LTC1967IMS8 Linear Technology, LTC1967IMS8 Datasheet - Page 8

LTC1967IMS8

Manufacturer Part Number

LTC1967IMS8

Description

IC CONVERTER RMS-DC PREC 8MSOP

Manufacturer

Linear Technology

Datasheet

1.LTC1967CMS8.pdf (28 pages)

Specifications of LTC1967IMS8

Current - Supply

320µA

Voltage - Supply

5.0V

Mounting Type

Surface Mount

Package / Case

8-MSOP, Micro8™, 8-uMAX, 8-uSOP,

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

LTC1967IMS8#TRPBF

Manufacturer:

Quantity:

19 200

Current page: 8 of 28
Download datasheet (324Kb)

APPLICATIO S I FOR ATIO

How an RMS-to-DC Converter Works

Monolithic RMS-to-DC converters use an implicit compu-

tation to calculate the RMS value of an input signal. The

fundamental building block is an analog multiply/divide

used as shown in Figure 3. Analysis of this topology is

easy and starts by identifying the inputs and the output of

LTC1967

currents. The power delivered to the load depends on the

firing angle, as well as any parasitic losses such as switch

“ON” voltage drop. Real circuit waveforms will also typi-

cally have significant ringing at the switching transition,

dependent on exact circuit parasitics. For the purposes of

this data sheet, “SCR Waveforms” refers to the ideal

chopped sine wave, though the LTC1967 will do faithful

RMS-to-DC conversion with real SCR waveforms as well.

The case shown is for = 90 , which corresponds to 50%

of available power being delivered to the load. As noted in

Table 1, when

is being delivered to the load and the power drops quickly

With an average rectification scheme and the typical

calibration to compensate for errors with sine waves, the

RMS level of an input sine wave is properly reported; it is

only with a non-sinusoidal waveform that errors occur.

Because of this calibration, and the output reading in

an actual RMS-to-DC converter as opposed to a calibrated

average rectifier.

RMS

approaches 180 .

, the term True-RMS got coined to denote the use of

MAINS

= 114 , only 25% of the available power

LOAD

LINE

THY

LINE

–

Figure 2a

Figure 2b

CONTROL

LOAD

–

1967 F02b

–

1967 F02a

THY

the lowpass filter. The input to the LPF is the calculation

from the multiplier/divider; (V

filter will take the average of this to create the output,

mathematically:

Unlike the prior generation RMS-to-DC converters, the

LTC1967 computation does NOT use log/antilog circuits,

which have all the same problems, and more, of log/

antilog multipliers/dividers, i.e., linearity is poor, the band-

width changes with the signal amplitude and the gain drifts

with temperature.

How the LTC1967 RMS-to-DC Converter Works

The LTC1967 uses a completely new topology for RMS-to-

DC conversion, in which a

divider, and a simple polarity switch is used as the multi-

plier

Protected by multiple patents.

Because V

Figure 3. RMS-to-DC Converter with Implicit Computation

OUT

as shown in Figure 4.

OUT

is DC,

OUT

and

RMS V

OUT

LPF

modulator acts as the

)

OUT

1967 F03

. The lowpass

OUT

1967f

LTC1967IMS8 Linear Technology, LTC1967IMS8 Datasheet - Page 8

LTC1967IMS8

Specifications of LTC1967IMS8

Available stocks

Related parts for LTC1967IMS8