ISL26104_技术文档

DATASHEET

ISL26102, ISL26104

Low-Noise 24-bit Delta Sigma ADC

FN7608

Rev 0.00

October 12, 2012

The ISL26102 and ISL26104 provide a low-noise

Features

• Programmable gain amplifier with gains of 1 to 128

• Low noise: 7nV/√Hz @ PGA = 128

• Linearity error: 0.0002% FS

programmable gain amplifier along with a 24-bit Delta-Sigma

Analog-to-Digital Converter with two channel (ISL26102) or

four channel (ISL26104) differential, multiplexed inputs. The

devices feature exceptional noise performance for conversion

rates ranging from 2.5Sps to 4kSps.

• Output word rates up to 4kSps

The on-chip low-noise programmable-gain amplifier provides

gains ranging from 1 to 128, which supports ±19.5mVFS from

a 5V reference. The high input impedance allows direct

connection of sensors such as load cell bridges to ensure the

specified measurement accuracy without additional circuitry.

• Low-side switch for load cell power management

• +5V analog and +2.7V to +5V digital supplies

• ISL26102 in 24 Ld TSSOP

• ISL26104 in 28 Ld TSSOP

The Delta-Sigma ADC features a 3rd-order modulator providing

up to 21.5 bit noise-free performance (10Sps), with

user-selectable word rates. The converter can be operated

from an external clock source, an external crystal (typically

4.9152MHz), or the on-chip oscillator.

• ESD 7.5kV - HBM

Applications

• Weigh scales

The ISL26102 and ISL26104 offer a simple-to-use serial

interface.

• Temperature monitors and controls

• Load safety systems

• Industrial process control

• Pressure sensors

The ISL26102 and ISL26104 are available in a Thin Shrink

Small Outline Package (TSSOP). The devices are specified for

operation over the automotive temperature range (-40°C to

+105°C).

Related Literature

AN1704, “Precision Signal Path Data Acquisition System”

CAP

AVDD

DVDD

ON-CHIP

TEMP

SENSOR

XTALIN/

CLOCK

XTALOUT

INTERNAL

CLOCK

EXTERNAL

OSCILLATOR

AIN1+

AIN1-

CS

AIN2+

SDO/RDY

PGA

1, 2, 4, 8,16,

32, 64, 128

AIN2-



ADC

INPUT

MULTIPLEXER

AIN3+

AIN3-

SDI

ISL26104

ONLY

AIN4+

AIN4-

SCLK

PWDN

LSPS

DGND DGND

AGND

CAP DGND DGND VREF+ VREF-

FIGURE 1. BLOCK DIAGRAM

FN7608 Rev 0.00

October 12, 2012

Page 1 of 21

ISL26102, ISL26104

Ordering Information

PART NUMBER

(Notes 1, 2, 3)

PART

MARKING

TEMP RANGE

(°C)

PACKAGE

(Pb-free)

PKG.

DWG. #

DESCRIPTION

2 Channel ADC

4 Channel ADC

ISL26102AVZ

ISL26104AVZ

26102 AVZ

26104 AVZ

-40 to +105

24 Ld TSSOP

28 Ld TSSOP

M24.173

M28.173

ISL26104AV28EV1Z Evaluation Board

NOTES:

1. Add “-T*” suffix for tape and reel. Please refer to TB347 for details on reel specifications.

2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets, molding compounds/die attach materials, and 100% matte

tin plate plus anneal (e3 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations). Intersil

Pbfree products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.

3. For Moisture Sensitivity Level (MSL), please see device information page for ISL26102, ISL26104. For more information on MSL please see techbrief

TB363.

Pin Configurations

ISL26102

(24 LD TSSOP)

TOP VIEW

ISL26104

(28 LD TSSOP)

TOP VIEW

DVDD

DGND

28

1

2

3

4

5

6

7

8

9

SDO/RDY

24

DVDD

DGND

1

2

SDO/RDY

27 SCLK

23 SCLK

XTALIN/CLOCK

XTALOUT

DGND

26

25

24

23

22

21

20

19

18

17

16

15

PDWN

SDI

22

21

XTALIN/CLOCK

XTALOUT

DGND

3

PDWN

SDI

4

CS

20 CS

5

DVDD

LSPS

AVDD

AGND

VREF+

VREF-

AIN2+

AIN2-

AIN4+

AIN4-

19 LSPS

DVDD

6

ISL26102

DGND

AVDD

AGND

VREF+

VREF-

AIN2+

AIN2-

18

17

16

15

14

13

DGND

7

ISL26104

DGND

8

CAP

9

CAP

CAP 10

AIN1+ 11

AIN1- 12

AIN3+ 13

AIN3- 14

10

11

12

CAP

AIN1+

AIN1-

FN7608 Rev 0.00

October 12, 2012

Page 2 of 21

ISL26102, ISL26104

Pin Descriptions (TSSOP)

PIN NUMBER

ANALOG/DIGITAL

INPUT/OUTPUT

PIN NAME

DVDD

ISL26102

1, 6

ISL26104

1, 6

DESCRIPTION

Digital

Digital Power Supply (2.7V to 5.25V)

DGND

2, 5, 7, 8

3

2, 5, 7, 8

3

Digital

Digital Ground

XTALIN/CLOCK

Digital/Digital Input

External Clock Input: Typically 4.9152MHz. Tie low

to activate internal oscillator. Can also use external

crystal across XTALIN/CLOCK and XTALOUT pins.

XTALOUT

CAP

4

9, 10

11

12

-

4

9, 10

11

Digital

External Crystal Connection

PGA Filter Capacitor

Analog

AIN1+

AIN1-

Analog Input

Positive Analog Input Channel 1

Negative Analog Input Channel 1

Positive Analog Input Channel 3

12

AIN3+

13

AIN3-

AIN4-

AIN4+

AIN2-

AIN2+

VREF-

VREF+

AGND

AVDD

LSPS

-

14

15

16

17

18

19

20

21

22

23

24

25

26

27

28

Analog Input

Digital Output

Digital Input

Digital Output

Negative Analog Input Channel 3

Negative Analog Input Channel 4

Positive Analog Input Channel 4

Negative Analog Input Channel 2

Positive Analog Input Channel 2

Negative Reference Input

Positive Reference Input

-

13

14

15

16

17

18

19

20

21

22

23

24

Analog Ground

Analog Power Supply 4.75V to 5.25V

Low-Side Power Switch (Open Drain)

Chip Select (Active Low)

CS

SDI

Serial Data Input

PDWN

SCLK

Device Power Down (Active Low)

Serial Port Clock

SDO/RDY

Data Ready signal (conversion complete) and

Serial Data Output

FN7608 Rev 0.00

October 12, 2012

Page 3 of 21

ISL26102, ISL26104

Absolute Maximum Ratings

Thermal Information

A

to D

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to +0.3V

Thermal Resistance (Typical)

24 Ld TSSOP Package (Notes 4, 5) . . . . . .

28 Ld TSSOP Package (Notes 4, 5) . . . . . .



_JA(°C/W)

65



_JC(°C/W)

GND

Analog In to A

Digital In to D

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to A

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-0.3 to D

+0.3V

18

GND

VDD

63

ESD Rating

Maximum Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80mW

Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . .+150°C

Maximum Storage Temperature Range . . . . . . . . . . . . . .-65°C to +150°C

Human Body Model (Per MIL-STD-883 Method 3015.7) . . . . . . . . . . . . .7.5kV

Machine Model (Per JESD22-A115). . . . . . . . . . . . . . . . . . . . . . . . . . 450V

Charged Device Model (Per JESD22-C101) . . . . . . . . . . . . . . . . . . . . . . 2000V

Input Current

Momentary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100mA

Continuous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10mA

Latch-up

Operating Conditions

Temperature Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-40°C to +105°C

A

D

to A

to D

GND

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.75V to +5.25V

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2.7V to +5.25V

VDD

GND

(Per JEDEC, JESD-78C; Class 2, Level A). . . .100mA @ +25°C and +105°C

CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product

reliability and result in failures not covered by warranty.

