HI5721BIB - Intersil Corporation

Using the HI5721 Evaluation Module

Introduction

The HI5721 is a 10-bit 125MHz Digital to Analog Converter.

This current out DAC is designed for low glitch and high Spu-

rious Free Dynamic Range operation. This DAC is ideally

suited for Signal Reconstruction and DDS (Direct Digital

Synthesis) applications due to it’s inherent low noise design.

Architecture

The HI5721 DAC is designed with a split architecture to min-

imize glitch while maximizing linearity. Figure 1 shows the

functional architecture of the device. The 6 least signiﬁcant

bits of the converter are derived by a traditional R/2R net-

work to binaurally weight the 1mA current sources. The

upper 4, most signiﬁcant bits are implemented as seg-

mented or thermometer encoded current sources. The ther-

mometer encoder converts the incoming 4 bits to 15 control

lines to enable the most signiﬁcant current sources.

As shown in Figure 2 the thermometer encoder translates the

4 bit binary input data into a decode that enables individual

current sources. For example a binary code of 0110 on the

data bits D6 thru D9 will enable current sources I1, I2, I3, I4,

I5, and I6. The thermometer encoding architecture ensures

good linearity without laser trimming. Also, compared to a

straight R/2R design, the worst case glitch is greatly reduced

since creating the MSB current is the sum of current sources

I1 thru I8. Overall glitch is reduced by a factor of 16. This also

reduces the theoretical switching skew from current source to

current source by using identically sized switches with identi-

cal gain, leakage, and transient responses.

FIGURE 1. BLOCK DIAGRAM

UPPER

10-BIT

REF IN

IOUT

CLK

-AVEE AGND -DVEE DGND

4-BIT

DECODER

R/2R

NETWORK

VCC

IOUT

QUADRATURE

LOGIC

DATA

BUFFER/

LEVEL

SHIFTER

-CTRL AMP

REF OUT RSET CTRL AMP IN

25Ω

6 LSB’S

CURRENT

CELLS

SWITCHED

CURRENT

CELLS

VOLTAGE

REFERENCE

(LSB) D0

(MSB) D9

INVERT

OUT

Application Note May 1995 AN9410.1

FIGURE 2. THERMOMETER ENCODER

Designing to Minimize Glitch

One cause of Glitch is the time skew between bits of the

incoming digital data. Typically the switching time of digital

inputs are asymmetrical meaning that the turn off time is

faster than the turn on time. Unequal delay paths through the

device can cause one current source to change before

another. To minimize this, the Intersil HI5721 employes an

internal register just prior to the current sources updated on

the rising clock edge. In traditional DACs the worst case glitch

usually happens at the major transition i.e. 01 1111 1111 to

10 0000 0000. But in the HI5721 the worst case glitch is

moved to the 00 0001 1111 to 11 1110 0000 transition. This is

achieved by the split R/2R segmented current source archi-

tecture. This decreases the amount of current switching at any

one time and reduces the glitch by a factor of 16.

Since the glitch is a transient event, this leads designers to

believe that a simple low pass filter can be used to eliminate or

reduce the size of the glitch. In effect low pass filtering a glitch

tends to “smear” the event and does little to remove the energy of

the transient.

FIGURE 3. GLITCH AREA

Input Timing/Logic Levels

The HI5721 has a maximum clock rate speciﬁcation of

100MHz. The data setup time before the 50% point of the

rising edge of the clock is tS= 1.2ns (MIN) and the hold time

is tH= 0.5ns (MIN). Logic levels are 0.8V (MAX) for an input

low and 2.0V (MIN) for a logic high. The HI5721 is both TTL

and CMOS input compatible.

FIGURE 4. HI5721 DATA TIMING

INVERT Control Pin

The INVERT control pin is used to enable the internal

quadrature logic on the data bits. The internal quadrature

logic feature is used to reduce the amount of memory store

in a given Numerically Controlled Oscillator (NCO). The

NCO need only store one quadrant of the sine wave data

and use the invert pin to create the remaining 3 quadrants of

the sine wave.

