ALT35310A - 2-Power - Datasheet.Live

LTC1292/LTC1297

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FEATURES

DESCRIPTIO

KEY SPECIFICATIO S

TYPICAL APPLICATIO

Single Chip 12-Bit

Data Acquisition Systems

■

Resolution: 12 Bits

■

Fast Conversion Time: 12µs Max Over Temp

■

Low Supply Current: 6.0mA

■

Shutdown Supply Current: 5µA (LTC1297)

■

Single Supply 5V Operation

■

Power Shutdown After Each Conversion (LTC1297)

■

Built-In Sample-and-Hold

■

60kHz Maximum Throughput Rate (LTC1292)

■

Direct 3-Wire Interface to Most MPU Serial Ports and

All MPU Parallel Ports

■

Analog Inputs Common Mode to Supply Rails

The LTC

1292/LTC1297 are data acquisition systems that

contain a 12-bit, switched-capacitor successive approxi-

mation A/D, a differential input, sample-and-hold on the

(+) input, and serial I/O. When the LTC1297 is idle between

conversions it automatically powers down reducing the

supply current to 5µA, typically. The LTC1292 is capable

of digitizing signals at a 60kHz rate and with the device’s

excellent AC characteristics, it can be used for DSP appli-

cations. All these features are packaged in an 8-pin DIP

and are made possible using LTCMOS

switched-capaci-

tor technology.

The serial I/O is designed to communicate without external

hardware to most MPU serial ports and all MPU parallel

I/O ports allowing data to be transmitted over three wires.

Because of their accuracy, ease of use and small package

size these devices are well suited for digitizing analog

signals in remote applications where minimum number of

interconnects and power consumption are important.

12-Bit Differential Input Data Acquisition System

–

DIFFERENTIAL

INPUTS

COMMON MODE

RANGE

0V TO 5V

1N4148

REF

OUT

CLK

LTC1297

+IN

GND

–IN

LT1027

4.7µF

TANTALUM

8V TO 40V

1µF

22µF

TANTALUM

MC68HC11

SCK

MISO

*FOR OVERVOLTAGE PROTECTION LIMIT THE INPUT CURRENT TO 15mA

PER PIN OR CLAMP THE INPUTS TO V

AND GND WITH 1N4148 DIODES.

CONVERSION RESULTS ARE NOT VALID WHEN ANY INPUT IS OVERVOLTAGED

< GND OR V

> V

). SEE SECTION ON OVERVOLTAGE PROTECTION IN

THE APPLICATIONS INFORMATION.

LTC1292/7 TA01

SAMPLE

(Hz)

AVERAGE I

(µA)

100

1000

10000

1 100 10k

LTC1297• TA02

110 1k 100k

Power Supply Current

vs Sampling Frequency

, LTC and LT are registered trademarks of Linear Technology Corporation.

LTCMOS is trademark of Linear Technology Corporation

LTC1292/LTC1297

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PACKAGE/ORDER I FOR ATIO

ARBSOLUTEXI T

(Notes 1 and 2)

Supply Voltage (V

) to GND.................................. 12V

Voltage

Analog and Reference

Inputs..................................... –0.3V to V

+ 0.3V

Digital Inputs........................................ –0.3V to 12V

Digital Outputs .......................... –0.3V to V

+ 0.3V

Power Dissipation.............................................. 500mW

Operating Temperature Range

LTC1292/LTC1297BC, LTC1292/LTC1297CC,

LTC1292/LTC1297DC ............................ 0°C to 70°C

LTC1292BI, LTC1292CI,

LTC1292DI ......................................... –40°C to 85°C

Storage Temperature Range ................. –65°C to 150°C

Lead Temperature (Soldering, 10 sec.)................ 300°C

ORDER PART NUMBER

JMAX

= 150°C, θ

=100°C/W (J8)

CO VERTER A D ULTIPLEXER CHARACTERISTICS

UU W

N8 PACKAGE

8-LEAD PLASTIC DIP

TOP VIEW

+IN

–IN

GND

J8 PACKAGE

8-LEAD CERAMIC DIP

CLK

OUT

REF

PARAMETER CONDITIONS MIN TYP MAX MIN TYP MAX MIN TYP MAX UNITS

Offset Error (Note 4) ●±3.0 ±3.0 ±3.0 LSB

Linearity Error (INL) (Note 4 & 5) ●±0.5 ±0.5 ±0.75 LSB

Gain Error (Note 4) ●±0.5 ±1.0 ±4.0 LSB

Minimum Resolution for Which No 12 12 12 Bits

Missing Codes are Guaranteed

Analog and REF Input Range (Note 7) ● –0.05V to V

+ 0.05V V

On Channel Leakage Current On Channel = 5V ●±1±1±1µA

(Note 8) Off Channel = 0V

On Channel = 0V ●±1±1±1µA

Off Channel = 5V

Off Channel Lekage Current On Channel = 5V ●±1±1±1µA

(Note 8) Off Channel = 0V

On Channel = 0V ●±1±1±1µA

Off Channel = 5V

LTC1292C

LTC1297C

LTC1292B

LTC1297B LTC1292D

LTC1297D

LTC1292BIN8

LTC1292CIN8

LTC1292DIN8

LTC1292BCN8

LTC1292CCN8

LTC1292DCN8

Consult LTC Marketing for parts specified with wider operating temperature ranges.

JMAX

= 100°C, θ

=130°C/W (N8)

LTC1292BCJ8 LTC1297BCJ8

LTC1292CCJ8 LTC1297CCJ8

LTC1292DCJ8 LTC1297DCJ8

LTC1297BCN8

LTC1297CCN8

LTC1297DCN8

The ● denotes the specifications

which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 3)

OBSOLETE PACKAGE

Consider the N8 Package for Alternate Source

LTC1292/LTC1297

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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

CLK

Clock Frequency V

= 5V (Note 6) (Note 9) 1.0 MHz

SMPL

Analog Input Sample Time See Operating Sequence LTC1292 1.5CLK

LTC1297 0.5CLK+5.5µs

CONV

Conversion Time See Operating Sequence 12 CLK

Cycles

CYC

Total Cycle Time See Operating Sequence LTC1292 14CLK+2.5µs

(Note 6) LTC1297 14CLK+6µs

dDO

Delay Time, CLK↓ to D

OUT

Data Valid See Test Circuits ●160 300 ns

dis

Delay Time, CS↑ to D

OUT

Hi-Z See Test Circuits ●80 150 ns

Delay Time, CLK↓ to D

OUT

Enabled See Test Circuits ●80 200 ns

hDO

Time Output Data Remains Valid After CLK↓130 ns

OUT

Fall Time See Test Circuits ●65 130 ns

OUT

Rise Time See Test Circuits ●25 50 ns

WHCLK

CLK High Time V

= 5V (Note 6) 300 ns

WLCLK

CLK Low Time V

= 5V (Note 6) 400 ns

suCS

Setup Time, CS↓ Before CLK↑V

= 5V (Note 6) LTC1292 50 ns

(LTC1297 Wakeup Time) LTC1297 5.5 µs

WHCS

CS High Time Between Data Transfer Cycles V

= 5V (Note 6) LTC1292 2.5 µs

LTC1297 0.5 µs

WLCS

CS Low Time During Data Transfer V

= 5V (Note 6) LTC1292 14CLK

LTC1297 14CLK+5.5µs

Input Capacitance Analog Inputs On Channel 100 pF

Analog Inputs Off Channel 5 pF

Digital Inputs 5 pF

AC CHARACTERISTICS

LTC1292B/LTC1297B

LTC1292C/LTC1297C

LTC1292D/LTC1297D

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

High Level Input Voltage V

= 5.25V ●2.0 V

Low Level Input Voltage V

= 4.75V ●0.8 V

High Level Input Current V

= V

●2.5 µA

Low Level Input Current V

= 0V ●–2.5 µA

High Level Output Voltage V

= 4.75V, I

= –10µA 4.7 V

= 360µA●2.4 4.0 V

Low Level Output Voltage V

= 4.75V, I

= 1.6mA ●0.4 V

High Z Output Leakage V

OUT

= V

, CS High ●3µA

OUT

= 0V, CS High ●–3 µA

SOURCE

Output Source Current V

OUT

= 0V –20 mA

SINK

Output Sink Current V

OUT

= V

20 mA

LTC1292B/LTC1297B

LTC1292C/LTC1297C

LTC1292D/LTC1297D

DIGITAL A D DC ELECTRICAL CHARACTERISTICS

The ● denotes the specifications which

apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 3)

