Casella CEL CEL-160 User Manual

description of the F key in section 3.1, whilst

the following cable sets are available for

connecting filters to the recorder.

CableType Description

CEL-3697

CEL-196/160 Automatic Frequency
Recording

CEL-3698

SA59/CEL-160 Automatic Frequency
Recording

CEL-3699

B & K 2215/CEL-160 Frequency
Recording

CEL-3700

SA24/CEL 160 Automatic Frequency
Recording

CEL-3701

B & K1621/CEL-160 Frequency
Recording

CEL-3727

B & K1616/CEL-160 Freqency Recording

CEL-3728

B & K1618/CEL-160 Automatic
Frequency Recording

Figure 5: Standard cable sets for

frequency analysers

6.1

Stepped Serial Analysers

The CEL-160 operates with these filters

connected into its sound level meter section in

order that they filter the AC signal into

frequency bands as it is passed through this

section of the recorder. An output level for

each band is therefore obtained in sequence.

Cable sets for these filters provide plugs for

connection to the filter in and out sockets

(cable marked input to filter input socket etc)

and a control cable for connection to the

remote socket. The FILTER-A-LIN switch must

be in the filter position and the instrument

calibrated with the filter in circuit. The filter

should be set for automatic analysis as per its

own operational instructions, which in the case

of the CEL-196 means depressing its 'Reset'

button. The recorder should be set for log level

recording (10 mS time constant) at a paper

speed of 1 mm/S.

When the analysis is required the E key

should be depressed. This will cause the time

scale annotations to be printed and the filter

will then step through its various frequency

weightings and band filters. Each band is

represented by 5 mm of chart and annotated

A.B.C.D. and AP (all pass) for the broad band

settings and each individual octave band

annotated with its centre frequency. For

clarity, individual third octave bands are not

annotated but each band is clearly denoted by

a vertical line drawn from the maximum band

level for approximately 10 mm.

Most serial analysers produce switching

spikes when changing bands and these take

some time to decay. Similarly, it takes some

time for a high level in one band to decay to a

lower level that may exist in an adjacent band.

In order to ensure that these factors do not

cause errors in an analysis, the following

functions have been written into the

controlling program.

(i)

The recorder always waits 50 ms

between bands.

(ii)

The filter can hold the recorder from

progressing the scan until its switching

transients have decayed.

(iii)

The analysis will not proceed if the signal

is decaying at a rate in excess of 1 dB/S.

The requirements of the relationship between

bandwidth and averaging time are now widely

appreciated.

Using conventional electromechanical

level recorders to drive serial analysers the

worst case had to be assumed and the scan

rate selected to suit the lowest frequency and

the narrowest bandwidth. As a result of these

constraints an analysis always took much

longer than was necessary because it was not

possible to alter the scan rate when the higher

frequencies and wider bands were reached.

With the advent of the micro- processor

control that is incorporated into the CEL-160, it

becomes possible to dynamically control the

analysis to optimise these parameters.

In selecting a serial filter program the

recorder makes basic decisions regarding

averaging time and sweep speed based upon

the filter characteristics, and these parameters

are both controlled during the analysis to

produce the optimum results in the shortest

time.

A digital time constant is introduced into

the measurement chain that is varied along

with the paper speed during the sweep.

Ideally, the product of the time constant and

bandwidth should be constant and should

therefore, for a constant percentage

bandwidth filter, change every band but

experience has shown that changes less often

are acceptable. The CEL-160 will change the

time constant every 5 third-octaves (or 2

octaves) and changes by a factor of

approximately 3 each time. Two changes are

provided giving a total change of 10 to 1.

In practice the time constant is reduced

and the paper speed increased in synchro-

nisation; the full relationsahip is given in Fig 6.

Page 14 - CEL-160 Graphic Recorder