LTC1451IN8#PBF Datasheet LTC1451CS8#PBF, LTC1451IS8#PBF, LTC1451CN8#PBF | P7-P9

LTC1451

LTC1452/LTC1453

sn145123 145123fas

Resolution (n): Resolution is defined as the number of

digital input bits, n. It defines the number of DAC output

states (2

) that divide the full-scale range. The resolution

does not imply linearity.

Full-Scale Voltage (V

): This is the output of the DAC

when all bits are set to 1.

Voltage Offset Error (V

): Normally, DAC offset is the

voltage at the output when the DAC is loaded with all zeros.

The DAC can have a true negative offset, but because the

part is operated from a single supply, the output cannot go

below zero. If the offset is negative, the output will remain

near 0V resulting in the transfer curve shown in Figure 1.

The offset of the part is measured at the code that corre-

sponds to the maximum offset specification:

= V

OUT

– [(Code × V

)/(2

– 1)]

Least Significant Bit (LSB): One LSB is the ideal voltage

difference between two successive codes.

LSB = (V

– V

)/(2

– 1) = (V

– V

)/4095

Nominal LSBs:

LTC1451 LSB = 4.095V/4095 = 1mV

LTC1452 LSB = V(REF)/4095

LTC1453 LSB = 2.5V/4095 = 0.610mV

Integral Nonlinearity (INL): End-point INL is the maxi-

mum deviation from a straight line passing through the

end-points of the DAC transfer curve. Because the part

operates from a single supply and the output cannot go

below zero, the linearity is measured between full scale

and the code corresponding to the maximum offset speci-

fication. The INL error at a given input code is calculated

as follows:

INL = [V

OUT

– V

– (V

– V

)(code/4095)]/LSB

OUT

= The output voltage of the DAC measured at

the given input code

Differential Nonlinearity (DNL): DNL is the difference

between the measured change and the ideal 1LSB change

between any two adjacent codes. The DNL error between

any two codes is calculated as follows:

DNL = (∆V

OUT

– LSB)/LSB

∆V

OUT

= The measured voltage difference between

two adjacent codes

Digital Feedthrough: The glitch that appears at the analog

output caused by AC coupling from the digital inputs when

they change state. The area of the glitch is specified in

nV × sec.

DAC CODE

1451/2/3 F01

OUTPUT

VOLTAGE

NEGATIVE

OFFSET

Figure 1. Effect of Negative Offset

DEFI ITIO S

LTC1451

LTC1452/LTC1453

sn145123 145123fas

Reference

The LTC1451 includes an internal 2.048V reference, mak-

ing 1LSB equal to 1mV (gain of 2). The LTC1453 has an

internal reference of 1.22V with a full scale of 2.5V (gain of

2.05). The internal reference output is turned off when the

pin is forced above the reference voltage, allowing an

external reference to be connected to the reference pin.

The LTC1452 has no internal reference and the REF pin

must be driven externally. The buffer gain is 2, so the

external reference must be less than V

/2 and be capable

of driving the 8k minimum DAC resistor ladder.

Voltage Output

The LTC1451 family’s rail-to-rail buffered output can

source or sink 5mA over the entire operating temperature

range while pulling to within 300mV of the positive supply

voltage or ground. The output swings to within a few

millivolts of either supply rail when unloaded and has an

equivalent output resistance of 40Ω when driving a load to

the rails. The output can drive 1000pF without going into

oscillation.

Serial Interface

The data on the D

input is loaded into the shift register

on the rising edge of the clock. The MSB is loaded first. The

DAC register loads the data from the shift register when

CS/LD is pulled high. The CLK is disabled internally when

CS/LD is high. Note: CLK must be low before CS/LD is

pulled low to avoid an extra internal clock pulse.

The buffered output of the 12-bit shift register is available

on the D

OUT

pin which swings from GND to V

Multiple LTC1451/LTC1452/LTC1453s may be daisy-

chained together by connecting the D

OUT

pin to the D

pin of the next chip, while the CLK and CS/LD signals

remain common to all chips in the daisy chain. The serial

data is clocked to all of the chips, then the CS/LD signal is

pulled high to update all of them simultaneously.

OPERATIO

LTC1451

LTC1452/LTC1453

sn145123 145123fas

An Isolated 4mA to 20mA Process Controller

Has 3.3V Minimum Loop Voltage

11451/2/3 TA04

10k

45k 5k

90k 5k

2N3440

10Ω

LOOP

3.3V TO 30V

OUT

OUTIN

CLK

CS/LD

CLK

CS/LD

CLK

CS/LD

OUT

1µF

LTC1453

4N28

OPTO-ISOLATORS

3.3V

500Ω

1121-3.3

FROM

OPTO-

ISOLATED

INPUTS

REF

–

LT1077

This circuit shows how to use an LTC1453 to make an

opto-isolated digitally controlled 4mA to 20mA process

controller. The controller circuitry, including the opto-

isolation, is powered by the loop voltage that can have a

wide range of 3.3V to 30V. The 1.22V reference output of

the LTC1453 is used for the 4mA offset current and V

OUT

is used for the digitally controlled 0mA to 16mA current.

is a sense resistor and the op amp modulates the

transistor Q1 to provide the 4mA to 20mA current through

this resistor. The potentiometers allow for offset and full-

scale adjustment. The control circuitry dissipates well

under the 4mA budget at zero-scale.

Note that although these DACs have internal Schmitt

triggers and are suitable for use with slow rising edges

such as produced by the above optoisolator, the use of

optoisolators in a daisy-chained topology requires the

addition of a gate or the use of a fast isolator on the clock

signal. Setup and hold times between D

OUT

and D

are not

guaranteed unless a clock edge with a rise time of less than

100ns is provided.

TYPICAL APPLICATIO S

P1-P3 P4-P6 P7-P9 P10-P12

LTC1451IN8#PBF

Mfr. #:

Buy LTC1451IN8#PBF

Manufacturer:

Analog Devices Inc.

Description:

Digital to Analog Converters - DAC 12-Bit Vout DAC w/Vref, Serial I/O

Lifecycle:

New from this manufacturer.

Delivery:

DHL FedEx Ups TNT EMS

Payment:

T/T Paypal Visa MoneyGram Western Union

LTC1451IN8#PBF

LTC1451IN8#PBF

Products related to this Datasheet