The ● denotes the specifications which apply over the full operating temperature range,

otherwise specifications are at TA = 25°C. (Note 3)

LTC1292/LTC1297

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LTC1292B/LTC1297B

LTC1292C/LTC1297C

LTC1292D/LTC1297D

SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS

Positive Supply Current CS High LTC1292 ●612 mA

CS Low LTC1297 ●612 mA

CS High Power Shutdown CLK Off LTC1297 ●510 µA

REF

Reference Current CS High ●10 50 µA

DIGITAL A D DC ELECTRICAL CHARACTERISTICS

CCHARA TERISTICS

ATYPICALPER

FORCE

AMBIENT TEMPERATURE (°C)

–50

SUPPLY CURRENT (mA)

30 70

LTC1292/7 G02

–30 –10 50 90 110

10 130

CLK = 1MHz

VCC = 5V

SUPPLY VOLTAGE (V)

SUPPLY CURRENT (mA)

LTC1292/7 G01

CLK = 1MHz

= 25°C

LTC1297 Supply Current (Power

Shutdown) vs Temperature

AMBIENT TEMPERATURE (°C)

–50

SUPPLY CURRENT (µA)

050 75

LTC1292/7 G03

–25 25 100 125

= 5V

REF

= 5V

CS HIGH

CLK OFF

Supply Current vs TemperatureSupply Current vs Supply Voltage

below GND or one diode drop above V

. Be careful during testing at low

levels (4.5V), as high level reference or analog inputs (5V) can cause

this input diode to conduct, especially at elevated temperatures, and cause

errors for inputs near full scale. This spec allows 50mV forward bias of

either diode. This means that as long as the reference or analog input does

not exceed the supply voltage by more than 50mV, the output code will be

correct. To achieve an absolute 0V to 5V input voltage range will therefore

require a minimum supply voltage of 4.950V over initial tolerance,

temperature variations and loading.

Note 8: Channel leakage current is measured after the channel selection.

Note 9: Increased leakage currents at elevated temperatures cause the

S/H to droop, therefore it is recommended that f

CLK

≥125kHz at 125°C,

CLK

≥ 31kHz at 85°C, and f

CLK

≥ 3kHz at 25°C.

Note 1: Absolute Maximum Ratings are those values beyond which the life

of a device may be impaired.

Note 2: All voltage values are with respect to ground (unless otherwise

noted).

Note 3: V

= 5V, V

REF

= 5V, CLK = 1.0MHz unless otherwise specified.

Note 4: One LSB is equal to V

REF

divided by 4096. For example, when

REF

= 5V, 1LSB = 5V/4096 = 1.22mV.

Note 5: Linearity error is specified between the actual end points of the

A/D transfer curve. The deviation is measured from the center of the

quantization band.

Note 6: Recommended operating conditions.

Note 7: Two on-chip diodes are tied to each reference and analog input

which will conduct for reference or analog input voltages one diode drop

The ● denotes the specifications which

apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 3)

LTC1292/LTC1297

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CCHARA TERISTICS

ATYPICALPER

FORCE

LTC1297 Supply Current (Power

Shutdown) vs CLK Frequency

REFERENCE VOLTAGE (V)

LINEARITY (LSB = 1/4096 × V

REF

)

0.75

1.00

1.25

LTC1292/7 G06

0.50

0.25

01235

= 5V

Change in Gain vs Temperature

* AS THE CLK FREQUENCY IS DECREASED FROM 1MHz, MINIMUM CLK FREQUENCY (∆ERROR ≤ 0.1LSB) REPRESENTS THE

FREQUENCY AT WHICH A 0.1LSB SHIFT IN ANY CODE TRANSITION FROM ITS 1MHz VALUE IS FIRST DETECTED (NOTE 9).

CLK FREQUENCY (kHz)

SUPPLY CURRENT (µA)

800

LTC1292/7 G04

0200 400 600 1000

= 5V

REF

= 5V

CS HIGH

CMOS LOGIC LEVELS

Change in Linearity vs

Reference Voltage

Unadjusted Offset Voltage vs

Reference Voltage

REFERENCE VOLTAGE (V)

0.5

0.6

LTC1292/7 G05

0.4

0.3

0.1 234

0.2

0.9

0.8

OFFSET (LSB = 1/4096 × V

REF

)

0.7

= 0.125mV

= 5V

= 0.250mV

Change in Gain vs

Reference Voltage Change in Offset vs Temperature

AMBIENT TEMPERATURE (°C)

–50

MAGNITUDE OF OFFSET CHANGE (LSB)

0.3

0.4

0.5

LTC1292/7 G08

0.2

0.1

0–25 025 75 125100

VCC = 5V

VREF = 5V

CLK = 1MHz

Change in Linearity vs

Temperature

AMBIENT TEMPERATURE (°C)

–50

MAGNITUDE OF LINEARITY CHANGE (LSB)

0.3

0.4

0.5

LTC1292/7 G09

0.2

0.1

0–25 025 75 125100

VCC = 5V

VREF = 5V

CLK = 1MHz

DOUT Delay Time vs Temperature

REFERENCE VOLTAGE (V)

–1.2

CHANGE IN GAIN (LSB = 1/4096 × VREF)

–1.0

–0.8

–0.6

–0.4

–0.2

1234

LTC1292/7 G07

VCC = 5V

AMBIENT TEMPERATURE (°C)

–50

MAGNITUDE OF GAIN CHANGE (LSB)

0.3

0.4

0.5

LTC1292/7 G10

0.2

0.1

0–25 025 75 125100

VCC = 5V

VREF = 5V

CLK = 1MHz

AMBIENT TEMPERATURE (°C)

–50

MINIMUM CLK FREQUENCY (MHz)

0.15

0.20

0.25

LTC1292/7 G11

0.10

0.05

–25 025 75 125100

VCC = 5V

Minimum Clock Rate for

0.1 LSB Error*

AMBIENT TEMPERATURE (°C)

–50

DOUT DELAY TIME FROM CLK↓ (ns)

150

200

250

LTC1292/7 G12

100

0–25 025 75 125100

VCC = 5V

MSB FIRST DATA

LSB FIRST DATA

LTC1292/LTC1297

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CCHARA TERISTICS

ATYPICALPER

FORCE

100

0.2

MAXIMUM CLK FREQUENCY* (MHz)

0.4

0.6

0.8

1.0

1k 10k 100k

LTC1292/7G13

VCC = 5V

VREF = 5V

CLK = 1MHz

RSOURCE– (Ω)

–

+IN

–IN

+VIN

RSOURCE

Maximum Filter Resistor vs

Cycle Time

PI FU CTIO S

* MAXIMUM CLK FREQUENCY REPRESENTS THE

CLK FREQUENCY AT WHICH A 0.1LSB SHIFT IN

THE ERROR AT ANY CODE TRANSITION FROM ITS

1MHz VALUE IS FIRST DETECTED.

** MAXIMUM R

FILTER

REPRESENTS THE FILTER

RESISTOR VALUE AT WHICH A 0.1LSB CHANGE IN

FULL SCALE ERROR FROM ITS VALUE AT

FILTER

= 0Ω IS FIRST DETECTED.