NOTES:

4.  is measured with the component mounted on a high effective thermal conductivity test board in free air. See Tech Brief TB379 for details.

JA

5. For  , the “case temp” location is taken at the package top center.

JC

Electrical Specifications

V

+ = 5.0V, V

- = 0V, A

= 5V, D

= 5V XTALIN/CLOCK = 4.9152MHz (Note 6)

REF

VDD

T

= -40°C to +105°C, unless otherwise specified. Boldface limits apply over the operating temperature range, -40°C to +105°C.

A

MIN

MAX

SYMBOL

ANALOG INPUTS

PARAMETER

TEST LEVEL OR NOTES

(Note 7)

TYP

(Note 7)

UNITS

V

V_IN

Differential Input Voltage Range

±0.5V /

REF

Gain

Input Voltage Range: Common Mode +

Signal

Gain = 1

A

+ 0.1

A

- 0.1

V

GND

VDD

Gain = 2, 4, 8, 16, 32, 64, 128

Gain = 1

+ 1.5

A

- 1.5

V

GND

VDD

Input Bias Current; AIN+, AIN-

300

3

nA

Gain = 2, 4, 8, 16, 32, 64, 128

Gain = 1

Input Offset Current; AIN+, AIN-

±20

±1

Gain = 2, 4, 8, 16, 32, 64, 128

SYSTEM PERFORMANCE

Resolution

No Missing Codes

Gain = 1

24

Bits

INL

Integral Nonlinearity

±0.0002

±0.0004

±0.4

±0.001

% FSR

Gain = 2 to 128

Gain = 1

Offset

ppm of

FS

Offset Drift

Gain = 1

±300

nV/°C

Gain = 2 to 128

±300/Gain

± 10

Full Scale Error

Full Scale Drift

Gain = 1

±0.007

±0.02

±0.1

±3.5

110

%

Gain = 2 to 128

Gain = 1

ppm/°C

dB

Gain = 64

Gain = 128

Gain of 1

CMRR

PSRR

OWR

Common Mode Rejection Ratio

Power Supply Rejection Ratio

Output Word Rate (Note 8)

85

Gain of 128

Gain of 1

130

dB

100

dB

Gain of 128

100

2.5

125

dB

4000

SPS

FN7608 Rev 0.00

October 12, 2012

Page 4 of 21

ISL26102, ISL26104

Electrical Specifications

V

+ = 5.0V, V

REF

- = 0V, A

VDD

= 5V, D = 5V XTALIN/CLOCK = 4.9152MHz (Note 6)

VDD

REF

T

= -40°C to +105°C, unless otherwise specified. Boldface limits apply over the operating temperature range, -40°C to +105°C. (Continued)

A

MIN

MAX

SYMBOL

VOLTAGE REFERENCE INPUT

VREF Voltage Reference Input

VREF+ Positive Voltage Reference Input

PARAMETER

TEST LEVEL OR NOTES

(Note 7)

TYP

5.0

(Note 7)

UNITS

VREF = VREF+ - VREF-

1.5

A

+ 0.1

V

VDD

V

+ 1.5

A

+ 0.1

- 1.5

REF-

VDD

VREF-

VREFI

Negative Voltage Reference Input

Voltage Reference Input Current

A

- 0.1

V

GND

REF+

350

nA

Low-Side Power Switch

r

ON-resistance

10



ON

Continuous Current

30

mA

Power Supply Requirements

A

Analog Supply Voltage

Digital Supply Voltage

Analog Supply Current

4.75

2.7

5.0

6

5.25

10

V

VDD

D

V

VDD

A

Gain of 1

mA

µA

IDD

Gain = 2 to 128

Power-down

Standby

9

12

0.2

0.3

750

1

2.5

D

Digital Supply Current

Gain of 1

950

26

IDD

Gain = 2 to 128

Power-down

Standby

1.8

Power

Normal

Gain = 1

33.75

48.75

6

54.75

64.75

Gain = 2 to 128

Power-down

Standby

mW

µW

10.5

Digital Inputs

V

0.7 D

VDD

V

IH

V

0.2 D

IL

VDD

V

I

= -1mA

= 1mA

D - 0.4

VDD

V

OH

OL

V

0.2 D

V

OL

VDD

Input Leakage Current

±10

µA

MHz

External Clock Input Frequency

Serial Clock Input Frequency (Note 9)

0.3

4.9152

4

NOTES:

6. If the device is driven with an external clock, best performance will be achieved if the rise and fall times of the clock are slowed to less than 20ns

(10% to 90% rise/fall time).

7. Compliance to datasheet limits is assured by one or more methods: production test, characterization and/or design.

8. Output word rates (MIN and MAX in the table) are specified using 4.9152MHz clock. If a different clock frequency is used, or if the internal oscillator

is used as the clock source for the converter, the output word rates will scale proportionally to the change in the clock frequency.

9. The OWR (Output Word Rate) setting dictates the rate at which the SDO/RDY signal will fall. To read every conversion word, reading of the conversion

word should begin immediately after SDO/RDY falls and the SCLK rate should be fast enough to read all 24 data bits of the conversion word before

the next falling edge of SDO/RDY that indicates that a new conversion word is available.

FN7608 Rev 0.00

October 12, 2012

Page 5 of 21

ISL26102, ISL26104

TABLE 1. INPUT REFERRED NOISE (nV, RMS)

PGA GAIN

OUTPUT WORD RATE

(Note 10)

1

2

4

8

16

32

64

128

6.5

2.5

187.1

101.8

112.2

133.0

157.7

207.1

264.6

292.7

368.2

405.5

517.0

52.0

25.0

14.5

8.8

6.6

5

209.2

253.6

308.3

417.7

55.9

28.5

16.3

10.5

8.4

8.2

10

63.8

35.5

20.0

13.9

11.9

15.7

23.3

31.6

35.4

46.2

50.6

64.1

72.6

90.2

101.0

112.4

124.3

134.0

147.6

162.3

178.0

196.0

11.6

15.2

22.4

30.1

34.3

45.2

49.5

62.5

70.5

87.4

20

77.6

43.8

25.0

18.1

25.3

40

105.1

140.1

159.4

203.0

222.2

284.5

318.1

398.0

445.0

489.5

557.0

632.0

708.8

801.0

891.0

955.1

60.2

35.1

80

100

547.2

78.2

46.8

34.9

607.0

87.5

52.2

39.7

160

780.3

845.1

1030.6

1169.0

1476.0

1632.0

1806.1

2018.0

2289.0

2572.5

2945.0

3287.0

3708.2

110.6

119.7

147.2

165.3

211.0

237.2

267.0

297.6

328.0

365.8

423.7

478.0

545.1

68.0

52.3

200

74.2

57.3

320

93.2

72.5

400

591.7

756.0

857.9

958.6

1089.0

1234.0

1380.4

1538.0

1711.0

1876.9

105.2

129.7

139.5

157.8

180.2

202.3

230.2

259.0

285.0

316.6

81.9

640

102.4

114.7

126.8

143.7

163.4

176.0

201.0

221.0

242.8

800

98.9

107.7

123.5

132.0

145.8

161.3

174.3

194.9

1000

1280

1600

2000

2560

3200

4000

NOTE:

4

10. The ADC has a programmable SINC filter. The -3dB bandwidth of the filter for a given word rate is 0.239 x OWR.

10000

1000

1X

100

10

1

2X

4X

8X

16X

32X

64X

128X

1

10

100

1000

10000

WORD RATE (Sps)

FIGURE 2. NOISE vs GAIN AND WORD RATE SETTINGS

FN7608 Rev 0.00

October 12, 2012

Page 6 of 21

ISL26102, ISL26104

TABLE 2. NOISE FREE BITS

NOISE-FREE BITS

OUTPUT WORD RATE

(Note 11)

1

2

4

8

16

32

64

128

19.8

19.5

19.0

18.6

18.0

17.6

17.4

17.0

16.9

16.5

16.4

16.0

15.9

15.7

15.5

15.3

15.2

15.1

14.9

2.5

21.9

21.8

21.5

21.2

20.8

20.4

20.3

19.9

19.8

19.5

19.3

19.0

18.8

18.7

18.5

18.3

18.2

18.0

17.8

17.6

21.8

21.7

21.4

21.2

20.8

20.4

20.3

20.0

19.8

19.5

19.3

18.9

18.8

18.6

18.4

18.2

18.1

17.9

17.8

17.6

21.8

21.7

21.5

21.2

20.8

20.4

20.2

19.8

19.7

19.3

19.2

18.9

18.7

18.6

18.4

18.2

18.0

17.9

17.7

17.6

21.9

21.7

21.3

21.0

20.6

20.2

20.0

19.7

19.6

19.3

19.1

18.8

18.6

18.4

18.3

18.1

18.0

17.8

17.6

17.4

21.6

21.5

21.2

20.9

20.4

19.9

19.8

19.4

19.3

19.0

18.8

18.5

18.4

18.2

18.0

17.8

17.7

17.5

17.3

17.2

21.4

21.1

20.7

20.3

19.8

19.4

19.2

18.8

18.7

18.3

18.1

17.8

17.7

17.5

17.3

17.1

17.0

16.8

16.7

16.6

20.8

20.4

19.9

19.5

19.0

18.5

18.4

18.0

17.8

17.5

17.3

17.0

16.8

16.7

16.5

16.4

16.3

16.2

16.0

15.9

5

10

20

40

80

100

160

200

320

400

640

800

1000

1280

1600

2000

2560

3200

4000

NOTE:

11. Noise-free resolution in Table 2 is calculated as LOG ((Input Span)/(RMS Noise x 6.6))/LOG(2). The result is rounded to the nearest tenth of a bit. The

Input Span is equivalent to ±0.5VREF/GAIN, V

= 5V. The RMS noise is selected from Table 1 for the desired Output Word Rate and Gain option.

REF

10

10000

8

6

4

2

0

NORMAL MODE

1000

NORMAL MODE, ALL PGA GAINS

100

10

POWERDOWN MODE

1

-40

-10

20

50

80

110

-10

20

50

80

110

TEMPERATURE (°C)

FIGURE 3. ANALOG CURRENT vs TEMPERATURE (GAIN = 2 TO 128)

FIGURE 4. DIGITAL CURRENT vs TEMPERATURE

FN7608 Rev 0.00

October 12, 2012

Page 7 of 21

ISL26102, ISL26104

Typical Characteristics

1000

100

10

1

100

10

1

0.1

1

10

100

1000

0.1

1

10

100

1000

FREQUENCY (Hz)

FIGURE 5. NOISE SPECTRAL DENSITY, 4kSPS, PGA GAIN = 1

FIGURE 6. NOISE SPECTRAL DENSITY, 4kSPS, PGA GAIN = 128

1x

+

AIN1+

-

390

AIN2+

AIN1-

AIN2-

CAP

100nF

CAP

2x, 4x, 8x, 16x

32x, 64x, 128x

3^RDORDER

AVDD

PROGRAMMABLE

DIGITAL FILTER

SERIAL

PORT



MODULATOR

-

390

TEMP

SENSOR

+

1x

FIGURE 7. ISL26102 (2 CHANNEL) BLOCK DIAGRAM

FN7608 Rev 0.00

October 12, 2012

Page 8 of 21

ISL26102, ISL26104

Circuit Description

5.00

4.50

4.00

3.50

3.00

2.50

2.00

1.50

1.00

0.50

0.00

AIN-

A key element in the ISL26102/ISL26104 A/D converters is its

low noise chopper-stabilized programmable gain amplifier. The

amplifier features seven gain settings (2x, 4x, 8x, 16x, 32x, 64x,

and 128x). On these gain settings, the amplifier has very high

input impedance but has restricted common mode range, which

does not extend all the way to the power supply rails. When the

gain of 1x is selected, the chopper-stabilized amplifier is

bypassed. The modulator input, which is used directly in 1x gain,

has a common mode range that extends to the supply rails. But,

because of this greater common mode range on the 1x gain

setting, the input current is higher than on the other gain

settings.

AIN+

2.500

VCM

2.500

FIGURE 8. DIFFERENTIAL INPUT FOR V

= 5V, GAIN = 1X

REF

Digital Filter

The output of the delta-sigma modulator in the A/D converter is

filtered with a Sinc digital filter that includes programmable

The ISL26102 provides the user with two fully differential signal

inputs at the multiplexer plus two other internal channel

selections, which allow the user to monitor the analog supply

voltage of the chip, and the on-chip temperature sensor. The

ISL26104 provides the user with two additional fully differential

inputs on the multiplexer.

4

decimation to achieve a wide range of output word rates. The

4

transfer function of the Sinc filter is illustrated in Figure 9.

Figure 9 is normalized to 1 being the output word rate. The

output word rate can be selected by setting bits in the OWR

(Output Word Rate) Register. The converter provides a wide

selection of word rates as shown in Table 3. Note that the word

rates are based upon an XTALIN/CLOCK of 4.9152MHz. If the

clock is a different frequency than 4.9152MHz, the actual output

word rate will scale proportionally.

The programmable gain amplifier has a passive RC filter on its

output. The resistors are located inside the chip on the outputs of

the differential amplifier stages. The capacitor (nominally a

100nF C0G ceramic or PPS film (Polyphenylene sulfide)) for the

filter is connected to the two CAP pins of the chip. The outputs of

the differential amplifier stages of the PGA are filtered before

their signals are presented to the delta-sigma modulator. This

filter reduces the amount of noise by limiting the signal

bandwidth and eliminating the chopping artifacts of the chopped

PGA stage.

TABLE 3. OUTPUT WORD RATE REGISTER SETTINGS

DATA RATE (Sps)

2.5

REGISTER CODE (Hex)

00

01

02

03

04

05

0B

06

0C

07

0D

08

0E

11

09

0F

12

0A

10

13

5

Figure 7 illustrates a block diagram of the programmable gain

amplifier.