FIGURE 5. USING THE INTERNAL QUADRATURE LOGIC

To use the internal quadrature logic simply connect the

INVERT pin to bit D9 of the HI5721 DAC. In normal opera-

tion INVERT should be connected to 0V or Digital Ground.

BIT 9

(MSB)

I10

I11

I12

I13

I14

I15

I16

SUMMING

JUNCTION (IOUT)

4-BIT BINARY

THERMOMETER

ENCODER

BIT 8

BIT 7

BIT 6

t(ps)

HEIGHT (H)

WIDTH (W)

GLITCH AREA = 1/2 (H X W)

CLK

D9 - D0

INV

1 QUADRANT

DATA

OF SINE WAVE

Application Note 9410

Integral Linearity

The HI5721 has a FSR range of 20.48mA. When driving an

equivalent 50Ωload the fullscale voltage swing is 0V to +1.024V.

Most video and communication applications use a 1VP-P voltage

swing which yields 20mA full scale current sink capability. With a

1VP-P voltage s wing on the HI5721 output an LSB is:

LSB = Full Scale Range/(2N-1)

where N is the number of bits and the Full Scale Range is 1VP-P.

The LSB size for this application is 977µV. To determine the Inte-

gral Linearity of the HI5721 the bit weights of each major transi-

tion is taken. The Best Fit Straight Line method is used to

calculate the overall INL. Measurements are taken at bits 0 thru 6

at each bit transition. Then all combinations of the upper 4 bits

are measured. Finally some worst case codes are measured

and the full scale is measured. Once this is completed a best fit

straight line is drawn through the data points and the worst case

de viation is determined.

The worst case integral linearity of the HI5721 is specified to be

less than 1.5 LSBs. The linearity of the HI5721 is worst in the

segmented current sources in the thermometer encoded sec-

tion. This is due to the errors of each current source being

biased in one direction and being additive with increasing data

values. The R/2R resistor matching need be to a 6-bit level to

ensure overall 10-bit linearity. Process control of resistor match-

ing in the BiCMOS process used is easily adequate to do the

job. For the overall transfer function the typical INL perfor-

mance is shown in Figure 6.

FIGURE 6A. INL TYPICAL PERFORMANCE CURVE

FIGURE 6B. TYPICAL PERFORMANCE CURVE

FIGURE 6.

Differential Linearity and Missing Codes

For a D/A Converter the differential linearity is the step size

difference throughout the entire code range. For the HI5721

the step to step maximum difference is 1.0 LSBs. For any

given D/A converter, to guarantee no missing codes the con-

verter must be monotonic.

The deﬁnition of monotonicity is; as the input code is

increased the output should increase. When an input code is

increased and the output of the DAC does not increase or

reverses direction, then this converter is assumed to be

missing codes.

FIGURE 7. DNL EXAMPLE

Shown in Figure 7, as the input code increases the output

voltage should increase. When an error of greater than 1.0

LSB is incurred, that bit can be assumed to be a missing

code since the output did not increase but rather remained

the same.

0.25

0.20

0.15

0.10

0.05

0.00

-0.05

-0.10

DNL

CODE

0.5

0.4

0.3

0.2

0.1

-0.1

-0.2

INL

CODE

INPUT CODE GREATER THAN ZERO

OUTPUT

VOLTAGE

-0.5 LSB ERROR

(MISSING CODE)

GREATER THAN

ERROR

-1.0 LSB

Application Note 9410

Adjusting Full Scale

The RSET pin is used to set the Full Scale Output Current.

The output current is a function of the reference voltage

applied to the CONTROL AMP IN pin and the value of the

RSET resistor. To calculate the IOUT Full Scale Current use

the following formula:

IOUT Full Scale = 32 x (CONTROL AMP IN/RSET)

So where CONTROL AMP IN = 1.25V

and RSET = 1960Ω

IOUT = 20.4mA

To adjust the output full scale current, use a potentiometer in

rheostat mode as shown in Figure 8.