CYCLE TIME (µs)

MAXIMUM R

FILTER

** (Ω)

100

10k

10 1k 10k

LTC1292/7 G14

1100

–

FILTER

≥1µF

FILTER

Maximum Clock Rate vs

Source Resistance

SOURCE

+ (Ω)

100

S & H AQUISITION TIME TO 0.02% (µs)

100

1000 10000

LTC1292/7 G15

–

SOURCE

REF

= 5V

= 25°C

0V TO 5V INPUT STEP

Sample-and-Hold Acquisition

Time vs Source Resistance

Input Channel Leakage Current vs

Temperature

AMBIENT TEMPERATURE (°C)

–50

INPUT CHANNEL LEAKAGE CURRENT (nA)

100

300

400

500

1000

700

–10 30 50 130

LTC1292/7 G16

200

800

900

600

–30 10 70 90 110

ON CHANNEL

OFF CHANNEL

GUARANTEED

Noise Error vs Reference Voltage

REFERENCE VOLTAGE (V)

PEAK-TO-PEAK NOISE ERROR (LSB)

0.25

0.75

1.00

1.25

245

2.25

0.50

1.50

1.75

2.00

LTC1292/7 G17

LTC1292/LTC1297

NOISE = 200µV

P-P

CS (Pin 1): Chip Select Input. A logic low on this input

enables the LTC1292/LTC1297. Power shutdown is acti-

vated on the LTC1297 when CS is brought high.

+IN, –IN (Pin 2, 3): Analog Inputs. These inputs must be

free of noise with respect to GND.

GND (Pin 4): Analog Ground. GND should be tied directly

to an analog ground plane.

REF

(Pin 5): Reference Input. The reference input defines

the span of the A/D converter and must be kept free of

noise with respect to GND.

OUT

(Pin 6): Digital Data Output. The A/D conversion

result is shifted out of this output.

CLK (Pin 7): Shift Clock. This clock synchronizes the serial

data transfer.

(Pin 8):

Positive Supply. This supply must be kept free

of noise and ripple by bypassing directly to the analog

ground plane.

LTC1292/LTC1297

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Load Circuit for tdis and ten

Load Circuit for tdDO, tr and tf

On and Off Channel Leakage Current Voltage Waveforms for DOUT Delay Time, tdDO

IDAGRA

BLOCK

TEST CIRCUITS

Voltage Waveforms for DOUT Rise and Fall Times, tr, tf

Voltage Waveforms for tdis

INPUT

SHIFT

COMP

SAMPLE

AND

HOLD

12-BIT

CAPACITIVE

DAC

OUTPUT

SHIFT

12-BIT

SAR

CONTROL

AND

TIMING

ANALOG

INPUT MUX

REF

GND

–IN

+IN

OUT

CLK

LTC1292/7 BD

DOUT

1.4V

3kΩ

100pF

TEST POINT

LTC1292/7 TC03

OUT

100pF

TEST POINT

5V t

dis

WAVEFORM 2, t

dis

WAVEFORM 1

LTC1292/7 TC02

OFF

POLARITY

OFF CHANNEL

ON CHANNEL

LTC1292/7 TC01

CLK

OUT

0.8V

dDO

0.4V

2.4V

LTC1292/7 TC04

OUT

0.4V

2.4V

LTC1292/7 TC05

OUT

WAVEFORM 1

(SEE NOTE 1)

2.0V

dis

90%

10%

OUT

WAVEFORM 2

(SEE NOTE 2)

NOTE 1: WAVEFORM 1 IS FOR AN OUTPUT WITH INTERNAL CONDITIONS SUCH

THAT THE OUTPUT IS HIGH UNLESS DISABLED BY THE OUTPUT CONTROL.

NOTE 2: WAVEFORM 2 IS FOR AN OUTPUT WITH INTERNAL CONDITIONS SUCH

THAT THE OUTPUT IS LOW UNLESS DISABLED BY THE OUTPUT CONTROL.

LTC1292/7 TC06

LTC1292/LTC1297

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TEST CIRCUITS

Voltage Waveforms for ten

The LTC1292/LTC1297 are data acquisition components

which contain the following functional blocks:

1. 12-Bit Succesive Approximation Capacitive A/D

Converter

2. Differential Input

3. Sample-and-Hold (S/H)

4. Synchronous, Half-Duplex Serial Interface

5. Control and Timing Logic

DIGITAL CONSIDERATIONS

Serial Interface

The LTC1292/LTC1297 communicate with microproces-

sors and other external circuitry via a synchronous, half-

duplex, three-wire serial interface (see Operating Se-

quence). The clock (CLK) synchronizes the data transfer

with each bit being transmitted on the falling CLK edge.

The LTC1292/LTC1297 do not require a configuration

input word and have no D

pin. They are permanently

configured to have a single differential input and to per-

form a unipolar conversion. A falling CS initiates data

transfer. To allow the LTC1297 to recover from the power

shutdown mode, t

suCS

has to be met. Then the first CLK

pulse enables D

OUT

. After one null bit, the A/D conversion

result is output on the D

OUT

line with a MSB-first sequence

followed by a LSB-first sequence. With the half-duplex

serial interface the D

OUT

data is from the current conver-

sion. This provides easy interface to MSB-first or LSB-first

PPLICATI

I FOR ATIO

serial ports. Bringing CS high resets the LTC1292/LTC1297

for the next data exchange and puts the LTC1297 into its

power shutdown mode.

Table 1. Microprocessor with Hardware Serial Interfaces

Compatible with the LTC1292/LTC1297**

OUT

0.8V

B11

CLK

LTC1292/7 TC07

PART NUMBER TYPE OF INTERFACE

Motorola

MC6805S2, S3 SPI

MC68HC11 SPI

MC68HC05 SPI

RCA CDP68HC05 SPI

HitachiHD6305 SCI Synchronous

HD6301 SCI Synchronous

HD63701 SCI Synchronous

HD6303 SCI Synchronous

HD64180 SCI Synchronous

National Semiconductor

COP400 Family MICROWIRE

†

COP800 Family MCROWIRE/PLUS

†

NS8050U MICROWIRE/PLUS

HPC16000 Family MICROWIRE/PLUS

Texas Instruments

TMS7002 Serial Port

TMS7042 Serial Port

TMS70C02 Serial Port

TMS70C42 Serial Port

TMS32011* Serial Port

TMS32020* Serial Port

TMS370C050 SPI

* Requires external hardware

** Contact factory for interface information for processors not on this list

†

MICROWIRE and MICROWIRE/PLUS are trademarks of National

Semiconductor Corp.

LTC1292/LTC1297

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LTC1292 Operating Sequence

PPLICATI

I FOR ATIO

Motorola SPI (MC68HC11)

The MC68HC11 has been chosen as an example of an MPU

with a dedicated serial port. This MPU transfers data MSB

first and in 8-bit increments. A dummy D

word sent to the

data register starts the SPI process. With two 8-bit transfers,

the A/D result is read into the MPU (Figure 1). For the

LTC1292 the first 8-bit transfer clocks B11 through B8 of

the A/D conversion result into the processor. The second

8-bit transfer clocks the remaining bits B7 through B0 into

Microprocessor Interfaces

The LTC1292/LTC1297 can interface directly (without

external hardware) to most popular microprocessors’

(MPU) synchronous serial formats (see Table 1). If an

MPU without a dedicated serial port is used, then three of

the MPU’s parallel port lines can be programmed to form

the serial link to the LTC1292/LTC1297. Included here are

one serial interface example and one example showing a

parallel port programmed to form the serial interface.