10

20

Functional Description

Analog Input Span

40

80

100

The input span of the A/D converter is determined by the

magnitude of the voltage reference and the gain setting

selection. The voltage reference magnitude is determined by the

voltage difference between the VREF+ and the VREF- pins. This

voltage may be as low as 1.5V or as great as the analog supply

voltage to the chip. The voltage on the VREF pins is scaled to accept

a voltage into the A/D converter on 1x gain of ±0.5 VREF/GAIN

where gain is 1. An illustration of the input span when using a 5V

160

200

320

400

640

V

is in Figure 8. The figure illustrates that with a V = 5V and a

REF

800

gain setting of 1x, the input span will be ±2.5V, which is a fully

differential signal. If the programmable gain amplifier gain is set to

another value other than 1x, the input span will be reduced by the

1000

1280

1600

2000

2560

3200

4000

gain scale factor. With a V

= 5V and the PGA gain set at 128x,

REF

the input span into the ADC will be [±(0.5)5V]/128 = ±19.53mV on

a fully differential basis.

FN7608 Rev 0.00

October 12, 2012

Page 9 of 21

ISL26102, ISL26104

0

-20

CRYSTAL

XTALIN/

CLOCK

OSCILLATOR

-40

CLOCK DETECT

-60

-80

EN

INTERNAL

-100

-120

-140

-160

-180

OSCILLATOR

XTALOUT

MUX

TO ADC

-200

0.10

1.00

10.00

FIGURE 10. CLOCK GENERATOR BLOCK DIAGRAM

NORMALIZED FREQUENCY (1.00 = OWR)

4

Overview of Registers and A/D Converter

Operation

FIGURE 9. TRANSFER FUNCTION OF SINC NORMALIZED TO

1 = OUTPUT WORD RATE

The ISL26102, ISL26104 devices are controlled via their serial

port by accessing various on-chip registers. Communication to

the A/D via the serial port occurs by writing a command byte

followed by a data byte. All registers in the converter are

accessed or written as 8-bit wide registers, even though some

data words may be up to three bytes in length. The converter has

offset registers (three bytes wide) associated with each PGA gain

setting. These registers hold the offset calibration word, a three

byte twos complement word, for each gain selection. When

power is first applied to the converter these registers are reset to

zero. Note that the ISL26102, ISL26104 converters do not have

gain calibration registers for the PGA gains. This is because the

gain for each PGA gain setting is calibrated at the factory.

Digital Filter Settling Time

If the Input Mux Selection register is written into to select a new

channel, the modulator and the digital filter are reset and the

converter begins computing a new output word when the new

mux selection is made. The first conversion word output from the

A/D after a new mux channel is selected, or after the PGA gain is

4

changed, will be delayed to allow the filter to fully settle. A Sinc

filter takes four conversion times to fully settle, therefore the

SDO/RDY signal will not fall until a time of four normal

conversion periods has elapsed. The SDO/RDY output falls to

signal that an output conversion word is ready to be read.

Whenever the input signal has a large step change in value, it

may take as many as six output conversions for the output word

to accurately represent the new input value.

Table 4 list the registers inside the ADC. When power is first

applied the Offset Array Registers, registers which hold the offset

calibration words for each PGA gain, are set to zero.

Clock Sources

The Chip ID register has a bit, which allows the user to identify

whether the chip is an ISL26102 (2 channel) or an ISL26104

(4 Channel) device. This register also has a code, which is

assigned to reveal the revision of the chip.

The ISL26102/ISL26104 can operate from an internal oscillator,

and external clock source, or from a crystal connected between

the XTALIN/CLOCK and XTALOUT pins. See the block diagram for

the clock system in Figure 10. When the converter is powered up,

the CLOCK DETECT block determines if an external clock source

is present. If a clock signal greater than 300kHz is present on the

XTALIN/CLOCK pin, the circuitry will disable the internal oscillator

and use the external clock as the clock to drive the chip circuitry.

If the ADC is to be operated from the internal oscillator the

XTALIN/CLOCK pin should be grounded. If the ADC is to be

driven with an external clock there should be a 100 resistor

placed in series with the clock signal to the XTALIN/CLOCK pin.

This helps slow the rise and fall time edges, which can impact

converter performance. If the ADC is to be operated with a

crystal, the crystal should be located very close to the A/D

converter package pins. Note that loading capacitors for the

crystal are not required as there are loading capacitors built into

the silicon, although the capacitor values are optimized for

operation with a 4.9152MHz crystal.

The SDO/LSPS register allows the user to control the behavior of

the SDO (Serial Data Output) output. If bit (b1) is set to logic 0,

the SDO/RDY output will go low when conversions are completed

and output the 24-bit conversion word if CS is taken high and 24

SCLKs are issued to the SCLK pin. If the SDO bit in this register is

set to logic 1, the SDO output will be set to a tri-state condition

(high output impedance). This allows another device, such as

another A/D converter, to be connected to this same signal line

going to the microcontroller.

The LSPS (Low-Side Power Switch) bit allows the user to toggle a

switch via the LSPS pin that can be used to enable power to a

load cell or other circuitry. When the LSPS bit is logic 0 the LSPS

switch is open. When the LSPS bit is logic 1, the switch is closed.

The LSPS bit is set back to a logic 0 if the chip is put into Standby

via the Standby Register, or if the PDWN signal is activated. See

data sheet tables for the current capability of the switch.

The Standby register has a bit which when set to logic 1, the chip

enters the standby mode. In standby mode, the chip enters a low

power state. Only the crystal oscillator is left powered (if used) to

enable a quick return to full operation when bit (b0) is set back to

logic 0. If the crystal is not being used, it is not powered. In this

FN7608 Rev 0.00

October 12, 2012

Page 10 of 21

ISL26102, ISL26104

case, there is no difference in power consumption for standby or

power-down modes.

If the b1b0 bits are set to 10, conversions will be performed

continuously until bits b1b0 are set to either 00 or 01, Standby

mode is activated, or the PDWN pin is taken low. Refer to

“Reading Conversion Data” on page 14.

The Output Word Rate register allows the user to set the rate at

which the converter performs conversions. Table 3 lists the

output word rate options.

The Delay Timer register allows the user to program a delay time,

which will be inserted between the time that the user selects an

input to be converted via the Input Mux Selection register and

when the conversion is started. If continuous conversions are

selected via the Conversion Control register, the Input Mux

Selection register can be changed without needing to stop

conversions. The Delay Timer register allows the user to insert a

delay between when the mux is changed and when a new

conversion is started. If the Delay Timer register is set to all 0's

the minimum delay will be 100µs.

The Input Mux Selection register defines the input signal that will

be used when conversions are performed. The signals include

either 2 (ISL26102) or 4 (ISL26104) differential input channels,

an on-chip temperature sensor, or the monitor node for the AVDD

supply voltage. Note that if the temperature sensor or the AVDD

monitor are selected the PGA gain is internally set for 1x gain.

The PGA Gain register allows the user to set the PGA gain setting

for the channel pointed to by the Channel Pointer register. The

PGA provides gain settings of 1x (in this gain setting the

programmable gain amplifier is actually bypassed and the signal

goes directly to the modulator), 2x, 4x, 8x, 16x, 32x, 64x, and

128x.

Any time the PGA Gain setting is changed, the channel selection

is changed, or a command is given to start conversion(s), the

user can expect a delay before the SDO/RDY signal will fall. This

delay is defined by Equation 1:



The Conversion Control register provides the means to initiate

offset calibration, or initiate single or continuous conversions. If

bit b2 of this register is set to a logic 1, an offset calibration will

be performed and the states of bits b1 and b0 are ignored. The

state of bit b2 will be set back to a logic 0 after the offset

calibration is complete.

