LTC1968CMS8#TRPBF Linear Technology, LTC1968CMS8#TRPBF Datasheet - Page 10

LTC1968CMS8#TRPBF

Manufacturer Part Number

LTC1968CMS8#TRPBF

Description

IC CONVERTER RMS-DC PREC 8MSOP

Manufacturer

Linear Technology

Datasheet

1.LTC1968CMS8PBF.pdf (28 pages)

Specifications of LTC1968CMS8#TRPBF

Current - Supply

2.3mA

Voltage - Supply

5.0V

Mounting Type

Surface Mount

Package / Case

8-MSOP, Micro8™, 8-uMAX, 8-uSOP,

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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APPLICATIO S I FOR ATIO

LTC1968

Because this peak has energy (proportional to voltage

squared) that is 16 times (4

the peak is necessarily present for at most 6.25% (1/16)

of the time.

The LTC1968 performs very well with crest factors of 4 or

less and will respond with reduced accuracy to signals

with higher crest factors. The high performance with crest

factors less than 4 is directly attributable to the high

linearity throughout the LTC1968.

DESIGN COOKBOOK

The LTC1968 RMS-to-DC converter makes it easy to

implement a rather quirky function. For many applications

all that will be needed is a single capacitor for averaging,

appropriate selection of the I/O connections and power

supply bypassing. Of course, the LTC1968 also requires

power. A wide variety of power supply configurations are

shown in the Typical Applications section towards the end

of this data sheet.

Capacitor Value Selection

The RMS or root-mean-squared value of a signal, the root

of the mean of the square , cannot be computed without

some averaging to obtain the mean function. The LTC1968

true RMS-to-DC converter utilizes a single capacitor on

the output to do the low frequency averaging required for

RMS-to-DC conversion. To give an accurate measure of a

dynamic waveform, the averaging must take place over a

sufficiently long interval to average, rather than track, the

–0.2

–0.4

–0.6

–0.8

–1.6

–1.8

–2.0

–1.0

–1.2

–1.4

C = 22µF

C = 10µF

C = 47µF

) the energy of the RMS value,

C = 4.7µF

Figure 6. DC Error vs Input Frequency

C = 2.2µF

INPUT FREQUENCY (Hz)

lowest frequency signals of interest. For a single averaging

capacitor, the accuracy at low frequencies is depicted in

Figure 6.

Figure 6 depicts the so-called “DC error” that results at a

given combination of input frequency and filter capacitor

values

the output is fed to a circuit with an inherently band-limited

frequency response, such as a dual slope/integrating A/D

converter, a ∆Σ A/D converter or even a mechanical analog

meter.

However, if the output is examined on an oscilloscope with

a very low frequency input, the incomplete averaging will

be seen, and this ripple will be larger than the error

depicted in Figure 6. Such an output is depicted in

Figure 7. The ripple is at twice the frequency of the input

therefore easy to trim or calibrate out. The “Error Analyses” section to follow discusses the effect

of static error terms.

This frequency-dependent error is in additon to the static errors that affect all readings and are

. It is appropriate for most applications, in which

C = 1µF

Figure 7. Output Ripple Exceeds DC Error

ACTUAL OUTPUT

WITH RIPPLE

f = 2 × f

RIPPLE

PEAK

(5%)

INPUT

PEAK RIPPLE

DC ERROR +

ERROR =

(5.05%)

PEAK

C = 0.47µF

TIME

(0.05%)

ERROR

OUTPUT

IDEAL

OF ACTUAL

AVERAGE

OUTPUT

1968 F07

C = 0.22µF

1968 F06

100

1968f

LTC1968CMS8#TRPBF Linear Technology, LTC1968CMS8#TRPBF Datasheet - Page 10

LTC1968CMS8#TRPBF

Specifications of LTC1968CMS8#TRPBF

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