Figure 1. Data Exchange Between LTC1292 and MC68HC11

CLK

tCYC

B11 B10B9B8

B5B4

B0B1B2

B5B6

B9B10 B11

tCONV

DOUT

Hi-Z

tSMPL tSMPL

LTC1292/7 AI01

LTC1297 Operating Sequence

CLK

OUT

MPU

RECEIVED WORD

LTC1292/7 F01

B7 B6 B5 B4 B3 B2 B1 B0 B1

B10

B11

BYTE 2

B10 B9 B8B11

1ST TRANSFER 2ND TRANSFER

BYTE 1

B2 B1 B0

B3B4

B7 B5

CLK

CYC

B11 B10B9B8

B5B4

B0B1B2

B5B6

B9B10 B11

CONV

OUT

Hi-Z

SMPL

LTC1292/7 AI02

suCS

POWER SHUTDOWN MODE

LTC1292/LTC1297

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the MPU. The data is right-justified in the two memory

locations (Figure 2). This was made possible by delaying

the falling edge of CS till after the second CLK. ANDing the

first byte with 0F

HEX

clears the four most significant bits.

This operation was not included in the code. It can be

inserted in the data gathering loop or outside the loop

when the data is processed.

PPLICATI

I FOR ATIO

LABEL MNEMONIC OPERAND COMMENTS

LDAA #$50 CONFIGURATION DATA FOR SPCR

STAA $1028 LOAD DATA INTO SPCR ($1028)

LDAA #$1B CONFIG. DATA FOR PORT D DDR

STAA $1009 LOAD DATA INTO PORT D DDR

LDAA #$00 LOAD DUMMY DIN WORD INTO

ACC A

STAA $50 LOAD DUMMY DIN DATA INTO $50

LOOP LDX #$1000 LOAD INDEX REGISTER X WITH

$1000

LDAB #$00 LOAD ACC B WITH $00

LDAA $50 LOAD DUMMY DIN INTO ACC A

FROM $50

STAA $102A LOAD DUMMY DIN INTO SPI,

START SCK

NOP DELAY CS FALL TIME TO RIGHT

JUSTIFY DATA

MC68HC11 CODE for LTC1292 Interface

STAB $08, X D0 GOES LOW (CS GOES LOW)

NOP 6 NOPS FOR TIMING

LDAA $1029 CHECK SPI STATUS REG

LDAA $102A LOAD LTC1292 MSBs INTO ACC A

STAA $61 STORE MSBs IN $61

STAA $102A LOAD DUMMY DIN INTO SPI,

START SCK

NOPS 6 NOPS FOR TIMING

BSET $08,X,$01 D0 GOES HIGH (CS GOES HIGH)

LDAA $1029 CHECK SPI STATUS REGISTER

LDAA $102A LOAD LTC1292 LSBs IN ACC

STAA $62 STORE LSBs IN $62

JMP LOOP START NEXT CONVERSION

LABEL MNEMONIC OPERAND COMMENTS

BYTE 2

B3B7 B6 B5 B4 B2 B0

B10 B9 B8B11

OO BYTE 1

OUT

FROM LTC1292 STORED ON MC68HC11 RAM

LOCATION #61

LOCATION #62

MSB

LTC1292/7 F02

CLK

OUT

LTC1292

ANALOG

INPUTS

SCK

MISO

MC68HC11

Figure 2. Hardware and Software Interface to Motorola MC68HC11 Microcontroller

Figure 3. Data Exchange Between LTC1297 and MC68HC11

For the LTC1297 (Figure 3) a delay must be introduced to

accommodate the setup time, t

suCS

, before the dummy

word is sent to the data register. The first 8-bit transfer

clocks B11 through B6 of the A/D conversion result into

the processor. The second 8-bit transfer clocks the re-

maining bits B5 through B0 into the MPU. Note B1 and B2

from the LSB-first data word have also been clocked in.

CLK

OUT

MPU

RECEIVED WORD

LTC1292/7 F03

B7 B6 B5 B4 B3 B2 B1 B0 B1

B10

B11

BYTE 2

B8 B7 B6B9

B10

?B11

1ST TRANSFER 2ND TRANSFER

BYTE 1

B0 B1 B2

B1B2

B5 B3

B2 B3

LTC1292/LTC1297

12927fb

on two port lines and the D

OUT

signal is read on a third port

line. After a falling CLK edge each data bit is loaded into the

carry bit and then rotated into the accumulator. Once the

first 8 MSBs have been shifted into the accumulator they

are loaded into register R2. The last four bits are shifted in

the same way and loaded into register R3. The output data

is left-justified in registers R2 and R3 (Figure 5).

For the LTC1297 four NOPs need to be inserted in the 8051

code after CS goes low to allow the LTC1297 to wake up

from power shutdown (t

suCS

PPLICATI

I FOR ATIO

LABEL MNEMONIC OPERAND COMMENTS

LDAA #$50 CONFIGURATION DATA FOR SPCR

STAA $1028 LOAD DATA INTO SPCR ($1028)

LDAA #$1B CONFIG. DATA FOR PORT D DDR

STAA $1009 LOAD DATA INTO PORT D DDR

LDAA #$00 LOAD DUMMY DIN WORD INTO

ACC A

STAA $50 LOAD DUMMY DIN DATA INTO $0

LOOP LDX #$1000 LOAD INDEX REGISTER X WITH

$1000

LDAB #$00 LOAD ACC B WITH $00

LDAA $50 LOAD DIN INTO ACC FROM $50

BCLR $08,X,$01 D0 GOES LOW (CS GOES LOW)

NOP 3 NOP FOR t

suCS

TIMING

NOP

STAA $102A LOAD DUMMY DIN INTO SPI,

START CLK

LABEL MNEMONIC OPERAND COMMENTS

MC68HC11 CODE for LTC1297 Interface

LOOP1 LDAA $1029 CHECK SPI STATUS REG

BPL LOOP1 CHECK IF TRANSFER IS DONE

LDAA $102A LOAD LTC1297 MSBs INTO ACC A

STAA $61 STORE MSBs IN $61

STAA $102A LOAD DUMMY DIN INTO SPI,

START SCK

LOOP2 LDAA $1029 CHECK SPI STATUS RES

BPL LOOP2 CHECK IF TRANSFER IS DONE

BSET $08X,$01 D0 GOES HIGH (CS GOES HIGH)

LDAA $102A LOAD LTC1297 LSBs INTO ACC A

STAA $62 STORE LSBs IN $62

ROR $61 ROTATE RIGHT WITH CARRY

ROR $62 NEEDED TO RIGHT JUSTIFY

ROR $61 THE DATA IN $61 AND $62

ROR $62

JMP LOOP START NEXT CONVERSION

BYTE 2

B3B7 B6 B5 B4 B2 B0

B10 B9 B8B11

OO BYTE 1

OUT

FROM LTC1297 STORED ON MC68HC11 RAM

LOCATION #61

LOCATION #62

MSB

LTC1292/7 F04

CLK

OUT

LTC1297

ANALOG

INPUTS

SCK

MISO

MC68HC11

Figure 4. Hardware and Software Interface to Motorola MC68HC11 Microcontroller

The data is right- justified in the two memory locations by

rotating right twice (Figure 4). ANDing the first byte with

HEX

clears the four most significant bits. This operation

was not included in the code. It can be inserted in the data

gathering loop or outside the loop when the data is

processed.