4ms + Delay Timer Register Setting 4ms + 100s + 4 1  OWR

(EQ. 1)

The first 4ms is for the PGA to settle. This delay cannot be

changed. The Delay Timer register setting is user controllable,

and it dictates the majority of the second section of the equation.

The 4*(1/OWR) term is the time required for the filter to settle at

the OWR (Output Word Rate), which has been selected in the

Output Word Rate register.

If the b1b0 bits are set to 01, a single conversion will be

performed. When the conversion is completed, the bits will be set

back to 00, the SDO/RDY pin will be taken low (note that the CS

pin must be a logic 1 for SDO/RDY to fall) and the conversion

data will be held in a register. If the user enables CS (held at

logic 1) and provides 24 SCLKs to the SCLK pin, the data word

will be shifted out of the SDO/RDY pin as a 24-bit two’s

complement word, starting with the MSB. Data bits are clocked

out on the rising edge of SCLK. If the entire 24-bit data word is

not read before the completion of the next conversion, it will be

overwritten with the new conversion word.

The PGA Offset Array registers hold the calibration results for the

offset calibration done for each of the PGA gain settings. The

result of an offset calibration is a 24-bit twos complement word.

There are eight high byte registers, eight mid byte registers and

eight low byte registers. When reading or writing to one of the

PGA Offset Array byte registers, the register selected will be

determined by the PGA Pointer Register.

The PGA Pointer register contains the pointer to the PGA Offset

register array bytes associated with a specific PGA gain.

FN7608 Rev 0.00

October 12, 2012

Page 11 of 21

ISL26102, ISL26104

TABLE 4. CONTROL REGISTERS

NAME

ADDRESS

DATA BITS

NOTES

Write Read b7 b6 b5 b4 b3 b2 b1 b0

Registers are Accessed by Address Byte followed by Register Data Byte

Chip ID

N/A

82h

00h b4

0 = ISL26104

1 = ISL26102

b3-b0

Revision Code

SDO/LSPS

Standby

02h b1

1= Disable SDO

0 = Enable SDO

b0

1 = LSPS ON

0 = LSPS OFF

0 is default

83h

03h b0

1 = Enable Standby

0 = Disable

0 is default

Output Word 85h

Rate

05h See Table 3 on page 9

0 is default, 2.5Sps

Input Mux

Selection

87h

07h ISL26104

b2 b1 b0

000 = Channel 1

001 = Channel 2

010 = Channel 3

011 = Channel 4

100 = Analog Supply Monitor

101 = Temperature Sensor

110 = Not used

111 = Not used

ISL26102

b2 b1 b0

000 = Channel 1

001 = Channel 2

010 = Analog Supply Monitor

011 = Temperature Sensor

100 = Not used

101 = Not used

110 = Not used

111 = Not used

Channel

Pointer

88h

08h ISL26104

b2 b1 b0

000 = Channel 1

001 = Channel 2

010 = Channel 3

011 = Channel 4

100 = Analog Supply Monitor

101 = Temperature Sensor

110 = Not used

111 = Not used

ISL26102

b2 b1 b0

000 = Channel 1

001 = Channel 2

010 = Analog Supply Monitor

011 = Temperature Sensor

100 = Not used

101 = Not used

110 = Not used

111 = Not used

FN7608 Rev 0.00

October 12, 2012

Page 12 of 21

ISL26102, ISL26104

TABLE 4. CONTROL REGISTERS (Continued)

DATA BITS

NAME

ADDRESS

97h 17h b2 b1 b0

NOTES

PGA Gain

PGA Gain Setting for Channel Pointed to by the Channel Pointer Register.

Whenever the Analog Supply Monitor or the Temp Sensor are selected, the PGA

gain is set to 1x.

000 = 1x

001 = 2x

010 = 4x

011 = 8x

100 = 16x

101 = 32x

110 = 64x

111 = 128x

Conversion

Control

84h

04h b2

0 = Off

Performing Offset Calibration has priority over instructions from bits b1b0

1 = Perform Offset Calibration

b1 b0

00 = Stop Conversions

01 = Perform Single Conversion

10 = Perform Continuous Conversions

11 = Not Used

Delay Timer

C2h

BDh

42h b7-b0 The start of conversion is delayed

by: Delay = Register Word*4ms + 100µs

PGA Offset

Array

3Dh Offset Calibration Result

Most Significant Byte

For PGA Pointed to by PGA Pointer Register

(High Byte)

PGA Offset

Array

(Mid Byte)

BEh

BFh

3Eh Offset Calibration Result

Middle Byte

For PGA Pointed to by PGA Pointer Register

PGA Offset

Array

3Fh Offset Calibration Result

Low Byte

For Channel Pointed to by Channel Pointer Register

(Low Byte)

PGA Monitor Bch

3ch b2 b1 b0

000 = 1x

This register points to the offset register associated with the PGA gain selection

001 = 2x

010 = 4x

011 = 8x

100 = 16x

101 = 32x

110 = 64x

111 = 128x

See Figure 11 for an illustration of the timing to write on-chip

registers.

Writing to On-chip Registers

Writing into a register on the chip involves writing an address

byte followed by a data byte. The lead bit of the address byte is

always a logic 1 to indicate that data is to be written. The

remaining seven bits of the address byte contain the address of

the register that is to be written. To begin the write cycle, CS must

first be taken low with SCLK low. This should occur at least

If multiple registers are to be written, CS should be taken high

after each address byte/data byte combination and remain high

for at least a period of time equal to 6*1/(Xtal/Clock) frequency.

If the chip is operating from a 4.9152MHz master clock, this

would mean that CS should remain high between write cycles for

at least 6*1/4.9152MHz = 1.22µs.

125ns before SCLK goes high. This is shown as t in the timing

cs

diagram of Figure 11. Once CS is low, the user must then present

the lead bit to the SDI port. The data bits will be latched into the

Lower frequency master clock rates (minimum master clock rate

can be as low as 300kHz) will require CS to remain high for a

longer period of time between register write cycles.

port by rising edges of SCLK. The data set-up time (t ) of the

ds

data bits to the rising edge of SCLK is 50ns (Note that one half

clock cycle of the highest SCLK rate is 1/(2*4 MHz) = 125ns).

Each time an address/data byte combination is written into the

port, the master clock is used to place the data into the register

after CS returns high. This is required because the data transfer

must be synchronized to the clock that is driving the

modulator/filter circuitry.

Data hold time (t ) is also 50ns. Data bits should be advanced

dh

to the next bit on falling edges of SCLK. Once the eight data bits

have been written, CS should be returned to high. (CS must be

high to read conversion data words from the port). When CS goes

high the user should ignore any activity on the SDO/RDY pin for

at least 10 cycles of the master clock, which is driving the ADC.

FN7608 Rev 0.00

October 12, 2012

Page 13 of 21

ISL26102, ISL26104

will then wait for the SDO/RDY signal to fall. Once the SDO/RDY

signal falls, the 24-bit conversion data word becomes available to

the port. To read the conversion word, the CS signal should be left

in the logic 1 state and 24 SCLKs issued to the SCLK pin. The first

rising SCLK edge will make the MSB data bit of the 24-bit word

become available. The falling edge of the first SCLK will latch the

bit into the external receiving logic device. Subsequent rising

edges of SCLK will cause the port output to advance to the next

data bit. Once the last data bit is read, the SCLK signal should

remain low until another conversion word is available or until a

command to write or read an on-chip register is performed.

