Appendix a. filter bandwidth and time delay – Campbell Scientific IRGASON Integrated CO2/H2O Open-Path Gas Analyzer and 3D Sonic Anemometer User Manual

Appendix A. Filter Bandwidth and Time

Delay

The EC100 measures CO

2

, H

2

O, 3-D wind components, and sonic temperature

from the IRGASON at 100 Hz and then applies a user-selectable low-pass

filter. The available filter bandwidths are 5, 10, 12.5, 20, and 25 Hz. FIGURE

A-1 shows the amplitude response of these filters. The EC100 filters provide a

flat pass band, a steep transition from pass band to stop band, and a well-

attenuated stop band. FIGURE A-2 compares the EC100 10 Hz filter to a 50

ms moving average filter with approximately the same bandwidth.

The ideal eddy-covariance filter is one that is wide enough to preserve the low-

frequency signal variations that transport flux and narrow enough to attenuate

high-frequency noise. In addition, to minimize aliasing (the misinterpretation

of high-frequency variation as lower-frequency variation), the measurement

bandwidth must be less than half of the sample rate (datalogger scan rate).

Two factors complicate choosing the ideal eddy-covariance bandwidth. First,

the flux signal bandwidth varies from one installation to another, and the flux

signal bandwidth varies with mean wind speed at a given installation. Second,

the fast sample rate required to anti-alias a desired signal bandwidth may result

in large, unwieldy data sets.

Fortunately, the covariance calculation itself relaxes the need for the ideal

bandwidth. First, the time-averaged (typically thirty-minute) covariance

calculations inherently reduce noise, and second, aliasing does not degrade the

accuracy of covariance calculations. Therefore, the factory default for the

EC100 bandwidth (20 Hz) is rather wide to preserve the signal variations that

transport flux, and that bandwidth is suitable for most flux applications.

Additional bandwidths are available for experimenters desiring to match the

EC100 filter bandwidth to their data acquisition sample rate to avoid aliasing.

In this case, the selected bandwidth should be one-half of the sample rate

(datalogger scan rate), and experimenters should be careful to avoid attenuation

of flux-carrying signals.

The EC100 electronics synchronously sample the gas analyzer and sonic

anemometer of the IRGASON. However, experimenters wishing to

synchronize their EC100 data with other measurements (e.g., energy balance

sensors) in the data acquisition system must account for the time delay of the

EC100 filter. TABLE A-1 shows the delay for each of the filter bandwidths.

The EC100 provides a constant time delay for all spectral components within

each filter’s pass band.

The following examples show how to use TABLE A-1. To synchronize

EC100 data to other datalogger measurements when the datalogger scan rate is

25 Hz and the EC100 bandwidth is set to 20 Hz (a 200 ms delay from TABLE

A-1), delay the non-EC100 data by five datalogger scans. Similarly, for a 10

Hz datalogger scan rate and the same 20 Hz EC100 bandwidth, delay the non-

EC100 data by two datalogger scans to match the EC100 data. For the best

synchronicity, choose a datalogger scan interval that is an integer multiple of

the EC100 filter delay.

A-1