Interfacing to the Parallel Port of the Intel 8051 Family

The Intel 8051 has been chosen to show the interface

between the LTC1292/LTC1297 and parallel port

microprocessors. The signals CS and CLK are generated

LTC1292/LTC1297

12927fb

PPLICATI

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Figure 5. Hardware and Software Interface to Intel 8051 Processor

LABEL MNEMONIC OPERAND COMMENTS

MOV P1,#02h BIT 1 PORT 1 SET AS INPUT

CLR P1.3 CLK GOES LOW

SETB P1.4 CS GOES HIGH

CONT CLR P1.4 CS GOES LO

NOP 4 NOP FOR LTC1297 t

suCS

(Wakeup

NOP Time) (Not Needed for LTC1292)

NOP

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

MOV R4,#08H LOAD COUNTER

LOOP MOV C,P1.1 READ DATA BIT INTO CARRY

RLC A ROTATE DATA BIT INTO ACC

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

DJNZ R4,LOOP NEXT BIT

MOV R2,A STORE MSBs IN R2

MOV C,P1.1 READ DATA BIT INTO CARRY

CLR A CLEAR ACC

RLC A ROTATE DATA BIT (B3) INTO ACC

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

MOV C,P1.1 READ DATA BIT INTO CARRY

RLC A ROTATE DATA BIT (B2) INTO ACC

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

MOV C,P1.1 READ DATA BIT INTO CARRY

RLC A ROTATE DATA BIT (B1) INTO ACC

SETB P1.3 CLK GOES HIGH

CLR P1.3 CLK GOES LOW

MOV C,P1.1 READ DATA BIT INTO CARRY

SETB P1.4 CS GOES HIGH

RRC A ROTATE DATA BIT (B0) INTO ACC

RRC A ROTATE RIGHT INTO ACC

MOV R3,A STORE LSBs IN R3

AJMP CONT START NEXT CONVERSION

LABEL MNEMONIC OPERAND COMMENTS

8051 CODE

Sharing the Serial Interface

The LTC1292/LTC1297 can share the same two-wire

serial interface with other peripheral components or other

LTC1292/LTC1297s (Figure 6). In this case, the CS signals

decide which LTC1292 is being addressed by the MPU.

ANALOG CONSIDERATIONS

Grounding

The LTC1292/LTC1297 should be used with an analog

ground plane and single point grounding techniques. Do

not use wire wrapping techniques to breadboard and

evaluate the device. To achieve the optimum performance

DOUT FROM LTC1292/LTC1297 STORED IN 8051 RAM

B3 B2 B0

B1 OO

B7 B6 B5 B4

B10 B9 B8B11

MSB

ANALOG

INPUTS CLK

DOUT

LTC1292

LTC1297 CS P1.4

P1.3

P1.1

8051

LTC1292/7 F05

DOUT B11 B7

B10 B4

B5B6 B3 B2 B1 B0

CLK

LTC1292/LTC1297

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PPLICATI

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Figure 6. Several LTC1292/LTC1297s Sharing One 2-Wire Serial Interface

LTC1292

LTC1297

CS CS

2-WIRE SERIAL

INTERFACE TO OTHER

PERIPHERALS OR

LTC1292/LTC1297s

210

OUTPUT PORT

SERIAL DATA

MPU LTC1292

LTC1297 LTC1292

LTC1297

LTC1292/7 F06

+–+–+–

Figure 7. Example Ground Plane

for the LTC1292/LTC1297

22µF

TANTALUM

LTC1292/7 F07

LTC1292

LTC1297

0.1µF

HORIZONTAL: 10µs/DIV

minimum and the V

supply should have a low output

impedance such as obtained from a voltage regulator

(e.g., LT323A). For high frequency bypassing a 0.1µF

ceramic disk placed in parallel with the 22µF is

recommended. Again the leads should be kept to a

minimum. Figures 8 and 9 show the effects of good and

poor V

bypassing.

Analog Inputs

Because of the capacitive redistribution A/D conversion

techniques used, the analog inputs of the LTC1292/

LTC1297 have capacitive switching input current spikes.

These current spikes settle quickly and do not cause a

problem. If large source resistances are used or if slow

settling op amps drive the inputs, take care to insure that

the transients caused by the current spikes settle completely

before the conversion begins.

use a PC board. The ground pin (Pin 4) should be tied

directly to the ground plane with minimum lead length (a

low profile socket is fine). Figure 7 shows an example of

an ideal LTC1292/LTC1297 ground plane design for a two-

sided board. Of course this much ground plane will not

always be possible, but users should strive to get as close

to this ideal as possible.

Bypassing

For good performance, V

must be free of noise and

ripple. Any changes in the V

voltage with respect to

ground during a conversion cycle can induce errors or

noise in the output code. V

noise and ripple can be kept

below 0.5mV by bypassing the V

pin directly to the

analog ground plane with a minimum of 22µF tantalum

capacitor and with leads as short as possible. The lead

from the device to the V

supply also should be kept to a

HORIZONTAL: 10µs/DIV

Figure 8. Poor VCC Bypassing. Noise and

Ripple Can Cause A/D Errors Figure 9. Good VCC Bypassing Keeps

Noise and Ripple on VCC Below 1mV

VERTICAL: 0.5mV/DIV

LTC1292/LTC1297

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PPLICATI

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Source Resistance

The analog inputs of the LTC1292/LTC1297 look like a

100pF capacitor (C

) in series with a 500Ω resistor (R

)

(Figures 10a and 10b). C

gets switched between (+) and

(–) inputs once during each conversion cycle. Large

external source resistors and capacitances will slow the

settling of the inputs. It is important that the overall RC

time constant is short enough to allow the analog inputs to

settle completely within the allowed time.

“+” Input Settling

The input capacitor for the LTC1292 is switched onto the

“+” input during the sample phase (t

SMPL

, see Figures 11a,

11b and 11c). The sample period can be as short as t

WHCS

+ 1/2 CLK cycle or as long as t

WHCS

+ 1 1/2 CLK cycles

before a conversion starts. This variability depends on

where CS falls relative to CLK. The voltage on the “+” input

must settle completely within the sample period. Minimizing

SOURCE

+ and C1 will improve the settling time. If large “+”

input source resistance must be used, the sample time can

be increased by using a slower CLK frequency. With the

minimum possible sample time of 3.0µs, R

SOURCE

+ < 2.0k

and C1 < 20pF will provide adequate settling time.

The sample period for the LTC1297 starts on the falling

edge of CS and ends on the falling edge of the first CLK

Figure 11a. Setup Time (tsuCS) Is Met for the LTC1292

“+” and “–” Input Settling Windows

(Figure 12). The length of the sample period is t

suCS

+0.5

CLK cycles. Again, the voltage on the “+” input must settle

completely within the sample period. If large “+” input

source resistance must be used, the sample time can be

increased by using a slower CLK frequency or by increasing

Figure 10a. Analog Input Equivalent Circuit for the LTC1292

Figure 10b. Analog Input Equivalent Circuit for the LTC1297

CS↑RON

500Ω

tWHCS

+ 0.5 CLK

CIN

100pF

LTC1292

“+”

INPUT

RSOURCE +

VIN +

“–”

INPUT

RSOURCE –

VIN –

LTC1292/7 F10a

CS↓R

500Ω

suCS

+ 0.5 CLK

100pF

LTC1297

“+”

INPUT

SOURCE

“–”

INPUT

SOURCE

–

LTC1292/7 F10b

OUT

CLK

B11

HI-Z B9

B10

LTC1292/7 F11a

1ST BIT TEST (–) INPUT MUST

SETTLE DURING THIS TIME

SUCS

WHCS

SMPL

(+) INPUT MUST SETTLE DURING THIS TIME

(+) INPUT

(–) INPUT

LTC1292/LTC1297

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PPLICATI

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Figure 11b. Setup Time (tsuCS) Is Met for the LTC1292

Figure 11c. Setup Time (tsuCS) Is Not Met for the LTC1292

suCS

. With the minimum possible sample time of 6µs,

SOURCE

+ < 5k and C1 < 20pF will provide adequate

settling time. In general for both the LTC1292 and LTC1297

keep the product of the total resistance and the total

capacitance less than t

SMPL

/9. If this condition can not be

met, then make C1 > 0.47µF (see RC Input Filtering

section).