FIGURE 8. FULL SCALE OUTPUT APPLICATION CIRCUIT

The Control Ampliﬁer

The internal Control Ampliﬁer is used to buffer the internal or

an external reference. The precision current cells require an

adequate amount of drive to bias. The Control Ampliﬁer

frees the user from having to provide an external ampliﬁer.

The Evaluation Board

The HI5721 Evaluation board is a 1/2 size daughter board

designed to interface to the HSP-EVAL board. When used

together these boards create a flexible and powerful DDS sys-

tem. The HSP45116 board is used to generate the high speed

digital sine wave patterns for the D/A module. The HI5721

board reconstructs the incoming digital data to an analog rep-

resentation that can be analyzed on a spectrum analyzer or

oscilloscope.

Plugging In

After setting-up the HSP45116 board and the HI5721 board;

power should be applied to the banana jacks. A +5V, and a -

5.2V supply will be needed. To reduce noise the power sup-

ply leads should be twisted pairs.

Connect the interface cable to an IBM PC or compatible’s

parallel port. Power should be applied to the board and then

run the software directly from ﬂoppy disk. To run the software

place the ﬂoppy disk into drive A: and type:

A: NCOMCTRL

the HSP45116 Control Panel will be loaded. To exercise the

board the following parameters should be set:

BINFMT# = 0

and then set the Center Frequency to:

CENTER FREQUENCY = 01000000HEX

where the center frequency is in hex. At this point the output

of the HI5721 DAC module should be converting a sine wave

at 48KHz. Connect the output of the HI5721 module to an

oscilloscope.

The HI5721 module has Jumper plug for selecting the

INVERT feature of the HI5721. When J2 is installed, the

quadrature logic is disabled. When J2 is removed, the

quadrature logic is enabled and the DAC data will be 1’s

complemented.

DDS Interface

The HSP45116 board is a TTL/CMOS compatible logic

board. The HI5721 is a TTL/CMOS compatible logic D/A

converter. The design of the DAC module is to interface to

the 10 Most Signiﬁcant Bits of the NCO. The HI5721 module

should be plugged into P2 of the HSP-EVAL board.

Spurious Free Dynamic Range

The Spurious Free Dynamic Range of the HI5721 DACs is

the most important speciﬁcation for communication applica-

tions. This speciﬁcation shows how Integral Linearity, Glitch,

and Switching noise affect the spectral purity of the output

signal. Several important things must be noted ﬁrst.

When a quantized signal is reconstructed, certain artifacts are

created. Let’s take the example of trying to recreate a 1MHz

sine wave with a 1VP-P output. In the frequency domain the

fundamental should appear at 1MHz as shown in Figure 9.

FIGURE 9. FREQUENCY PLOT OF 1MHz TONE

The fundamental of a pure 1MHz tone should appear as an

impulse in the frequency domain at 1MHz. In a sampled sys-

tem noise terms are produced near the sampling frequen-

cies called aliases. These aliases are related to the

fundamental in that they are located at ±fNaround the sam-

pling frequency as shown in Figure 10.

RSET (17)

5KΩ

1960Ω

AMPLITUDE

(dB)

1MHz

-85

-50

NOISE FLOOR

FUNDAMENTAL

(PURE TONE)

Application Note 9410

FIGURE 10. SAMPLING ALIAS PRODUCTS

So for a 1MHz fundamental and a 5MHz sampling rate an

alias term is created at 4MHz and 6MHz. A (SIN)/X function

shaping is also induced by sampling a signal. Aliases con-

tinue up through the frequency spectrum repeating around

the sampling frequency and its harmonics (i.e. 2fS,3f

S,4f

S).

A reconstructed sine wave out of the HI5721 is not ideal and

as such has harmonics of the fundamental. The difference

between the magnitude of the fundamental and the highest

noise spur whether it is harmonically related to the funda-

mental or not, is the deﬁnition of Spurious Free Dynamic

Range. Figures 11, through 16 are sample plots taken of the

HI5721 at various frequencies. Included are the oscilloscope

plots.