Reading from On-chip Registers

Reading from a register on the chip begins by writing an address

byte into the SDI port. The lead bit of the address byte is always a

logic 0 to indicate that data is to be read from an on-chip register.

The remaining seven bits of the address byte contains the

address of the register that is to be read. To begin the read cycle,

CS must first be taken low with SCLK low and be low for at least

125ns before SCLK is taken high to latch the first data bit. The

eight address bits will be latched into the port by rising edges of

SCLK. The data set-up time (t ) of the data bits to the rising edge

ds

of SCLK is 50ns (one half clock cycle of the highest SCLK rate is

1/(2*4MHz) = 125ns). Data hold time (t ) is also 50ns. Address

SDO/RDY goes low to signal that a conversion has been

performed and that the conversion word is available. If the

analog input signal goes over range this may cause the

modulator to become unstable. If this condition occurs the

modulator resets itself. The output code will be held at full scale

but the effect of the modulator being reset will cause the

SDO/RDY signal to fall at only one fourth of its word rate. This

occurs because when the modulator is reset, the digital filter is

also reset and it takes four conversion periods for the filter to

accumulate enough modulator bit stream information to produce

an accurate conversion result.

dh

bits should be advanced to the next bit on falling edges of SCLK.

Once the address byte has been written, the port will output a

byte from the selected 8-bit register onto the SDO pin. A total of

16 SCLKs are required to write the address byte and then read

the 8-bit register output. The timing for reading from on-chip

registers is illustrated in Figure 12.

Reading Conversion Data

Reading conversion data is done in a different manner than

when reading on-chip registers. After writing into the Conversion

Control register to instruct the A/D to start conversions, the user

CS

t

sc

cs

1

2

3

4

5

6

7

8

9

1

0

1

2

1

3

1

4

1

5

1

6

SCLK

t

ds dh

A

6

A

5

A

4

A

3

A

2

A

1

A

0

D

7

D

6

D

5

D

4

D

3

D

2

D

1

D

0

SDI

W

DON’T CARE

FIGURE 11. WRITE ON-CHIP REGISTER WAVEFORMS

CS

t

sc

cs

t

1

2

3

4

5

6

7

8

9

1

0

1

2

1

3

1

4

1

5

1

6

SCLK

SDI

t

DON’T CARE

ds dh

R

X

A

6

A

5

A

4

A

3

A

2

A

1

A

0

X

Q

7

Q

6

Q

5

Q

4

Q

3

Q

2

Q

1

Q

0

X

XX (DON’T CARE)

SDO

FIGURE 12. READ ON-CHIP REGISTER WAVEFORMS

CS

DATA READY

DATA

NEW DATA READY

MSB

LSB

2

3

2

1

0

SDO/RDY

SCLK

1

2

3

4

2

4

FIGURE 13. READING CONVERSION DATA WORD WAVEFORMS

FN7608 Rev 0.00

October 12, 2012

Page 14 of 21

ISL26102, ISL26104

Output Data Format

DVDD

The converter outputs data in twos complement format in

accordance with coding shown in Table 5.

TABLE 5. OUTPUT CODES CORRESPONDING TO INPUT

1kΩ

INPUT SIGNAL

+ 0.5V /GAIN

DESCRIPTION

+ Over-range

+ 1 LSB

OUTPUT CODE (HEX)

7FFFFF

CONNECT TO

PDWN PIN

REF

2.2nF

23

0.5V

0

/[GAIN*(2 - 1)]

000001

REF

FIGURE 14. PDWN DELAY CIRCUIT

Zero Input

- 1 LSB

000000

23

-0.5V

/[GAIN*(2 -1)]

FFFFFF

REF

Standby Mode Operation

- 0.5V

/GAIN

REF

- Over-range

800000

The A/D converter can be placed in the standby mode by writing

to the Standby register. Standby mode causes the converter to

enter a low power state except for the crystal oscillator amplifier.

If the converter is operated with a crystal connected to the

XTALIN/CLOCK and XTALOUT pins the crystal will continue to

oscillate. This reduces start-up time when the Standby register

bit is written back to logic 0 to exit standby mode.

Operation of PDWN

When power is first applied to the converter, the PDWN pin must

transition from Low to High after both power supplies have

settled to specified levels in order to initiate a correct internal

power-on reset. A means of controlling the PDWN pin with a

simple RC delay circuit is illustrated in Figure 14. If AVDD and

DVDD are different supplies, be certain that AVDD is fully

established before PDWN goes high.

Low Side Power Switch

The ADC includes a low side power switch. The LSPS pin is an

open drain connection to a transistor, which can be turned on or

off via bit control in the SDO/LSPS register. The LSPS switch can

be used to enable/disable excitation to external systems, such as

a load cell. Figure 15 illustrates the typical connection of the ADC

in a load cell measurement system. The LSPS pin is connected to

the low side of the load cell.

The PDWN pin can be taken low at any time to reduce power

consumption. When PDWN is taken low, all circuitry is shut

down, including the crystal oscillator. When coming out of

power-down, PDWN is brought high to resume operation. There

will be some delay before the chip begins operation. The delay

will depend upon the source of the clock being used. If the

XTALIN/CLOCK pin is driven by an external clock, the delay will be

minimal. If the crystal oscillator is the clock source, the oscillator

must start before the chip can function. Using the on chip crystal

oscillator amplifier with an attached 4.9152MHz clock will

typically require about 20ms to start-up.

5V

3.3V

0.1µF

18

1

6

DVDD

AVDD

16

9

VREF+

CAP

GAIN = 128

24

SDO/RDY

0.1µF

10

23

21

SCLK

SDI

CAP

-

+

ISL26102

20

22

MICRO

CONTROLLER

CS

PDWN

11

12

AIN1+

AIN1-

AIN2+

AIN2-

4

3

XTALOUT

13

14

15

19

XTALIN/CLOCK

VREF-

LSPS

AGND

17

DGND

2, 5, 7, 8

FIGURE 15. A LOAD CELL MEASUREMENT APPLICATION USING THE ISL26102

FN7608 Rev 0.00

October 12, 2012

Page 15 of 21

ISL26102, ISL26104

23

)/2 = 298nV. Since the converter

span is bipolar, and its span represents ± 8.338 million codes,

the +111.7mV will output of a code of approximately 374,800

counts.

converter will be ±0.5(V

REF

Device Supply and Temperature Monitoring

One of the multiplexer input selections is the AVDD Monitor. This

option allows the A/D converter to measure a divided down value

of the AVDD voltage. The nominal output code from AVDD

23

monitor is given by (2 )*AVDD/(2*VREF). Table 6 provides a

The on-chip temperature will typically be about 3° hotter than

ambient because the device's power consumption is about

50 mW and the thermal impedance from die to ambient is about

63°/W; (0.05)*63 = 3.15°.

listing of the nominal count of the A/D converter associated with

supply voltage values between 4.75 and 5.25V. Table 6 is based

on V

= 5V.

REF

If a V

REF

of 2.5V is used, the output code from the A/D converter

Getting Started

will stay at +Full Scale when AVDD > 5V. Thus, the AVDD monitor

will not be able to check the voltages greater than 5V, but it will

provide proper readings for AVDD voltages below 5V.

