HI5721BIB - Rochester Electronics

FN3949 Rev 8.00 Page 1 of 14

March 2003

FN3949

Rev 8.00

March 2003

HI5721

10-Bit, 125MSPS, High Speed D/A Converter

DATASHEET

The HI5721 is a 10-bit, 125MSPS, high speed D/A

converter. The converter incorporates a 10-bit, input data

outputs. The HI5721 features low glitch energy and excellent

frequency domain specifications.

Features

• Throughput Rate . . . . . . . . . . . . . . . . . . . . . . . . 125MSPS

• Low Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .700mW

• Integral Linearity Error . . . . . . . . . . . . . . . . . . . . . 1.5 LSB

• Low Glitch Energy . . . . . . . . . . . . . . . . . . . . . . . . .1.5pV•s

• TTL/CMOS Compatible Inputs

• Improved Hold Time. . . . . . . . . . . . . . . . . . . . . . . . . 0.5ns

• Excellent Spurious Free Dynamic Range

• Improved Second Source for the AD9721

Applications

• Wireless Communications

• Direct Digital Frequency Synthesis

• Signal Reconstruction

• HDTV

• Test Equipment

• High Resolution Imaging Systems

• Arbitrary Waveform Generators

Pinout

HI5721

(PDIP, SOIC)

TOP VIEW

Part Number Information

PART

NUMBER

TEMP.

RANGE (oC) PACKAGE

PKG.

NO.

HI5721BIP -40 to 85 28 Ld PDIP E28.6

HI5721BIB -40 to 85 28 Ld SOIC (W) M28.3

HI5721-EVP 25 Evaluation Board (PDIP)

HI5721-EVS 25 Evaluation Board (SOIC)

D9 (MSB)

D0 (LSB)

CLOCK

INVERT

VCC

DGND

CTRL AMP IN

REF OUT

CTRL AMP OUT

REF IN

IOUT

ARTN

AGND

RSET

DVEE

DGND

DVEE

AVEE

IOUT

OBSOLETE PRODUCT

NO RECOMMENDED REPLACEMENT

contact our Technical Support Center at

1-888-INTERSIL or www.intersil.com/tsc

HI5721

FN3949 Rev 8.00 Page 2 of 14

March 2003

Typical Applications Circuit

Functional Block Diagram

D7 (3)

D6 (4)

D5 (5)

D4 (6)

D3 (7)

D2 (8)

D1 (9)

D0 (LSB) (10)

+5V

VCC (14)

0.01F

DGND (15, 28)

CLK (11)

INVERT (13)

-5.2V (AVEE)

0.1F

(19) ARTN

(22) AVEE

D/A OUT

(20) IOUT

(21) IOUT

(17) RSET

1960

64

(26) CTRL AMP IN

(23) REF IN

HI5721

D9 D9 (MSB) (1)

D8 (2)

DVEE (16, 27)

- 5.2V (AVEE)

0.01F

(24) CTRL AMP OUT

(25) REF OUT

64

0.1F

- 5.2V (DVEE)

0.01F

0.1F

(18) AGND

50

UPPER

VOLTAGE

REFERENCE

REF IN

IOUT

(LSB) D0

(MSB) D9

INVERT

CLK

4-BIT

DECODER

IOUT

QUADRATURE

LOGIC

-CTRL AMP

REF OUT RSET CTRL AMP IN

25

DATA

BUFFER/

LEVEL

SHIFTER

OUT

SWITCHED

CURRENT

CELLS

6 LSBs

CURRENT

CELLS

SLAVE

AVEE AGND DVEE DGND VCC

R2R

NETWORK

227227

ARTN

HI5721

FN3949 Rev 8.00 Page 3 of 14

March 2003

Absolute Maximum Ratings Thermal Information

Digital Supply Voltage VCC to DGND . . . . . . . . . . . . . . . . . . . +5.5V

Negative Digital Supply Voltage DVEE to DGND . . . . . . . . . . -5.5V

Negative Analog Supply Voltage AVEE to AGND, ARTN . . . . -5.5V

Digital Input Voltages (D9-D0, CLK, INVERT) . . . . . . . VCC to -0.5 V

Internal Reference Output Current. . . . . . . . . . . . . . . . . . . . . .500A

Control Amplifier Input Voltage Range. . . . . . . . . . . . AGND to -4.0V

Control Amplifier Output Current . . . . . . . . . . . . . . . . . . . . . 2.5mA

Reference Input Voltage Range. . . . . . . . . . . . . . . . . -3.7 V to AVEE

Analog Output Current (IOUT) . . . . . . . . . . . . . . . . . . . . . . . . . 30mA