AMPLITUDE

(dB)

1MHz

-85

-50

FUNDAMENTAL

4MHz

ALIAS

(fS - 1MHz)

SAMPLING FUNCTION

(SIN X)/X

FIGURE 11A. OSCILLOSCOPE PLOT FIGURE 11B. SAMPLE PLOT

FIGURE 11. A 1MHz FUNDAMENTAL TO fS UNFILTERED

FIGURE 12. A 1MHz FUNDAMENTAL ON A 1MHz SPAN UNFILTERED

fN= 1MHz UNFILTERED

fS = 40MHz

ATTEN 20dB

RL 0dB

∆MKR -65.50dBC

1.00MHz

START 0Hz

RBW 1.0kHz STOP 20.00MHz

SWP 50.0s

VBW 1.0kHz

10dB/

∆MKR

1.00MHz

-65.50dB

fN = 1MHz UNFILTERED LIMIT SPAN

fS = 40MHz

ATTEN 20dB

RL 0dB

∆MKR -81.50dBC

33kHz

CENTER 1.000MHz

RBW 300Hz SPAN 1.000MHz

SWP 28.0s

VBW 300Hz

10dB/

∆MKR

33kHz

-81.50dB

Application Note 9410

FIGURE 13A. OSCILLOSCOPE PLOT FIGURE 13B. A 1MHz FUNDAMENTAL TO NIQUIST WITH A

20MHz BANDPASS FILTER

FIGURE 13. A 1MHz FUNDAMENTAL TO NYQUIST WITH A 20MHz BANDPASS FILTER

FIGURE 14A. OSCILLOSCOPE PLOT FIGURE 14B. SAMPLE PLOT

FIGURE 14. A 5MHz FUNDAMENTAL TO fS UNFILTERED

FIGURE 15. A 5MHz FUNDAMENTAL ON A 1MHz SPAN UNFILTERED

fN = 1MHz FILTERED

fS= 40MHz

ATTEN 20dB

RL 0dB

∆MKR 64.16dBC

1.00MHz

START 0Hz

RBW 3.0kHz STOP 20.00MHz

SWP 5.60s

VBW 3.0kHz

10dB/

∆MKR

1.00MHz

-64.16dB

fN = 5MHz UNFILTERED

fS = 40MHz

ATTEN 20dB

RL 0dB

∆MKR -55.50dBC

10.00MHz

START 0Hz

RBW 1.0kHz STOP 20.00MHz

SWP 50.0s

VBW 1.0kHz

10dB/

∆MKR

-55.50dB

10.00MHz

fN = 5MHz UNFILTERED LIMIT SPAN

fS = 40MHz

ATTEN 20dB

RL 0dB

∆MKR -66.83dBC

5kHz

CENTER 5.000MHz

RBW 300Hz SPAN 1.000MHz

SWP 28.0s

VBW 300Hz

10dB/

∆MKR

-66.83dB

5kHz

Application Note 9410

FIGURE 16A. OSCILLOSCOPE PLOT FIGURE 16B. SAMPLE PLOT

FIGURE 16. A 5MHz FUNDAMENTAL TO fS WITH A BANDPASS FILTER

fN = 5MHz FILTERED

fS= 40MHz

ATTEN 20dB

RL 0dB

∆MKR -65.34dBC

5.00MHz

START 0Hz

RBW 3.0kHz STOP 20.00MHz

SWP 5.60s

VBW 3.0kHz

10dB/

PEAK

-80.6dBm

THRESHOLD

Application Note 9410

Using the HSP-EVAL Test Platform

The HSP-EVAL DDS platform allows quick testing of spectral

properties of a given DAC. The Numerically Controlled Oscil-

lator/Modulator (NCOM) generates digital sinewave patterns

that are loaded into the DAC. The analog output of the DAC

is the reconstructed sinewave pattern. The program NCOM-

CTRL allows downloading of the desired center frequency.