“–” Input Settling

At the end of the sample phase the input capacitor switches

to the “–” input and the conversion starts (see Figures 11a,

11b, 11c and 12). During the conversion, the “+” input

voltage is effectively “held” by the sample-and-hold and

will not affect the conversion result. It is critical that the

OUT

CLK

B11

HI-Z B9

B10

LTC1292/7 F11b

1ST BIT TEST (–) INPUT MUST

SETTLE DURING THIS TIME

WHCS

SMPL

(+) INPUT MUST SETTLE DURING THIS TIME

(+) INPUT

(–) INPUT

OUT

CLK

B11

HI-Z B10

LTC1292/7 F11c

1ST BIT TEST (–) INPUT MUST

SETTLE DURING THIS TIME

WHCS

SMPL

(+) INPUT MUST SETTLE DURING THIS TIME

(+) INPUT

(–) INPUT

LTC1292/LTC1297

12927fb

Figure 12. “+” and “–” Input Settling Windows for the LTC1297

“–” input voltage be free of noise and settle completely

during the first CLK cycle of the conversion. Minimizing

SOURCE

– and C2 will improve settling time. If large “–”

input source resistance must be used the time can be

extended by using a slower CLK frequency. At the maximum

CLK frequency of 1MHz, R

SOURCE

– < 250

Ω

and C2 < 20pF

will provide adequate settling.

Input Op Amps

When driving the analog inputs with an op amp it is

important that the op amp settles within the allowed time

(see Figures 11a, 11b, 11c and 12). Again the “+” and “–

” input sampling times can be extended as described

above to accommodate slower op amps. Most op amps

including the LT1797 and LT1677 single supply op amps

can be made to settle well even with the minimum settling

windows of 3.0µs for the LTC1292 or 6.0µs for the

LTC1297 (“+” input) and 1µs (“–” input) that occurs at the

maximum clock rate of 1MHz. Figures 13 and 14 show

examples of both adequate and poor op amp settling.

VERTICAL: 5mV/DIV

HORIZONTAL: 500ns/DIV

HORIZONTAL: 20µs/DIV

Figure 13. Adequate Settling of Op Amp Driving Analog Input

VERTICAL: 5mV/DIV

Figure 14. Poor Op Amp Settling Can Cause A/D Errors

PPLICATI

I FOR ATIO

DOUT

CLK

B11

HI-Z B10

LTC1292/7 F12

1ST BIT TEST (–) INPUT MUST

SETTLE DURING THIS TIME

tWHCS

tSMPL

(+) INPUT MUST SETTLE

DURING THIS TIME

(+) INPUT

(–) INPUT

tsuCS

LTC1292/LTC1297

12927fb

RC Input Filtering

It is possible to filter the inputs with an RC network as

shown in Figure 15. For large values of C

(e.g., 1µF) the

capacitive input switching currents are averaged into a net

DC current. A filter should be chosen with a small resistor

and large capacitor to prevent DC drops across the resistor.

The magnitude of the DC current is approximately I

100pF × V

CYC

and is roughly proportional to V

. When

running the LTC1292(LTC1297) at the minimum cycle

time of 16.5µs (20µs), the input current equals 30µA

(25µA) at V

= 5V. Here a filter resistor of 4Ω (5Ω) will

cause 0.1LSB of full scale error. If a large filter resistor

must be used, errors can be reduced by increasing the

cycle time as shown in the typical performance

characteristics curve Maximum Filter Resistor vs Cycle

Time.

Figure 15. RC Input Filtering

curve of S&H Acquisition Time vs Source Resistance). The

input voltage is sampled during the t

SMPL

time as shown

in Figure 11. The sampling interval begins at the rising

edge of CS for the LTC1292, and at the falling edge of CS

for the LTC1297, and continues until the falling edge of the

CLK before the conversion begins. On this falling edge the

S&H goes into the hold mode and the conversion begins.

Differential Input

With a differential input the A/D no longer converts a single

voltage but converts the difference between two voltages.

The voltage on the +IN pin is sampled and held and can be

rapidly time-varying as in single-ended mode. The voltage

on the –IN pin must remain constant and be free of noise

and ripple throughout the conversion time. Otherwise the

differencing operation will not be done accurately. The

conversion time is 12 CLK cycles. Therefore a change in

the –IN input voltage during this interval can cause

conversion errors. For a sinusoidal voltage on the –IN

input this error would be:

VfV

ERROR MAX IN PEAK CLK

( ) (– )

()











212

Where f

(–IN)

is the frequency of the –IN input voltage,

PEAK

is its peak amplitude and f

CLK

is the frequency of the

CLK. Usually V

ERROR

will not be significant. For a 60Hz

signal on the –IN input to generate a 0.25LSB error

(300µV) with the converter running at CLK = 1MHz, its

peak value would have to be 66mV. Rearranging the above

equation the maximum sinusoidal signal that can be

digitized to a given accuracy is given as:

IN MAX ERROR MAX

PEAK

CLK

(– ) ()

=π



















212

For 0.25LSB error (300µV) the maximum input sinusoid

with a 5V peak amplitude that can be digitized is 0.8Hz.

Reference Input

The voltage on the reference input of the LTC1292/

LTC1297 determine the voltage span of the A/D con-

verter. The reference input has transient capacitive

Input Leakage Current

Input leakage currents also can create errors if the source

resistance gets too large. For example, the maximum input

leakage specification of 1µA flowing through a source

resistance of 1k will cause a voltage drop of 1mV or

0.8LSB. This error will be much reduced at lower

temperatures because leakage drops rapidly (see typical

performance characteristics curve Input Channel Leakage

Current vs Temperature).

SAMPLE-AND-HOLD

Single-Ended Input

The LTC1292/LTC1297 provide a built-in sample-and-

hold (S&H) function on the +IN input for signals acquired

in the single-ended mode (–IN pin grounded). The sample-

and-hold allows the LTC1292/LTC1297 to convert rapidly

varying signals (see typical performance characteristics

FILTER

LTC1292/7 F15

LTC1292

LTC1297

“+”

“–”

PPLICATI

I FOR ATIO

LTC1292/LTC1297

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PPLICATI

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Figures 17 and 18 show examples of both adequate and

poor settling. Using a slower CLK will allow more time

for the reference to settle. Even at the maximum CLK

rate of 1MHz most references and op amps can be

made to settle within the 1µs bit time. For example the

LT1790 will settle adequately.

Reduced Reference Operation

The effective resolution of the LTC1292/LTC1297 can

be increased by reducing the input span of the con-

verter. The LTC1292/LTC1297 exhibit good linearity

over a range of reference voltages (see typical perfor-

mance characteristics curves of Change in Linearity vs

Reference Voltage). Care must be taken when operat-

ing at low values of VREF because of the reduced LSB

step size and the resulting higher accuracy requirement

placed on the converter. Offset and noise are factors

that must be considered when operating at low VREF

values. The internal reference for VREF has been tied to

the GND pin. Any voltage drop from the GND pin to the

ground plane will cause a gain error.

Offset with Reduced VREF

The offset of the LTC1292/LTC1297 has a larger effect

on the output code when the A/D is operated with a

reduced reference voltage. The offset (which is typi-

cally a fixed voltage) becomes a larger fraction of an

LSB as the size of the LSB is reduced. The typical

performance characteristics curve of Unadjusted Off-

set Error vs Reference Voltage shows how offset in

LSBs is related to reference voltage for a typical value

of VOS. For example a VOS of 0.1mV, which is 0.1LSB

with a 5V reference becomes 0.4LSB with a 1.25V

reference. If this offset is unacceptable, it can be

corrected digitally by the receiving system or by offset-

ting the –IN input to the LTC1292/LTC1297.