When power is first applied to the converter, the PDWN pin

should be held low until the power supplies and the voltage

reference are stable. Then PDWN should be taken high. When

this occurs the serial port logic and other logic in the chip will

have been reset. The chip contains factory calibration data stored

in on-chip non-volatile memory. When PDWN goes positive this

data is transferred into the appropriate working registers. This

initialization can take up to 12.6ms. If an external clock or the

internal oscillator are used as the clock for the chip, then this

12.6ms time includes the time necessary for these to be

functional. But, if the crystal oscillator is used, the crystal may

take 20ms to start up before the 12.6ms initialization occurs.

Writing into or reading from the serial port should be delayed

until the clock source and the initialization period have elapsed.

TABLE 6. ANALOG SUPPLY MONITOR OUTPUT CODES OVER SUPPLY

VOLTAGES (V

= 5.0V)

REF

AVDD

(V)

OUTPUT CODE

(±5%)

5.25

5.10

5.00

4.90

4.75

4407063

4281464

4197996

4114662

3989915

Once the clock source and initialization period have elapsed, the

user should configure the ADC by writing into the appropriate

registers. The commands and the corresponding data bytes that

are to be placed into each of the registers are shifted into the SDI

pin with CS held low. CS should be taken high for at least six

cycles of the master clock after each command/data byte

combination. This allows the control logic to properly synchronize

the writing of the register with the master clock that controls the

modulator/filter system. Each command/data byte combination

should have its own CS cycle of CS going low, shifting the data,

then CS going high, and remaining high for at least six cycles of

the master clock.

+

TO BUFFER/PGA

24-BIT ADC

AIN1 +

-

AIN1 -

AIN2 +

AIN2 -

AIN3 +

AIN3 -

AIN4 +

AIN4 -

TEMP

Even though the device has been powered up, reset, and its

register settings have been configured, the programmable gain

amplifier and modulator portions of the ADC remain in a low

power state until a command to start conversions is written into

the Conversion Control register. To minimize drift in the device

due to self-heating, it is recommended that after all registers are

initialized to their initial condition, the command to start

continuous conversions be issued as soon as is practical.

Subsequent changes to registers, such as selecting another mux

channel, should be performed with continuous conversions

active. The proper method of writing to the other registers when

continuous conversions are active is to wait for SDO/RDY to fall,

read the conversion data, then take CS low and issue the

command and the data byte that is to be written into a register,

then return CS high. If multiple registers are to be written, CS

should be toggled low and high to frame each command/data

byte combination. Whenever any of the following registers

[SDO/LSPS, Output Word Rate, Input Mux Selection, PGA Gain,

Delay Timer, PGA Offset Array, or Offset Calibration] are written

with continuous conversions in progress, the digital filter will be

reset and there will be a delay determined by Equation 1 on

page 11. The delay will begin when CS returns and remains high.

When the delay has elapsed, the SDO/RDY signal will go low to

SENSOR

AVDD

FIGURE 16. INPUT MULTIPLEXER BLOCK DIAGRAM

When the Input Mux Selection register is instructed to select the

on-chip temperature sensor signal, the A/D measures a

differential voltage produced between two diodes that are biased

at different operating currents. The differential voltage is defined

by Equation 2:

(EQ. 2)

V = 102.2 mV + (379µV* T(°C))

Whenever the temperature sensor is selected in the Input Mux

Selection Register, the Gain is set to 1x.

At a temperature of +25°C the measured voltage will be

approximately 111.7mV. The actual output code from the

converter will depend upon the magnitude of the VREF signal.

The 111.7mV signal will be a portion of the span set by the VREF

voltage using a gain setting of 1x. If V

is 5V, one code in the

REF

FN7608 Rev 0.00

October 12, 2012

Page 16 of 21

ISL26102, ISL26104

signal that a conversion data word is available. The Chip ID

register (read only), the Channel Pointer register, and the PGA

Monitor register can be read or written without any effect to the

filter, and therefore there will be no delay in SDO/RDY falling. If

the Standby register is enabled, conversions will be stopped.

in the PGA Offset Arrays. Some user applications prefer to calibrate

their system in the factory, then off load the calibration data and

write it into non-volatile memory. Then when the product is powered

up, this data is written back into the registers of the ADC.

1. Write into the PGA Pointer register (BCh) the selection wanted

for the Gain of the PGA.

Performing Calibration

2. Read the three different PGA Offset Array registers, High byte

(3Dh), Mid byte(3Eh), and Low byte(3Fh). Note that they can

be read in any order, just understand that the three bytes

represent a two's complement 24-bit word with the byte in

order, high, mid and low.

The offset calibration function in the A/D converter removes the

offset associated with the PGA (Programmable Gain Amplifier) in

a specific gain setting. There are eight gain settings (1x, 2x, 4x,

8x, 16x, 32x, 64x, and 128x) and there is an array of eight sets of

three byte registers which hold the high, middle, and low bytes of

a 24-bit calibration word. The word is stored in twos complement

format.

Write Offset Calibration Registers

Upon power-up the offset registers are initialized to zero. After an

offset calibration is performed the registers associated with that

selected PGA gain will contain a valid 24-bit two's complement

number.

When calibration is performed it is to correct the PGA offset and is

not actually associated with a given input channel. When a

calibration is executed, its result is based upon the results of the

converter performing a conversion with the input to the PGA shorted

internally to the chip. The conversion result will have an uncertainty

due to the peak-to-peak noise of the converter on the word rate in

which the calibration is performed. Lower word rates have lower

signal bandwidth and therefore will have less peak to peak variation

in the output result when a calibration is performed. Therefore, it

can improve calibration accuracy if the calibration is performed with

the lowest word rate acceptable to the user.

This number can be saved into non-volatile memory and then

written back to the PGA Offset Array register.

1. Write into the PGA Pointer register (BCh) the selection for the

Gain setting of the PGA for which offset data is to be written.

2. Write the three different PGA Offset Array registers, High byte

(BDh), Mid byte (BEh), and Low byte (BFh). Note that they can

be written in any order, just understand that the three bytes

represent a two's complement 24-bit word with the byte in

order, high, mid and low.

Perform a PGA Offset Calibration

1. Write to the Output Word Rate register (85h) and select a

word rate.

The value written will be subtracted from the conversion data before

it is output from the converter whenever that particular PGA Gain

setting is used. Offset values up to the equivalent of full scale of the

converter can be written but realize that this can consume dynamic

range for the actual signal if the offset value is set to a large

number.

2. Write to the Input Mux Selection register (87h) and select an

input channel (AIN1 to AIN4, not AVDD monitor or

Temperature Sensor). Note that the channel will actually be

shorted internally so it need not be a specific channel.

3. Write to the Channel Pointer register (88h) with the same

selection written into the Mux Selection register.

Example Command Sequence

Table 7 illustrates an example command sequence to set up the

ADC once power supplies are active. The sequence of commands,

Set Channel Pointer, Set PGA Gain Setting, Set Mux Selection, Set

Data Rate, and Start Continuous Conversions, can be written into

the ADC as a sequence, each framed with CS going low at the

beginning of each command and returning high at the end of the

associated data byte (the rising edge of CS is the signal that actually

writes the data byte to the control register). After continuous

conversions are started, it is best if a time delay occur before the

Perform Offset Calibration is issued. There is no specific amount of

delay time as this depends upon the gain selection and the accuracy

required. When the command to perform the offset calibration is

issued, the continuous conversions in progress will be paused and

the conversion sequence will be performed as necessary to perform

the calibration. Once the calibration is completed, continuous

conversions will be automatically restarted. Any subsequent

commands which write into registers [SDO/LSPS, Output Word

Rate, Input Mux Selection, PGA Gain, Delay Timer, PGA Offset Array,

or Offset Calibration] while continuous conversions are in

progress will reset the digital filter and introduce a delay

determined by Equation 1 on page 11, after which, the SDO/RDY

signal will toggle low to signal the availability of a conversion

word.