Operating Conditions

Temperature Range. . . . . . . . . . . . . . . . . . . . . . . . . . -40oC to 85oC

Thermal Resistance (Typical, Note 1) JA(oC/W)

PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

SOIC Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

Maximum Power Dissipation

HI5721BIx . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .750mW

Maximum Junction Temperature

HI5721BIx . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .150oC

Maximum Storage Temperature Range . . . . . . . . . -65oC to 150oC

Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300oC

(SOIC - Lead Tips Only)

CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the

device at these or any other conditions above those indicated in the operational sections of this specification is not implied.

NOTE:

1. JA is measured with the component mounted on an evaluation PC board in free air.

Electrical Specifications AVEE, DVEE = -4.94 to -5.46V, VCC = +4.75 to +5.25V, CTRL AMP IN = REF OUT,

TA = 25oC for All Typical Values

PARAMETER TEST CONDITIONS

HI5721BI

TA = -40oC TO 85oC

UNITSMIN TYP MAX

SYSTEM PERFORMANCE

Resolution 10 - - Bits

Integral Linearity Error, INL (Note 4) (“Best Fit” Straight Line) - 0.5 1.5 LSB

Differential Linearity Error, DNL (Note 4) - 0.5 1.0 LSB

Offset Error, IOS (Note 4) - 16 75 A

Full Scale Gain Error, FSE (Notes 2, 4) - 2 10 %

Offset Drift Coefficient (Note 3) - 0.1 - A/oC

Full Scale Output Current, IFS - -20.48 - mA

Output Voltage Compliance Range (Note 3) -1.5 - +3.0 V

DYNAMIC CHARACTERISTICS

Throughput Rate (Note 3) 125.0 - - MSPS

Output Voltage Full Scale Step Settling Time, tSETT FS To 0.5 LSB Error Band RL = 50 (Note 3) - 4.5 - ns

Output Voltage Small Step Settling Time, tSETT SM 100mV Step to 0.5 LSB Error Band, RL = 50

(Note 3)

-3.5- ns

Singlet Glitch Area, GE (Peak Glitch) RL = 50(Note 3) - 3.5 - pV•s

Doublet Glitch Area, (Net Glitch) -1.5-pV•s

Output Slew Rate RL = 50DAC Operating in Latched Mode

(Note 3)

- 1,000 - V/s

Output Rise Time RL = 50DAC Operating in Latched Mode

(Note 3)

- 675 - ps

Output Fall Time RL = 50DAC Operating in Latched Mode

(Note 3)

- 470 - ps

HI5721

FN3949 Rev 8.00 Page 4 of 14

March 2003

Spurious Free Dynamic Range, SFDR to Nyquist fCLK = 125 MSPS, fOUT = 2.02MHz, 62.5MHz

Span (Notes 3, 5)

--59- dBc

fCLK = 125 MSPS, fOUT = 25MHz, 62.5MHz Span

(Notes 3, 5)

--53- dBc

fCLK = 100 MSPS, fOUT = 2.02MHz, 50MHz Span

(Notes 3, 5)

--59- dBc

fCLK = 100 MSPS, fOUT = 25MHz, 50MHz Span

(Notes 3, 5)

--51- dBc

Spurious Free Dynamic Range, SFDR Within a

Window

fCLK = 125 MSPS, fOUT = 2.02MHz, 2MHz Span

(Notes 3, 5)

--75- dBc

fCLK = 125 MSPS, fOUT = 25MHz, 2MHz Span

(Notes 3, 5)

--70- dBc

fCLK = 100 MSPS, fOUT = 2.02MHz, 2MHz Span

(Notes 3, 5)

--75- dBc

fCLK = 100 MSPS, fOUT = 25MHz, 2MHz Span

(Notes 3, 5)

--72- dBc

Signal to Noise Ratio (SNR) to Nyquist

(Ignoring the First 5 Harmonics)

fCLK = 125 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

-54- dB

fCLK = 125 MSPS, fOUT = 25MHz

(Notes 3, 5)

- 51.5 - dB

fCLK = 100 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

- 54.5 - dB

fCLK = 100 MSPS, fOUT = 25MHz

(Notes 3, 5)

- 50.3 - dB

Signal to Noise Ratio + Distortion (SINAD) to Nyquist fCLK = 125 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