Noise with Reduced VREF

The total input referred noise of the LTC1292/LTC1297

can be reduced to approximately 200µVP-P using a

ground plane, good bypassing, good layout techniques

and minimizing noise on the reference inputs. This

noise is insignificant with a 5V reference input but will

become a larger fraction of an LSB as the size of the LSB

switching currents due to the switched-capacitor con-

version technique (see Figure 16). During each bit test

of the conversion (every CLK cycle) a capacitive current

spike will be generated on the reference pin by the A/D.

These current spikes settle quickly and do not cause a

problem. If slow settling circuitry is used to drive the

reference input, take care to insure that transients

caused by these current spikes settle completely during

each bit test of the conversion.

8pF TO 40pF

LTC1292

LTC1297

REF

OUT

REF

EVERY

CLK CYCLE

REF

–

LTC1292/7 F16

Figure 16. Reference Input Equivalent Circuit

HORIZONTAL: 1µs/DIV

Figure 17. Adequate Reference Settling (LT1027)

HORIZONTAL: 10µs/DIV

Figure 18. Poor Reference Settling Can Cause A/D Errors

VERTICAL: 0.5mV/DIV

LTC1292/LTC1297

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is reduced. The typical performance characteristics

curve of Noise Error vs Reference Voltage shows the

LSB contribution of this 200µV of noise.

For operation with a 5V reference, the 200µV noise is

only 0.16LSB peak-to-peak. Here the LTC1292/LTC1297

noise will contribute virtually no uncertainty to the

output code. For reduced references, the noise may

become a significant fraction of an LSB and cause

undesirable jitter in the output code. For example, with

a 1.25V reference, this 200µV noise is 0.64LSB peak-

to-peak. This will reduce the range of input voltages

over which a stable output code can be achieved by

0.64LSB. Now, averaging readings may be necessary.

This noise data was taken in a very clean test fixture.

Any setup induced noise (noise or ripple on VCC, VREF

or VIN) will add to the internal noise. The lower the

reference voltage used, the more critical it becomes to

have a noise-free setup.

Gain Error Due to Reduced VREF

The gain error of the LTC1292/LTC1297 is very good

over a wide range of reference voltages. The error

component that is seen in the typical performance

characteristics curve Change in Gain Error vs Refer-

ence Voltage is due to the voltage drop on the GND pin

from the device to the ground plane. To minimize this

error the LTC1292/LTC1297 should be soldered di-

rectly onto the PC board. The internal reference point

for VREF is tied to GND. Any voltage drop in the GND pin

will make the reference voltage, internal to the device,

less than what is applied externally (Figure 19). This

drop is typically 420µV due to the product of the pin

resistance (RPIN) and the LTC1292/LTC1297 supply

PPLICATI

I FOR ATIO

This is the effective number of bits (ENOB). For the

example shown in Figures 20a and 20b, N = 11.8 bits

and 9.9 bits, respectively. Figure 21 shows a plot of

ENOB as a function of input frequency. The 2nd har-

monic distortion term accounts for the degradation of

the ENOB as fIN approaches fS/2.

Figure 22 shows an FFT plot of the output spectrum for

two tones applied to the input of the A/D. Nonlinearities

in the A/D will cause distortion products at the sum and

difference frequencies of the fundamentals and prod-

ucts of the fundamentals. This is classically referred to

as intermodulation distortion (IMD).

LTC1292

LTC1297

REF+

DAC

REF– V

REF

GND

LTC1292/7 F19

REFERENCE

VOLTAGE

current. For example, with VREF = 1.25V this will result

in a gain error change of –1.0LSB from the gain error

measured with VREF = 5V.

LTC1292 AC Characteristics

Two commonly used figures of merit for specifying the

dynamic performance of the A/Ds in digital signal

processing applications are the Signal-to-Noise Ratio

(SNR) and the “Effective Number of Bits (ENOB).” SNR

is the ratio of the RMS magnitude of the fundamental to

the RMS magnitude of all the non-fundamental signals

up to the Nyquist frequency (half the sampling fre-

quency). The theoretical maximum SNR for a sine wave

input is given by:

SNR = (6.02N + 1.76dB)

where N is the number of bits. Thus the SNR depends

on the resolution of the A/D. For an ideal 12-bit A/D the

SNR is equal to 74dB. Fast Fourier Transform (FFT)

plots of the output spectrum of the LTC1292 are shown

in Figures 20a and 20b. The input (fIN) frequencies are

1kHz and 28kHz with the sampling frequency (fS) at

58.8 kHz. The SNRs obtained from the plots are 73.0dB

and 61.5dB.

By rewriting the SNR expression it is possible to obtain

the equivalent resolution based on the SNR measure-

ment.

NSNR dB

=









–.

176

602

Figure 19. Parasitic Resistance in GND Pin

LTC1292/LTC1297

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Figure 20a. fIN = 1kHz, fS = 58.8kHz, SNR = 73.0dB

Figure 20b. fIN = 28kHz, fS = 58.8kHz, SNR = 61.5dB

Figure 21. LTC1292 ENOB vs Input Frequency

Figure 22. fIN1 = 5.1kHz, fIN2 = 5.6kHz, fS = 58.8kHz

Overvoltage Protection

Applying signals to the LTC1292/LTC1297’s analog

inputs that exceed the positive supply or that go below

ground will degrade the accuracy of the A/D and possi-

bly damage the devices. For example this condition

would occur if a signal is applied to the analog inputs

before power is applied to the LTC1292/LTC1297. An-

other example is the input source is operating from

different supplies of larger value than the LTC1292/

LTC1297. These conditions should be prevented either

with proper supply sequencing or by use of external

circuitry to clamp or current limit the input source.

There are two ways to protect the inputs. In Figure 23

diode clamps from the inputs to VCC and GND are used.

The second method is to put resistors in series with the

analog inputs for current limiting. Limit the current to

15mA per channel. The +IN input can accept a resistor

value of 1k but the –IN input cannot accept more than

250Ω when clocked at its maximum clock frequency of

1MHz. If the LTC1292/LTC1297 are clocked at the

maximum clock frequency and 250Ω is not enough to

current limit the input source, then the clamp diodes are

recommended (Figures 24a and 24b). The reason for

the limit on the resistor value is that the MSB bit test is

affected by the value of the resistor placed at the –IN

input (see discussion on Analog Inputs and the typical

performance characteristics Maximum CLK Frequency

vs Source Resistance).

FREQUENCY (kHz)

–60

–40

–20

15 25

LTC1292/7 F20a

–80

–100

510 20 30

–120

–140

MAGNITUDE (dB)

FREQUENCY (kHz)

–60

–40

–20

15 25

LTC1292/7 F22

–80

–100

510 20 30

–120

–140

MAGNITUDE (dB)

FREQUENCY (kHz)

–60

–40

–20

15 25

LTC1292/7 F20b

–80

–100

510 20 30

–120

–140

MAGNITUDE (dB)

FREQUENCY (kHz)

EFFECTIVE NUMBER OF BITS

9.5

10.0

10.5

60 100

LT1292/7 F21

9.0

8.5

8.0 20 40 80

11.0

11.5

12.0

fS = 58.8kHz

LTC1292/LTC1297

12927fb

If VCC and VREF are not tied together, then VCC should

be turned on first, then VREF. If this sequence cannot be

met, connecting a diode from VREF to VCC is recom-

mended (see Figure 25).

Because a unique input protection structure is used on

the digital input pins, the signal levels on these pins can

exceed the device VCC without damaging the device.