4. Write the PGA gain selection into the PGA Gain register (97h).

5. Write bits b1 and b0 of the Conversion Control Register (84h)

setting b1 to logic 1 and bit b2 to logic 0 to Perform

Continuous Conversions.

6. Allow some delay and then write bit b2 of the Conversion Control

Register (84h) to logic 1 to start the calibration process. The

calibration time will be a function of the selection made in the

Output Word Rate register. To determine when the calibration

cycle is completed the user has two options. One is to monitor

SDO/RDY for a falling edge as this signals the completion of

conversion. A second approach would be to introduce a wait

timer for at least the period of five conversion times at the word

rate selected. [Example: If the word rate is 10Sps the calibration

should be completed at 5x 1/10s or 500ms. After this time, the

microcontroller can poll bit 2 of the Conversion Control Register.

Bit b2 will be set back to logic 0 when the calibration has

completed. It is best not to pollthe register continuously because

the added activity on the serial port may introduce noise and

impact the calibration result.

Read Offset Calibration Registers

After an offset calibration has been performed, the calibration

result, which is a 24-bit (3 bytes) two's complement word, is stored

FN7608 Rev 0.00

October 12, 2012

Page 17 of 21

ISL26102, ISL26104

TABLE 7. EXAMPLE COMMAND SEQUENCE

ADDRESS

OPERATION

Set Channel Pointer

Set PGA Gain Setting

REGISTER

Channel Pointer

PGA Gain

(WRITE)

DATA

COMMENTS

88h

01h

Set to select channel 2 (AIN2+, AIN2-)

97h

06h

Sets PGA gain to 64x. This PGA gain is applied to the signal channel pointed

to by the Channel Pointer set above.

Set Mux Selection

Input Mux Selection

87h

00h

Mux selection determines which channel is connected to the ADC. This step

selects mux input 1 (AIN1+, AIN1-).

Set Data Rate

OWR

85h

84h

11h

02h

Sets output word rate to 1kSps. See Table 3 for other data rate options.

Start Continuous

Conversions

Conversion Control

Set bits (b1-b0) of the Conversion Control register to ‘10’ to start continuous

conversions.

Perform Offset

Calibration

Conversion Control

Input Mux Selection

84h

87h

04h

01h

Set bit (b2) of the Conversion Control register to 1 to initiate an offset

calibration of the PGA gain setting selected above. Note that bit (b3) will return

to 0 when the calibration is completed.

Set Mux Selection

Mux selection determines which channel is connected to the ADC. This step

selects mux input 2 (AIN2+, AIN2-).

FN7608 Rev 0.00

October 12, 2012

Page 18 of 21

ISL26102, ISL26104

Revision History

The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to web to make sure you

have the latest revision.

DATE

REVISION

FN7608.0

CHANGE

October 12, 2012

Initial release.

Products

Intersil Corporation is a leader in the design and manufacture of high-performance analog semiconductors. The Company's products

address some of the industry's fastest growing markets, such as, flat panel displays, cell phones, handheld products, and notebooks.

Intersil's product families address power management and analog signal processing functions. Go to www.intersil.com/products for a

complete list of Intersil product families.

For a complete listing of Applications, Related Documentation and Related Parts, please see the respective product information page.

Also, please check the product information page to ensure that you have the most updated datasheet: ISL26102, ISL26104

To report errors or suggestions for this datasheet, please go to www.intersil.com/askourstaff

FITs are available from our website at http://rel.intersil.com/reports/search.php

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

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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

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For information regarding Intersil Corporation and its products, see www.intersil.com

FN7608 Rev 0.00

October 12, 2012

Page 19 of 21

ISL26102, ISL26104

Package Outline Drawing

M24.173

24 LEAD THIN SHRINK SMALL OUTLINE PACKAGE (TSSOP)

Rev 1, 5/10

A

1

3

7.80 ±0.10

SEE DETAIL "X"

13

24

6.40

PIN #1

I.D. MARK

4.40 ±0.10

2

3

0.20 C B A

1

12

+0.05

-0.06

0.15

B

0.65

TOP VIEW

END VIEW

1.00 REF

H

-

0.05

C

+0.15

-0.10

0.90

1.20 MAX

GAUGE

PLANE

SEATING PLANE

0.10 C

0.25

+0.05

-0.06

C B A

0.25

0.10

5

0°-8°

0.60± 0.15

0.05 MIN

0.15 MAX

M

SIDE VIEW

DETAIL "X"

(1.45)

NOTES:

1. Dimension does not include mold flash, protrusions or gate burrs.

Mold flash, protrusions or gate burrs shall not exceed 0.15 per side.

2. Dimension does not include interlead flash or protrusion. Interlead

flash or protrusion shall not exceed 0.25 per side.

3. Dimensions are measured at datum plane H.

(5.65)

4. Dimensioning and tolerancing per ASME Y14.5M-1994.

5. Dimension does not include dambar protrusion. Allowable protrusion

shall be 0.08mm total in excess of dimension at maximum material

condition. Minimum space between protrusion and adjacent lead

is 0.07mm.

(0.65 TYP)

(0.35 TYP)

6. Dimension in ( ) are for reference only.

TYPICAL RECOMMENDED LAND PATTERN

7. Conforms to JEDEC MO-153.

FN7608 Rev 0.00

October 12, 2012

Page 20 of 21

ISL26102, ISL26104

Package Outline Drawing

M28.173

28 LEAD THIN SHRINK SMALL OUTLINE PACKAGE (TSSOP)

Rev 1, 5/10

A

1

3

9.70± 0.10

SEE DETAIL "X"

15

28

6.40

PIN #1

I.D. MARK

4.40 ± 0.10

2

3

0.20 C B A

1

14

+0.05

-0.06

0.15

B

0.65

TOP VIEW

END VIEW

1.00 REF

H

-

0.05

+0.15

-0.10

0.90

C

GAUGE

PLANE

1.20 MAX

0.25

SEATING PLANE

0.10 C

+0.05

-0.06

0.25

0.10

0°-8°

0.60 ±0.15

5

0.05 MIN

0.15 MAX

C B A

M

SIDE VIEW

DETAIL "X"

(1.45)

NOTES:

1. Dimension does not include mold flash, protrusions or gate burrs.

Mold flash, protrusions or gate burrs shall not exceed 0.15 per side.

2. Dimension does not include interlead flash or protrusion. Interlead

flash or protrusion shall not exceed 0.25 per side.

3. Dimensions are measured at datum plane H.

(5.65)

4. Dimensioning and tolerancing per ASME Y14.5M-1994.

5. Dimension does not include dambar protrusion. Allowable protrusion

shall be 0.08mm total in excess of dimension at maximum material

condition. Minimum space between protrusion and adjacent lead

is 0.07mm.

(0.35 TYP)

(0.65 TYP)

TYPICAL RECOMMENDED LAND PATTERN

6. Dimension in ( ) are for reference only.

7. Conforms to JEDEC MO-153.

FN7608 Rev 0.00

October 12, 2012

Page 21 of 21


型号：	ISL26104
厂家：	RENESAS TECHNOLOGY CORP
描述：	Low-Noise 24-bit Delta Sigma ADC
文件：	总21页 (文件大小：1221K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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