- 52.4 - dB

fCLK = 125 MSPS, fOUT = 25MHz

(Notes 3, 5)

- 49.2 - dB

fCLK = 100 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

- 52.7 - dB

fCLK = 100 MSPS, fOUT = 25MHz

(Notes 3, 5)

- 47.6 - dB

Total Harmonic Distortion (THD) to Nyquist fCLK = 125 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

- -57.8 - dBc

fCLK = 125 MSPS, fOUT = 25MHz

(Notes 3, 5)

- -53.3 - dBc

fCLK = 100 MSPS, fOUT = 2.02MHz,

(Notes 3, 5)

- -57.9 - dBc

fCLK = 100 MSPS, fOUT = 25MHz

(Notes 3, 5)

--51- dBc

Intermodulation Distortion (IMD) to Nyquist fCLK = 125 MSPS, fOUT1 = 800kHz,

fOUT2 = 900kHz (Notes 3, 5)

- 57.3 - dB

fCLK = 100 MSPS, fOUT1 = 800kHz,

fOUT2 = 900kHz (Notes 3, 5)

- 57.2 - dB

Electrical Specifications AVEE, DVEE = -4.94 to -5.46V, VCC = +4.75 to +5.25V, CTRL AMP IN = REF OUT,

TA = 25oC for All Typical Values (Continued)

PARAMETER TEST CONDITIONS

HI5721BI

TA = -40oC TO 85oC

UNITSMIN TYP MAX

HI5721

FN3949 Rev 8.00 Page 5 of 14

March 2003

REFERENCE/CONTROL AMPLIFIER

Internal Reference Voltage, REF OUT (Note 4) -1.15 -1.25 -1.35 V

Internal Reference Voltage Drift (Note 3) - 100 - V/oC

Internal Reference Output Current Sink/Source

Capability

(Note 3) -50 - +500 A

Amplifier Input Impedance (Note 3) - 10 - M

Amplifier Large Signal Bandwidth 4.0VP-P Sine Wave Input, to Slew Rate Limited

(Note 3)

-1-MHz

Amplifier Small Signal Bandwidth 1.0VP-P Sine Wave Input, to -3dB Loss (Note 3) - 10 - MHz

Reference Input Impedance (Note 3) - 4.6 - k

Reference Input Multiplying Bandwidth RL = 50, 100mV Sine Wave, to -3dB Loss at

IOUT (Note 3)

-75-MHz

DIGITAL INPUTS (D9-D0, CLK, INVERT)

Input Logic High Voltage, VIH (Note 4) 2.0 - - V

Input Logic Low Voltage, VIL (Note 4) - - 0.8 V

Input Logic Current, IIH (Note 4) - - 400 A

Input Logic Current, IIL (Note 4) - - 700 A

Digital Input Capacitance, CIN (Note 3) - 3.0 - pF

TIMING CHARACTERISTICS

Data Setup Time, tSU See Figure 3 (Note 3) 2.0 - - ns

Data Hold Time, tHLD See Figure 3 (Note 3) 0.5 - - ns

Propagation Delay Time, tPD See Figure 3 (Note 3) - 4.5 - ns

CLK Pulse Width, tPW1, tPW2 See Figure 3 (Note 3) 1.0 0.85 - ns

POWER SUPPLY CHARACTERISITICS

IDVEE (Note 4) - 100 110 mA

IAVEE (Note 4) - - 15 mA

VCC (Note 4) - 14 25 mA

Power Dissipation (Note 4) - 700 775 mW

Power Supply Rejection Ratio VCC 5%, VEE 5% - 50 - A/V

NOTES:

2. Gain Error measured as the error in the ratio between the full scale output current and the current through RSET (typically 640A). Ideally the

ratio should be 32.

3. Parameter guaranteed by design or characterization and not production tested.

4. All devices are 100% tested at 25oC. 100% productions tested at temperature extremes for military temperature devices, sample tested for

industrial temperature devices.