PPLICATI

I FOR ATIO

Figure 26. “Quick Look” Circuit for the LTC1292

LTC1292/7 F23

1N4148 DIODES

CLK

OUT

REF

+IN

–IN

GND

LTC1292

LTC1297

LTC1292/7 F24

1N4148 DIODES

CLK

OUT

REF

+IN

–IN

GND

LTC1292

LTC1297

Figure 24b. Overvoltage Protection with

Diode Clamps and Current Limiting Resistor

Figure 23. Overvoltage Protection with Clamp Diodes

LTC1292/7 F25

1N4148

CLK

OUT

REF

+IN

–IN

GND

LTC1292

LTC1297

Figure 25. Separate VCC and VREF Supplies

LTC1292/7 F24a

250Ω

CLK

OUT

REF

+IN

–IN

GND

LTC1292

LTC1297

Figure 24a. Overvoltage Protection with

Current Limiting Resistors

TO OSCILLOSCOPE

CD4520

LTC1292/7 F26

RESET

VDD

CLK

0.1µF

VIN

f/32 +5V

CLOCK IN

1MHz

22µF

CLK

VSS

RESET

VCC

CLK

DOUT

VREF

+IN

–IN

GND

LTC1292

LTC1292/LTC1297

12927fb

PPLICATI

I FOR ATIO

LSB

(B0) LSB-FIRST DATA

(B1)

MSB

(B11)

NULL

BIT

VERTICAL: 5V/DIV

HORIZONTAL: 2µs/DIV

CLK

DOUT

A “Quick Look” Circuit for the LTC1297

A circuit similar to the one used for the LTC1292 can be

used for the LTC1297(Figure 28). A one shot has been

generated with NAND gates, a resistor and capacitor to

satisfy the setup time tsuCS. This can be eliminated if a

slower clock is used. When CS goes low the one shot is

triggered. This turns off the clock to the LTC1297 for a

fixed time to meet tsuCS. Once the clock starts DOUT is

shifted out one bit at a time. CS is driven at 1/64 the

clock rate by the 74HC393. The output data from the

DOUT pin can be viewed on an oscilloscope that is set to

trigger on the falling edge of CS. See Figure 29.

CLK

DOUT

NULL

BIT MSB

(B11)

LSB-FIRST DATA

(B1)

LSB

(B0)

VERTICAL: 5V/DIV

HORIZONTAL: 5µs/DIV

Figure 29. Scope Trace of the LTC1297 “Quick Look”

Circuit Showing A/D Output 101010101010 (AAAHEX)

Figure 27. Scope Trace of the LTC1292 “Quick Look”

Circuit Showing A/D Output 101010101010 (AAAHEX)

Figure 28. “Quick Look” Circuit for the LTC1297

TO OSCILLOSCOPE

LTC1292/7 F28

0.1µF

VIN

f/64

340Ω

22µF

TANTALUM

VCC

CLK

DOUT

VREF

+IN

–IN

GND

LTC1297 74HC393

CLR1

1QA

1QB

1QC

1QD

GND

VCC

CLR2

2QA

2QB

2QC

2QD

0.02µF

CLOCK IN 1MHz

A “Quick Look” Circuit for the LTC1292

Users can get a quick look at the function and timing of

the LTC1292 by using the “Quick Look” circuit in Figure

26. VREF is tied to VCC. VIN is applied to the +IN input

and the –IN input is tied to the ground plane. CS is driven

at 1/32 the clock rate by the CD4520 and DOUT outputs

the data. The output data from the DOUT pin can be

viewed on an oscilloscope that is set up to trigger on the

falling edge of CS (Figure 27). Note the LSB data is

partially clocked out before CS goes high.

LTC1292/LTC1297

12927fb

PPLICATI

I FOR ATIO

Opto-Isolated Temperature Monitor

Amplification of sensor outputs is often required to

generate a signal large enough to be properly digitized.

For example, a J-type thermocouple provides only

52µV/°C. The 5µV offset of the LTC1050 chopper op

amp generates less than 0.1°C error (Figure 31). Cold

junction compensation is provided by the LT1025A.

(For more detail see LTC Design Note 5).

In the opto-isolated interface two signals are generated

from one. This allows a two-wire interface to the

LTC1292. A long high signal (>1ms) on the CLK IN input

allows the 0.1µF capacitor to discharge taking CS high.

This resets the A/D for the next conversion. When CLK

IN starts toggling, CS goes low and stays there until the

next extended CLK IN high time. See Figure 30.

5V/DIV

CLK IN

DATA OUT

20µs/DIV

1 F

TYPE J

GND

LT1025A

VIN H

–

LTC1050

0.33 Fµ

178k

0.1%

3.4k

0.1%

47Ω

1 Fµ

GND

LTC1292

VCC

–IN

+IN

CLK

DOUT

VREF

4.7 Fµ

3Ω

0.1 Fµ

10k

1N4148

22 FµLT1019-2.5

500k

21k CLK IN

500k

DATA

OUT

4N28s

1N4148

0°C – 500°C TEMPERATURE RANGE

ISOLATED

–

100k

74C14

LTC1292/7 F31

1N4148

Figure 31. Opto-Isolated Temperature Monitor

Figure 30. Opto-Isolated Temperature

Monitor Digital Waveforms

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.

However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen-

tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.

LTC1292/LTC1297

12927fb

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900

●

FAX: (408) 434-0507

●

www.linear.com

LT/CPI 0202 1.5K REV B • PRINTED IN USA

 LINEAR T ECHNOLOGY CORPORATION 1994

PACKAGE DESCRIPTIO

J8 Package

8-Lead CERDIP (Narrow .300 Inch, Hermetic)

(Reference LTC DWG # 05-08-1110)

N8 Package

8-Lead PDIP (Narrow .300 Inch)

(Reference LTC DWG # 05-08-1510)

RELATED PARTS

PART NUMBER DESCRIPTION COMMENTS

LTC1286 12-Bit, Micropower ADC in SO-8 12.5ksps, 1.3mW

LTC1402 12-Bit, 2.2Msps Serial ADC Unipolar (5V) or Bipolar (±5V), 90mW, 16-Pin SSOP Package

LTC1404 12-Bit, 600ksps Serial ADC in SO-8 Unipolar (5V) or Bipolar (±5V), 75mW

LTC1860 12-Bit, 250ksps Serial ADC in MSOP 4.25mW, Auto Shutdown-10µW at 1ksps

LTC1864 16-Bit, 250ksps Serial ADC in MSOP 4.25mW, Auto Shutdown-10µW at 1ksps

J8 1298

0.014 – 0.026

(0.360 – 0.660)

0.015 – 0.060

(0.381 – 1.524)

0.125

3.175

MIN

0.100

(2.54)

BSC

0.300 BSC

(0.762 BSC)

0.008 – 0.018

(0.203 – 0.457) 0° – 15°

0.045 – 0.065

(1.143 – 1.651)

0.045 – 0.068

(1.143 – 1.727)

FULL LEAD

OPTION

0.023 – 0.045

(0.584 – 1.143)

HALF LEAD

OPTION

CORNER LEADS OPTION

(4 PLCS)

0.200

(5.080)

MAX

0.005

(0.127)

MIN

0.405

(10.287)

MAX

0.220 – 0.310

(5.588 – 7.874)

1234

8765

0.025

(0.635)

RAD TYP

NOTE: LEAD DIMENSIONS APPLY TO SOLDER

DIP/PLATE OR TIN PLATE LEADS

N8 1098

0.100

(2.54)

BSC

0.065

(1.651)

TYP

0.045 – 0.065

(1.143 – 1.651)

0.130 ± 0.005

(3.302 ± 0.127)

0.020

(0.508)

MIN

0.018 ± 0.003

(0.457 ± 0.076)

0.125

(3.175)

MIN 12 34

8765

0.255 ± 0.015*

(6.477 ± 0.381)

0.400*

(10.160)

MAX

0.009 – 0.015

(0.229 – 0.381)

0.300 – 0.325

(7.620 – 8.255)

0.325 +0.035

–0.015

+0.889

–0.381

8.255

()

*THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.

MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm)

OBSOLETE PACKAGE