Frequency range, Maximum frequency, Minimum frequency – Campbell Scientific CR9000X Measurement and Control System User Manual

Section 7. Measurement Instructions

7-57

Frequency Range

Maximum

Frequency

The maximum non-attenuated frequency in the FFT is a function of the
Sampling Frequency,

SR

f

, (FSampRate) and the Filter option (FiltOption)

The maximum frequency in the spectrum calculated by an FFT is half the
sampling frequency (

2

/

SR

f

). This is also called the Nyquist frequency.

FSampRate must be at least twice the maximum frequency of interest,

high

f

.

Any frequencies higher than the Nyquist frequency that were present in the
time series will be aliased, contributing to the lower frequency components.
Aliasing is not a concern with the CR9052 because the Pass frequency and the
stop frequency are both less than FSampRate/2 for all filter options except 1.
Alaising is not a problem with filter option 1 because any signals in the
transition band up to the stop frequency of 26.8 kHz will be alaised to
frequencies higher than the pass frequency of 23.2 kHz.

The pass frequency (F

PASS

) is the maximum frequency that is not attenuated by

the filter. Be sure that the selected filter option FiltOption in combination with
FSampRate makes F

PASS

greater than or equal to the maximum frequency of

interest,

high

f

. (i.e., that

pass

high

f

f

≤

).

One effect of the filter option used is on the number of spectral bins calculated
by the FFT beyond the pass frequency. The pass frequency is defined in terms
of the sampling ratio,

samp

R

, the ratio of the sample rate to the pass frequency :

samp

SR

pass

R

f

f

/

=

. For the smallest sampling ratio of 2.5, the number of

bins representing frequencies greater than

pass

f

is approximately 20% of the

bins calculated by the FFT. This goes up to 90% of the calculated bins for the
maximum sampling ratio of 20. It is easy to set IHigh to not return bins
beyond

pass

f

. However, the fewer calculations required for the same

maximum frequency,

pass

f

f

=

max

, when using a sampling ratio of 2.5 vs a

sampling ratio of 20 may make the difference between seamless and
intermittent FFTs if the FFT length has to be increased at the higher sample
rate to obtain the desired minimum frequency.

Minimum

Frequency

Once FsampRate is selected to include the highest frequency of interest,
FFTLen can be set to determine the lowest non-zero frequency.

The lowest frequency AC component of an FFT (bin 1 in the description of the

FFT Spectra above) has a center frequency,

( )

N

f

N

f

f

SR

SR

c

=

×

=

1

1

.

Where

SR

f

is the sample rate (FsampRate, samples/second) and

N

is the

number of samples (FFTLen). This frequency is the reciprocal of the time
required to complete the sampling. In other words, exactly one cycle of this
low frequency is completed in the time it takes to sample the time series for the