5. Spectral measurements made without external filtering.

Electrical Specifications AVEE, DVEE = -4.94 to -5.46V, VCC = +4.75 to +5.25V, CTRL AMP IN = REF OUT,

TA = 25oC for All Typical Values (Continued)

PARAMETER TEST CONDITIONS

HI5721BI

TA = -40oC TO 85oC

UNITSMIN TYP MAX

HI5721

FN3949 Rev 8.00 Page 6 of 14

March 2003

Timing Diagrams

FIGURE 1. FULL SCALE SETTLING TIME DIAGRAM FIGURE 2. PEAK GLITCH AREA (SINGLET) MEASUREMENT

METHOD

FIGURE 3. PROPAGATION DELAY, SETUP TIME, HOLD TIME AND MINIMUM PULSE WIDTH DIAGRAM

CLK

D9-D0

IOUT

50%

tSETT

1/2 LSB ERROR BAND

tPD

t(ps)

HEIGHT (H)

WIDTH (W)

GLITCH AREA = 1/2 (H x W)

CLK

D9-D0

IOUT

50%

tPW1 tPW2

tSU

tHLD

tSU tSU

tPD

tPD tPD

tHLD tHLD

tSETT

tSETT tSETT

HI5721

FN3949 Rev 8.00 Page 7 of 14

March 2003

Typical Performance Curves

FIGURE 4. INTEGRAL NON-LINERARITY “BEST FIT”

STRAIGHT LINE

FIGURE 5. DIFFERENTIAL NON-LINEARITY

FIGURE 6. SPURIOUS FREE DYNAMIC RANGE TO NYQUIST

25MHz FUNDAMENTAL

FIGURE 7. SPURIOUS FREE DYNAMIC RANGE TO NYQUIST

2MHz FUNDAMENTAL

FIGURE 8. INTERMODULATION DISTORTION FIGURE 9. SPURIOUS FREE DYNAMIC RANGE (TO NYQUIST)

vs OUTPUT FREQUENCY

1023

DATA CODE

1.0

0.5

-0.5

-1.0

LSB

0200 600 800400

1023

DATA CODE

+0.5

0.2

-0.2

-0.5

LSB

0 200 600 800400

0.4

-0.4

START 0Hz STOP 62.50MHz

†RBW 3.0kHz †VBW 1kHz SWP 53.0s

†ATTEN 20dB

RL -10.0dBm 10dB/

MKR -54.16dB

25.2MHz

HI-5721

fCLK = 125 MSPS

-10

-20

-30

-40

-50

-60

-70

-80

-90

-100

-110

fOUT = 25 MHZ

START 0Hz STOP 62.50MHz

†RBW 3.0kHz †VBW 1.0kHz SWP 53.0s

†ATTEN 20dB

RL -10.0dBm 10dB/ SFDR = -55.8dBc

HI-5721

fCLK = 125 MSPS

-10

-20

-30

-40

-50

-60

-70

-80

-90

-100

-110

fOUT = 2 MHz

FREQUENCY (MHz)

0.0

-20

-40

-60

-110

02 64

-80

-100

800kHz

900kHz

f1 = 800kHz

f2 = 900kHz

fOUT (MHz)

fCLK = 125 MSPS

fCLK = 100 MSPS

dBc

22410 124 6 14 16 2082618 22

HI5721

FN3949 Rev 8.00 Page 8 of 14

March 2003

FIGURE 10. SPURIOUS FREE DYNAMIC RANGE

(1MHz WINDOW) vs FREQUENCY

FIGURE 11. SIGNAL TO NOISE RATIO vs OUTPUT FREQUENCY

FIGURE 12. SIGNAL TO NOISE + DISTORTION vs OUTPUT

FREQUENCY

FIGURE 13. TOTAL HARMONIC DISTORTION vs OUTPUT

FREQUENCY

FIGURE 14. GAIN ERROR vs TEMPERATURE FIGURE 15. OFFSET ERROR vs TEMPERATURE

Typical Performance Curves (Continued)

fOUT (MHz)

fCLK = 125 MSPS

fCLK = 100 MSPS

dBc

22410 124 6 14 16 2082618 22

fOUT (MHz)

22410 124 6 14 16 20826

fCLK = 125 MSPS

fCLK = 100 MSPS

47 18 22

fOUT (MHz)

fCLK = 125 MSPS

fCLK = 100 MSPS

22410 124 6 14 16 2082618 22

fOUT (MHz)

fCLK = 125 MSPS

fCLK = 100 MSPS

dBc

22410 124 6 14 16 2082618 22

TEMPERATURE (oC)

-2.5

-2.6

-2.7

-2.8

-2.9

-3.0

-3.1

-3.2

-3.3

-3.4

-3.5

-3.6

-3.7

-3.8

ERROR (%)

-40-20 0 20406080100

TEMPERATURE (oC)

40 50 60 70 80 903020100-10-20-30-40-50

A

HI5721

FN3949 Rev 8.00 Page 9 of 14

March 2003

FIGURE 16. REFERENCE VOLTAGE vs TEMPERATURE

NOTE: Clock Frequency does not alter power dissipation.

