 15mV and 1.2V. Performance of the

converter can be expected to decline as the reference

voltage is reduced due to the reduction in LSB voltage size.

If the user wants to amplitude modulate the DAC, they can

overdrive the REFIO pin with a waveform. The input

multiplying bandwidth of the REFIO input is approximately

1.4MHz. It is necessary that the multiplying signal be DC

offset so that the minimum and maximum peaks of the

signal do not exceed the limits imposed above. Jumper J2

must be changed so that pin 16 is tied high (the supply

voltage, which is the ‘left’ position of J2) when using an

external reference. The output current of the converter,

IOUTA and IOUTB, is a function of the voltage reference

used and the value of R

Outputs

The output current of the device is set by choosing R

and V

between 2mA and 20mA:

For example, using the internal V

(R14 on the schematic) value of 1.91k results in an I

of approximately 20mA (maximum allowed). Choose the

output loading so that the ‘Output Voltage Compliance

Range’ is not violated (0 to 1.25V). If an external V

chosen, it should not exceed +1.2V.

The output can be conﬁgured to drive a load resistor, a

transformer, an operational ampliﬁer, or any other type of

output conﬁguration so long as the output voltage

compliance range and the maximum output current is not

violated.

OUT

60ppm/

= 32 x V

REF

C drift coefficient over the full temperature range

such that the resultant of the following equation is

REF

SET.

SET

3-2

(R14 on the schematic).

REF

of 1.2V and an R

Application Notes 9821

REF

SET

OUT

SET

Load Resistor Output

The evaluation board comes with the simple resistor load

output conﬁguration. Both IOUTA and IOUTB have a 50

resistor connected to ground next to their respective SMAs.

See the attached schematic for clariﬁcation.

Sleep

The converter can be put into ‘sleep’ mode by connecting pin

15 to either of the converter’s supply voltages. For normal

operation, it is recommended that pin 15 be tied to ground.

However, the sleep pin does have an active pulldown

current, so the pin can be left disconnected for normal

operation. On the evaluation board, jumper J1 is provided for

controlling the sleep pin. Remove the jumper from J1 for

normal operation and replace it for sleep mode.

Power Supply(s) and Ground(s)

The user can operate from either a single supply or dual

supplies. The DAC is designed to function with the digital

and analog voltages at the same value. The evaluation

board contains two power supply connections to allow for

measuring the current drawn from the digital and analog

sections independently. For single supply mode, it is

recommended that a single power supply wire be attached

to either DV

from E2 to E3 (holes). A single ground wire should be

attached to either DCOM1 or ACOM1 from the power supply.

These grounds are identical, as the evaluation board uses a

single ground plane. The user can select to use dual ground

planes in their design connected at a single point near the

converter (this is the recommended conﬁguration). For dual

supply mode, connect a power supply wire to both AV

and DV

independently.

Getting Started

A summary of the external supplies, equipment, and signal

sources needed to operate the board is given below:

Attach a +5V power supply to the evaluation board. Connect

the 10 input bits from the data generator to the evaluation

board, preferably by using a male, 64 or 96-pin VME (Versa

Module Eurocard) connector that mates with the eval board.

Connect the clock source to the eval board, also preferably

through the 64-pin connector. Failure to make clean and

short connections to the data input lines and clock source

will result in a decrease in spectral performance.

1. +5V for HI5760.

2. Data generator capable of generating 10-bit patterns. The

3. Square wave clock source (usually part of the Data

4. Spectrum analyzer or oscilloscope for viewing the output

HSP-EVAL with the HSP45116 NCOM daughter board is

an option (see ‘Learning Your Way Around’).

Generator).

of the converter.

DD1

and ground wires to DCOM1 and ACOM1

or AV

DD1

, and then a jumper wire placed

DD1

HI5760EVAL1 Intersil, HI5760EVAL1 Datasheet - Page 2

HI5760EVAL1

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