1 / 23

Analytical figures of merit, noise, and S/N ratio

Analytical figures of merit, noise, and S/N ratio. Chemistry 243. Noise. A signal is only of analytical value if it can be definitively attributed to the species/system of interest in the presence of noise . Probably noise, or not very useful; a hint of a signal. Looks like a real signal.

theta
Download Presentation

Analytical figures of merit, noise, and S/N ratio

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Analytical figures of merit, noise, and S/N ratio Chemistry 243

  2. Noise • A signal is only of analytical value if it can be definitively attributed to the species/system of interest in the presence of noise. Probably noise, or not very useful; a hint of a signal Looks like a real signal

  3. What is signal and noise?

  4. Signal-to-noise ratio (S/N) is a measure of the quality of an instrumental measurement Ratio of the mean of the analyte signal to the standard deviation of the noise signal High value of S/N : easier to distinguish analyte signal from the noise signal Signal-to-Noise Ratio (S/N) Mostly Signal signal Std. Dev. Mostly Noise Rev. Sci. Inst., 1966, 37, 93-102.

  5. Where does noise come from? • Chemical noise • Temperature, pressure, humidity, fumes, etc. • Instrumental noise

  6. Detector and post-detector noise • Thermal (Johnson) noise • Shot noise • Flicker (1/f) noise • Environmental noise • Popcorn (burst) noise • Microphonic noise

  7. Thermal (Johnson) noise • Random motions of charge carriers (electrons or holes) that accompany thermal motions of solid lattice of atoms. • Lead to thermal current fluctuations that create voltage fluctuations in the presence of a resistive element • Resistor, capacitor, etc. nrms = root-mean-square noise voltage k = Boltzman’s constant T = temperature R = resistance of element (W) Df = bandwith (Hz) = 1/(3tr) tr = rise time

  8. Thermal (Johnson) noise continued • Dependent upon bandwidth (Df) but not f itself • white noise • Can be reduced by narrowing bandwidth • Slows instrument response time • More time required for measurement • Reduced by lowering T • Common to cool detectors • 298K77K lowers thermal noise by factor of ~2 N2(l): bp=77K nrms = root-mean-square noise voltage k = Boltzman’s constant T = temperature R = resistance of element (W) Df = bandwith (Hz) = 1/(3tr) tr = rise time

  9. 11 e-/s 10.5 e-/s 10 e-/s Shot noise • Arises from statistical fluctuations in quantized behaviors • Electrons crossing junctions or surfaces • Independent of frequency • Example: current irms = root-mean-square noise current I = average direct current e = electron charge Df = bandwidth (Hz)

  10. Flicker (1/f) noise • Magnitude is inversely proportional to the frequency of the signal • Significant at frequencies lower than 100 Hz • Long-term drift • Origin is not well understood • Dependent upon materials and device shape • Metallic resistors have 10-fold less flicker noise than carbon-based resistors. • Referred to as “pink” noise—more red (low frequency) components

  11. Environmental noise • Comes from the surroundings • Biggest source is “antenna” effect of instrument cabling J. Chem. Educ., 1968, 45, A533-542.

  12. Noise contributions in different frequency regimes Frequency independent Supposedly 1/f—mostly at low frequencies Occurs at discrete frequencies

  13. Hardware methods Grounding and shielding Difference and Instrumentation Amplifiers Analog Filtering Lock-In Amplifiers Modulation and Synchronous Demodulation Software methods Ensemble averaging Boxcar averaging Digital filtering Correlation methods Enhancing signal-to-noise

  14. Grounding and shielding • Surround circuits (most critical conductors) with conducting material that is connected to ground • Noise will be picked up by shield and not by circuit • Faraday cage http://www.autom8.com/images_product/table_farady_benchtop.jpg http://farm2.static.flickr.com/1227/578199978_17e8133c7c_o.jpg

  15. Analog filtering • Low pass filter removes high frequency noise • Thermal and shot noise • High pass filter removes low frequency noise • Drift and flicker noise • Narrow-band electronic filters High freq removed. Low freq preserved (passed). Example of low-pass filter

  16. Lock-in amplifiers • Modulation • Translate low frequency signal (prone to 1/f noise) to a high frequency signal which can amplified and then filtered to remove 1/f noise Mechanical chopper

  17. Lock-in amplifierscontinued • Synchronous demodulation • Converts AC signal to DC signal synchronous with chopper—follows reference • Low-pass filtering • Back converts high frequency DC signal to return filtered, low frequency output.

  18. Ensemble averaging to increase S/N • Averaging multiple data sets taken in succession • Divide sum of data sets by number of data sets J. Chem. Educ., 1979, 56, 148-153.

  19. Ensemble averagingcontinued • Signal-to-noise improves with increasing number of data sets N = rms noise n = number of replicate scans i = number of replicate scans in other data set # Scans, n Relative S/N 1 1 4 2 16 4 64 8

  20. Boxcar averaging • Smoothing irregularities and increasing S/N • Assumes signal varies slowly in time • Multiple points are averaged to give a single value • Often performed in real time • Detail is lost and utility limited for rapidly changing samples • Boxcar integrators commonly used in fast (pico- to microsecond) measurements using pulsed lasers.

  21. Moving average smooth • Similar to a boxcar average, but changes in time

  22. Downside of moving average smoothing

  23. Digital filtering • Fourier transform • Convert data from time- to frequency-domain, manipulate to remove higher frequency noise components, regenerate time-domain signal • Polynomial data smoothing • Moving average smooth • Least-squares polynomial smoothing

More Related