FIGURE 17. POWER DISSIPATION vs TEMPERATURE

Pin Descriptions

PIN NO. PIN NAME PIN DESCRIPTION

1-10 D0 (LSB)

through D9

(MSB)

Digital Data Bit 0, the Least Significant Bit through Digital Data Bit 9, the Most Significant Bit.

11 CLK Data Clock pin 100kHz to 125 MSPS.

12 NC No Connect.

13 INVERT Data Invert control for bits D0 (LSB) through D8. D9 (MSB) is not affected.

14 VCC Digital Logic Supply +5V.

15, 28 DGND Digital Ground.

16, 27 DVEE -5.2V Logic Supply.

17 RSET External resistor to set the full scale output current. IFS = 32 x (CTRL AMP IN/RSET). Typically 1960.

18 AGND Analog Ground supply current return pin.

19 ARTN Analog Signal Return for the R/2R ladder.

20 IOUT Current Output pin.

21 IOUT Complementary Current Output pin.

22 AVEE -5.2V Analog Supply.

23 REF IN Reference Input pin. Typically connected to CTRL AMP OUT and a 0.1F capacitor should be connected to

AVEE to bypass the reference voltage. Provides a reference for the current switching network.

24 CTRL AMP

OUT

Control Amplifier Output. Used to convert the internal reference or an external signal to the precision reference

current.

25 REF OUT Internal Reference Output. Output of the internal -1.25V (typical) bandgap voltage reference.

26 CTRL AMP IN Control Amplifier Input. High impedance, inverting input of the reference control/buffer amplifier.

Typical Performance Curves (Continued)

-50A LOAD

100A LOAD

NO LOAD

-1.20

-1.21

-1.22

-1.23

-1.24

-1.25

-1.26

-1.27

-1.28

-1.29

-1.30

-1.31

-1.32

-1.33

-1.34

-1.35

-40 -20 0 20 40 60 80 100

TEMPERATURE (oC)

(V)

TEMPERATURE (oC)

0.80

0.75

0.70

0.65

0.60

0.55

0.50

-50 -40 -30 -20 -10 0 10 20 30 40 6050 70 80 90

(W)

HI5721

FN3949 Rev 8.00 Page 10 of 14

March 2003

Detailed Description

The HI5721 is a 10-bit, current out D/A converter. The DAC

can convert at 125 MSPS and runs on +5V and -5.2V supplies.

The architecture is an R/2R and segmented switching current

cell arrangement to reduce glitch and maintain 10-bit linearity

without laser trimming. The HI5721 achieves its low power and

high speed performance from an advanced BiCMOS process.

The HI5721 consumes 700mW (typical) and has an improved

hold time of only 0.5ns (typical). The HI5721 is an excellent

converter to be used for communications applications and high

performance video systems.

Digital Inputs

The HI5721 is a TTL/CMOS compatible D/A. The inputs can be

inverted using the INVERT pin. When INVERT is LOW (‘0’) the

input quadrature logic simply passes the data through

unchanged.

When INVERT is HIGH (‘1’) bits D0 (LSB) through D8 are

inverted. D9 is not inverted and can be considered a sign bit

when enabling this quadrature compatible mode. The INVERT

function can simplify the requirements for large sine wave

lookup tables in a Numerically Controlled Oscillator. The NCO

used in a DDS application would only have to store or generate

90 degrees of information and then use the INVERT control to

control the sign of the output waveform.

Data Buffer/Level Shifters

Data inputs D0 (LSB) through D9 (MSB) are internally translated

from TTL to ECL. The internal latch and switching current

source controls are implemented in ECL technology to maintain

high switching speeds and low noise characteristics.

Decoder/Driver

The architecture employs a split R/2R and Segmented Current

source arrangement. Bits D0 (LSB) through D5 directly drive a

typical R/2R network to create the binary weighted current

sources. Bits D6 through D9 (MSB) pass through a

“thermometer” encoder that converters the incoming data into

15 individual segmented current source enables. The split

architecture helps to improve glitch while maintaining 10-bit

linearity without laser trimming. The worst case glitch is more

constant across the entire output transfer function.

Clocks and Termination

The internal 10-bit register is updated on the rising edge of the

clock. Since the HI5721 clock rate can run to 125 MSPS, to

minimize reflections and clock noise into the part proper

termination should be used. In PCB layout clock runs should be

kept short and have a minimum of loads. To guarantee consistent

results from board to board, controlled impedance PCBs should

be used with a characteristic line impedance ZO of 50.

