2252-DEMO THAT Corporation, 2252-DEMO Datasheet - Page 4

2252-DEMO

Manufacturer Part Number

2252-DEMO

Description

Power Management Modules & Development Tools RMS Detector Demo Board

Manufacturer

THAT Corporation

Type

AC/DC Switching Convertersr

Datasheet

1.2252L08-U.pdf (10 pages)

Specifications of 2252-DEMO

Input Voltage

12 V

Maximum Operating Temperature

+ 75 C

Minimum Operating Temperature

- 20 C

Product

Power Management Modules

Supply Current

1 mA

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 4 of 10
Download datasheet (373Kb)

Page 4

Computing the Mean

In the classic mathematical definition of rms

value, the time integral of the square of the signal

must be evaluated over infinite time. Obviously, for

a practical measurement, only a finite time is

available, which leads to the question of how to

weight events occuring at various times. Tradi-

tionally, the simplest and most meaningful weight-

ing is exponential in time, giving highest weight to

the most recent history, and exponentially less

weight to increasingly older events. This weighting

corresponds to convolution in time with the famil-

iar exponential weighting function, e

To accomplish this weighting, Pin 6 is normally

connected to a capacitor and a negative current

source. (Refer to the Typical Application Circuit in

Figure 4. In this circuit, C

together with V- form the current source.) This

current source

current, I

charges to 1 V

output of OA2).

The instantaneous emitter current in Q6 is propor-

tional to the antilog of its V

ence between Q6’s base voltage and the voltage at

pin 6. The potential at the base of Q6 represents

the log of the square of the input current, while

the emitter of Q6 is held at ac ground via the ca-

pacitor. Since Q6’s emitter current is proportional

to the antilog of its V

portional to the square of the instantaneous input

current.

Note that this antilogging only takes place for dy-

namic signals. For a dc input, the output of OA2

represents the square of the input current. After

charging, the external timing capacitor voltage

again approaches one diode drop below V

exact value of the diode drop will be determined by

the bias current I

in the input current I

SYM

50k

V+

Figure 4. Typical Application Circuit ( 15V)

20u

Cin

, through Q6. Over time, the capacitor

V-

24k

47k

establishes a quiescent dc bias

10k

Rin

. However, for sudden increases

below V

THAT Corporation; 45 Sumner Street; Milford, Massachusetts 01757-1656; USA

Tel: +1 508 478 9200; Fax: +1 508 478 0990; Web: www.thatcorp.com

, the current in Q6 is pro-

, the current available to

log

560k

SYM

V-

is the capacitor and R

V-

2252

(the potential at the

, which is the differ-

2M2

GND

IBIAS

OUT

CAP

V+

22M

10u

log

V+

OUT

. The

charge the capacitor C

square of the short-term increase in input current.

The “dynamic” antilogging causes the capacitor

voltage to represent the log of the mean of the

square of the input current.

Time Constants

Another way of looking at this situation is to con-

sider the action of Q6 and C

in the log domain. Q6 and C

pole at a frequency determined by a) the imped-

ance of Q6 at the bias current I

of C

The result is that the voltage at pin 6 represents

the average (or mean) of the square of the input

signal, averaged over the time constant . The av-

eraging corresponds to convolution with the time

weighting of a simple RC circuit. Mathematically,

this is as follows:

which the average level is computed. Note that

imposed by the log-domain filter.

How fast the 2252 acquires a signal (the “attack”),

and how fast it returns to rest following a signal

(the “release”), are locked in relationship to each

other

time-weighting imposed by this log-domain filter.

Separate attack and release adjustments are not

possible within the constraint of rms response.

The time response for typical values of I

(the circuit of Figure 4) is shown in Figure 5,

which shows the 2252’s response to a 100 ms,

1 kHz tone burst at ~ +10 dBV followed by

~500 ms of 1 kHz at ~ –30 dBV. The top trace is

the input tone burst (at 10 V/div), the bottom trace

is the output at 50 mV/div. The time scale is

50 ms/div.

The shape of the attack and release waveforms is

determined by the interaction of the exponential

response

log-representation of the signal. The straight-line

decay follows from the fact that the natural release

of the exponential time weighting is a decaying ex-

ponential in the linear world. This maps to a

straight line in the log representation. The attack

in the photo appears exponential, but actually fol-

lows the (

transformation from the linear to the log world

steepens the apparent attack shape.

The time constant, , also determines the amount

of ripple (at frequency 2f

. The time constant

represents the exponential time weighting

1 e

0 0259

the

I e dt

the

)

, at 300° Kelvin.

shape of the attack curve. The

nature

log-domain

THAT 2252 RMS-Level Detector

, where T is the time at

is given below.

is proportional to the

) in the output for any

as a first-order filter

establish a single

the

filter

and b) the value

exponential

with

and C

the

2252-DEMO THAT Corporation, 2252-DEMO Datasheet - Page 4

2252-DEMO

Specifications of 2252-DEMO

Related parts for 2252-DEMO