The clock or sampling frequency is 25MHz. To determine the

center frequency codeword the following formula is used:

Center FrequencyHEX = (Desired Frequency/25MHZ) x 232

This 32-bit hexadecimal word will create the fundamental. In

order to ensure zero phase offset the cursor should be

moved to the LOAD select. Pressing the spacebar the value

should be toggled from 1 to 0 and back to 1 again. This will

ensure that any previous values in the phase register are

cleared and the sinewave pattern is started at zero phase.

The HSP-EVAL setup is powered from the DAC module

power-supply banana jacks. The output of the setup can be

observed on an oscilloscope or a spectrum analyzer.

FIGURE 17. INTERSIL HI5721/DDS EVALUATION SYSTEM SETUP BLOCK DIAGRAM

PERSONAL COMPUTER SPECTRUM ANALYZER

HSP-EVAL/HPS45116

NCOM EVALUATION BOARD

HSP45116

NUMERICALLY

CONTROLLED

OSCILLATOR

50Ω

SMA

CABLE

HI5721

DAC

CLOCK

CIRCUIT

+5V -5.2V

HI5721

DAC MODULE

INCLUDED

SOFTWARE

PC INTERFACE

POWER

SUPPLY

Application Note 9410

Schematic Diagram

NOTES:

1. All passive components are SMT devices, except polarized capacitors and ferrite beads.

2. HI5721 is a 28 lead DIP. FIGURE 18.

910

11 12

13 14

15 16

17 18

19 20

21 22

23 24

25 26

DB0

DB1

DB2

DB3

DB4

DB5

DB6

DB7

DB8

DB9

SMA

D9 (MSB)

1D8

2D7

3D6

4D5

5D4

6D3

D0 (LSB)

INVERT

13 CLK

11 25

DVDD

DVSS

15 19

8D1

DVEE

16 22

DVSS

DVEE

HI5721

VCC

R6- R15

DB9

DB8

DB7

DB6

R17

CON2

22K

DB5

DB4

DB3

DB2

DB1

DB0

VCC

R16

50 R3

1960

-AVEE

-5.2V

+5V VCC VCC

PLACE AS CLOSE TO PIN

0.1µF

PLACE AS CLOSE TO PIN

22 AS POSSIBLE

-AVEE

10µH

SYSTEM

BJ1

BJACK

ECL SUPPLY -AVEE

J1A

CON32

J1B

VCC

J1C

DB0

CLK

DB3

DB5

DB7

DB9

CON32 CON32

DB1

DB2

DB4

DB6

DB8

20.1µFC9

10µF

0.01µF

-5.2V

16 AS POSSIBLE

C10

10µFC4

0.1µFC5

0.01µF

SPACE LIKE A

FERRITE BEAD

0.1µFC11

0.01µF

-5.2V

BJ1

BJACK

GROUND

REF OUT

IOUT

REF IN

ARET

IOUT/

C AMP OUT

C AMP IN

AVEE

RSET

AVSS

Application Note 9410

Evaluation Board Layers

FIGURE 19A. HI5721 SILKSCREEN

FIGURE 19B. HI5721 LAYER 1

HI5721 EVAL.

BOARD

Application Note 9410

FIGURE 19C. HI5721 LAYER 2

FIGURE 19D. HI5721 LAYER 3

Evaluation Board Layers (Continued)

Application Note 9410

All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certiﬁcation.

Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time with-

out notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and

reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result

from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.

For information regarding Intersil Corporation and its products, see web site http://www.intersil.com

Sales Ofﬁce Headquarters

NORTH AMERICA

Intersil Corporation

P. O. Box 883, Mail Stop 53-204

Melbourne, FL 32902

TEL: (321) 724-7000

FAX: (321) 724-7240

EUROPE

Intersil SA

Mercure Center

100, Rue de la Fusee

1130 Brussels, Belgium

TEL: (32) 2.724.2111

FAX: (32) 2.724.22.05

ASIA

Intersil (Taiwan) Ltd.

7F-6, No. 101 Fu Hsing North Road

Taipei, Taiwan

Republic of China

TEL: (886) 2 2716 9310

FAX: (886) 2 2715 3029

FIGURE 19E. HI5721 LAYER 4

Evaluation Board Layers (Continued)

Application Note 9410