To terminate the clock line a shunt terminator to ground is the

most effective type at a 125 MSPS clock rate. A typical value for

termination can be determined by the equation:

RT = ZO,

for the termination resistor. For a controlled impedance board

with a ZO of 50, the RT = 50. Shunt termination is best

used at the receiving end of the transmission line or as close to

the HI5721 CLK pin as possible.

Rise and Fall times and propagation delay of the line will be

affected by the Shunt Terminator. The terminator can be

connected to DGND.

Noise Reduction

To reduce power supply noise, separate analog and digital

power supplies should be used with 0.1F and 0.01F ceramic

capacitors placed as close to the body of the HI5721 as

possible on the analog (AVEE) and digital (DVEE) supplies.

The analog and digital ground returns should be connected

together back at the device to ensure proper operation on

power up. The VCC power pin should be decoupled with a

0.1F capacitor.

Reference

The internal reference in the HI5721 is a -1.25V (typical)

bandgap voltage reference with a 100V/oC temperature drift

(typical). The internal reference should be buffered by the

Control Amplifier to provide adequate drive for the segmented

current cells and the R/2R resistor ladder. Reference Out (REF

OUT) should be connected to the Control Amplifier Input

(CTRL AMP IN). The Control Amplifier Output (CTRL AMP

OUT) should be used to drive the Reference Input (REF IN)

and a 0.1F capacitor to analog V- (AVEE). This improves

settling time by decoupling switching noise from the analog

output of the HI5721.

The Full Scale Output Current is controlled by the CTRL AMP

IN pin and the set resistor (RSET). The ratio is:

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

Multiplying Capability

The HI5721 can operate in two different multiplying

configurations. First, using the CTRL AMP IN input pin, a -0.6V

to -1.2V signal can be applied with a bandwidth up to 1MHz. To

increase the multiplying bandwidth, the 0.1F capacitor

connected from REF IN to AVEE can be reduced.

RT = 50

HI5721

DAC

CLK

ZO = 50

FIGURE 18. AC TERMINATION OF THE HI5721 CLOCK LINE

HI5721

FN3949 Rev 8.00 Page 11 of 14

March 2003

If higher multiplying frequencies are desired, the reference

input can be directly driven. The analog signal range is -3.3V to

-4.25V. The multiplying signal must be capacitively coupled

into REF IN onto a DC bias between -3.3V to -4.25V (-3.8V

typically).

Outputs

The outputs IOUT and IOUT are complementary current

outputs. Current is steered to either IOUT or IOUT in proportion

to the digital input code. The sum of the two currents is always

equal to the full scale current minus one LSB. The current

output can be converted to a voltage by using a load resistor.

Both current outputs should have the same load resistor (64

typically). By using a 64 load on the output, a 50 effective

output resistance (ROUT) is achieved due to the 227 (15%)

parallel resistance seen looking back into the output. This is

the nominal value of the R2R ladder of the DAC. The 50

output is needed for matching the output with a 50 line. The

load resistor should be chosen so that the effective output

resistance (ROUT) matches the line resistance. The output

voltage is:

VOUT = IOUT x ROUT.

IOUT is defined in the reference section. The compliance range

of the output is from -1.5V to 3V, with a 1VP-P voltage swing

allowed within this range. However, if it is desired that the

output be offset above zero volts, it is necessary that pin 19

(ARTN) be connected to the same voltage as the load resistor,

not to exceed 3V.

Glitch

The output glitch of the HI5721 is measured by summing the

area under the switching transients after an update of the DAC.

Glitch is caused by 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 (TTL designs). Unequal delay paths through the

device can also cause one current source to change before

another. To minimize this the Intersil HI5721 employes an

internal register, just prior to the current sources, that is

updated on the clock edge. Lastly the worst case glitch usually

happens at the major transition i.e., 01 1111 1111 to 10 0000

0000. But in the HI5721 the glitch is moved to the 00 0001

1111 to 11 1110 0000 transition. This is achieved by the split

R/2R segmented current source architecture. This decreases

the amount of current switching at any one time and makes the

glitch practically constant over the entire output range. By

making the glitch a constant size over the entire output range

this effectively integrates this error out of the end application.

In measuring the output glitch of the HI5721 the output is

terminated into a 64 load. The glitch is measured at the major

carrys throughout the DAC’s output range.

The glitch energy is calculated by measuring the area under

the voltage-time curve. Figure 21 shows the area considered

as glitch when changing the DAC output. Units are typically

specified in picoVolt • seconds (pV • s).

RSET

CTRL AMP IN

CTRL AMP

REF IN

HI5721

-0.6 TO -1.2V

1MHz (MAX)

RSET

18OUT

FIGURE 19. LOW FREQUENCY MULTIPLYING CIRCUIT

REF IN

HI5721

AVEE

 -3.8V12050

383

2nF

FIGURE 20. WIDEBAND MULTIPLYING CIRCUIT

TABLE 1. INPUT CODING vs CURRENT OUTPUT

INPUT CODE (D9-D0) IOUT (mA) IOUT (mA)

11 1111 1111 -20.48 0

10 0000 0000 -10.24 -10.24

00 0000 0000 0 -20.48

(20) IOUT

125MHz

LOW PASS

FILTER

SCOPE

HI5721

6450

FIGURE 21. GLITCH TEST CIRCUIT

HI5721

FN3949 Rev 8.00 Page 12 of 14

March 2003

Applications

Voltage Conversion of the Output

To convert the output current of the D/A converter to a voltage,

an amplifier should be used as shown in Figure 23 below. The

DAC needs a 50 termination resistor on the IOUT pin to ensure

proper settling. The HFA1110 has an internal feedback resistor

to compensate for high frequency operation.

Bipolar Applications

To convert the output to a bipolar 2.0V output swing the

following applications circuit is recommended. The Reference

can only provide 100A of drive, so it must be buffered to

create the bipolar offset current needed to generate -2.0V

output with all bits ‘off’. The output current must be converted

to a voltage and then gained up and offset to produce the

proper swing. Care must be taken to compensate for the

output voltage swing and error.

Interfacing to the HSP45106 NCO-16

The HSP45106 is a 16-bit output, Numerically-Controlled

Oscillator (NCO). The HSP45106 can be used to generate

various modulation schemes for Direct Digital Synthesis (DDS)

applications. Figure 25 shows how to interface an HI5721 to

the HSP45106.

Interfacing to the HSP45102 NCO-12

The HSP45102 is a 12-bit output Numerically Controlled

Oscillator (NCO). The HSP45102 can be used to generate

various modulation schemes for Direct Digital Synthesis (DDS)

applications. Figure 26 shows how to interface an HI5721 to

the HSP45102.

This high level block diagram is that of a basic PSK modulator.

In this example the encoder generates the PSK waveform by

driving the Phase Modulation Inputs (P1, P0) of the

HSP45102. The P1-0 inputs impart a phase shift to the carrier

wave as defined in Table 2.

The 10 MSBs of the HSP45102 drive the 10-bit HI5721 DAC

which converts the NCO output into an analog waveform. The

output filter connected to the DAC can be tailored to remove

unwanted spurs for the desired carrier frequency. The

controller is used to load the desired center frequency and

control the HSP45102. The HI5721 coupled with the

HSP45102 make an inexpensive PSK modulator with Spurious

Free operation down to -76dBc.

t (ns)

GLITCH ENERGY = (a x t)/2

FIGURE 22. GLITCH ENERGY

a (mV)

HI5721

20 4

+5V

50

-5.2V

50

HFA1110

DAC

IOUT +

FIGURE 23. HIGH SPEED CURRENT TO VOLTAGE CONVERSION

TABLE 2. PHASE MODULATION INPUT CODING

P1 P0

PHASE SHIFT

(DEGREES)

000

0190

1 0 270

1 1 180

PIN 20

(HI5721)

PIN 25

(HI5721)

20K

-5V

20K

+5V

-5V

240

+5V

HFA1100

HA2705

BIPOLAR

OUTPUT

(2.0V)

FIGURE 24. BIPOLAR OUTPUT CONFIGURATION

HI5721

FN3949 Rev 8.00 Page 13 of 14

March 2003

Definition of Specifications

Integral Linearity Error, INL, is the measure of the worst case

point that deviates from a best fit straight line of data values

along the transfer curve.

Differential Linearity Error, DNL, is the measure of the step

size output deviation from code to code. Ideally the step size

should be 1 LSB. A DNL specification of 1 LSB or less

guarantees monotonicity.

Feedthru is the measure of the undesirable switching noise

coupled to the output.

Output Voltage Full Scale Settling Time, is the time required

from the 50% point on the clock input for a full scale step to

settle within an 1/2 LSB error band.

Output Voltage Small Scale Settling Time, is the time

required from the 50% point on the clock input for a 100mV

step to settle within an 1/2 LSB error band. This is used by

applications reconstructing highly correlated signals such as

sine waves with more than 5 points per cycle.

Glitch Area, GE, is the switching transient appearing on the

output during a code transition. It is measured as the area

under the curve and expressed as a Volt-Time specification.

Differential Gain, AV, is the gain error from an ideal sine

wave with a normalized amplitude.

Differential Phase,, is the phase error from and ideal sine

wave.

ENCODER

CONTROLLER

BASEBAND

BIT

STREAM

C11

B11

33 MSPS

CLK CLK

MOD2

MOD1

HSP45106

SIN15

D9 (MSB)

D0 (LSB)

DVDD

VCC

CLK

INVERT

DVSS

DVEE

HI5721

DVEE

DVSS

-5.2V_D

AVEE

AVSS

IOUT

IOUT/

REF IN

C AMP OUT

C AMP IN

RSET

ARET

REF OUT

1960

C2 1.0F

C1 0.01F

-5.2V_A

FILTER

TO RF

UP-CONVERT

STAGE

10H

-5.2V_A-5.2V_D

C10 MOD0

A11

F10

F11

H11

G11

J11

G10

D10

J10

K11

B10

A10

E11

H10

VCC

PMSEL

ENPOREG#

ENOFREG#

ENCFREG#

ENPHAC#

ENTIREG#

INHOFR#

INITPAC#

INITTAC#

TEST

PARSER#

BINFMT#

C15_MSB

C13

C12

C11

C10

CS#

WR#

PACI#

OES#

OEC#

DACSTRB#

SIN14

SIN13

SIN12

SIN11

SIN10

SIN9

SIN8

SIN7

SIN6

SIN5

SIN4

SIN3

SIN2

SIN1

SIN0

L10

COS15

COS14

COS13

COS12

COS11

COS10

COS9

COS8

COS7

COS6

COS5

COS4

COS3

COS2

COS1

COS0

TICO#

FIGURE 25. PSK MODULATOR USING THE HI5721 AND THE HSP45106 12-BIT NCO

-5.2V_A

FN3949 Rev 8.00 Page 14 of 14

March 2003

HI5721

Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted

in the quality certifications found at www.intersil.com/en/support/qualandreliability.html

Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such

modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets 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 www.intersil.com

For additional products, see www.intersil.com/en/products.html

All trademarks and registered trademarks are the property of their respective owners.

Signal to Noise Ratio, SNR, is the ratio of a fundamental to

the noise floor of the analog output. The first 5 harmonics

are ignored, and an output filter of 1/2 the clock frequency is

used to eliminate alias products.

Total Harmonic Distortion, THD, is the ratio of the DAC

output fundamental to the RMS sum of the harmonics. The

first 5 harmonics are included, and an output filter of 1/2 the

clock frequency is used to eliminate alias products.

Spurious Free Dynamic Range, SFDR, is the amplitude

difference from a fundamental to the largest harmonically or

non-harmonically related spur. A sine wave is loaded into

the D/A and the output filtered at 1/2 the clock frequency to

eliminate noise from clocking alias terms.

Intermodulation Distortion, IMD is the measure of the sum

and difference products produced when a two tone input is

driven into the D/A. The distortion products created will arise

at sum and difference frequencies of the two tones. IMD is

ENCODER

CONTROLLER

BASEBAND

BIT

STREAM

CONTROL

BUS

40 MSPS

CLK CLK

LOAD#

TXFR#

ENPHAC#

SEL_L/M#

SCLK

SFTEN#

MSB/LSB#

HSP45102

OUT11

OUT10

OUT9

OUT8

OUT7

OUT6

OUT5

OUT4

OUT3

OUT2

OUT1

OUT0

D9 (MSB)

D0 (LSB)

DVDD

VCC

CLK

INVERT

DVSS

DVEE

HI5721

DVEE

DVSS

-5.2V_D AVEE

AVSS

IOUT

IOUT/

REF IN

C AMP OUT

C AMP IN

RSET

ARET

REF OUT

1960

C2 1.0F

C1 0.01F

-5.2V_A

FILTER

TO RF

UP-CONVERT

STAGE

10H

10H-5.2V_A-5.2V_D

FIGURE 26. PSK MODULATOR USING THE HI5721 AND THE HSP45102 12-BIT NCO

-5.2V_A

IMD 20 (RMS of sum and difference distortion products)log

RMS amplitude of the fundamental

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