World Library  
Flag as Inappropriate
Email this Article

Spectrogram

Article Id: WHEBN0000263317
Reproduction Date:

Title: Spectrogram  
Author: World Heritage Encyclopedia
Language: English
Subject: Transcription (music), Pattern playback, Acoustics, Formant, List of unexplained sounds
Collection: Acoustic Measurement, Acoustics, Signal Processing, Time–frequency Analysis
Publisher: World Heritage Encyclopedia
Publication
Date:
 

Spectrogram

Typical spectrogram of the spoken words "nineteenth century". The lower frequencies are more dense because it is a male voice. The legend to the right shows that the color intensity increases with the density.

A spectrogram is a visual representation of the spectrum of frequencies in a sound or other signal as they vary with time or some other variable. Spectrograms are sometimes called spectral waterfalls, voiceprints, or voicegrams.

Spectrograms can be used to identify spoken words phonetically, and to analyse the various calls of animals. They are used extensively in the development of the fields of music, sonar, radar, and speech processing,[1] seismology, etc.

The instrument that generates a spectrogram is called a spectrograph.

The sample outputs on the right show a select block of frequencies going up the vertical axis, and time on the horizontal axis.

Spectrogram of . Note the harmonics occurring at whole-number multiples of the fundamental frequency. Note the fourteen draws of the bow, and the visual differences in the tones.

Contents

  • Format 1
  • Generation 2
  • Applications 3
  • Limitations and resynthesis 4
  • See also 5
  • References 6
  • External links 7

Format

3D surface spectrogram of a part from a music piece.

A common format is a graph with two geometric dimensions: the horizontal axis represents time or rpm, the vertical axis is frequency; a third dimension indicating the amplitude of a particular frequency at a particular time is represented by the intensity or color of each point in the image.

There are many variations of format: sometimes the vertical and horizontal axes are switched, so time runs up and down; sometimes the amplitude is represented as the height of a 3D surface instead of color or intensity. The frequency and amplitude axes can be either linear or logarithmic, depending on what the graph is being used for. Audio would usually be represented with a logarithmic amplitude axis (probably in decibels, or dB), and frequency would be linear to emphasize harmonic relationships, or logarithmic to emphasize musical, tonal relationships.

Generation

Spectrogram of a male voice saying 'ta ta ta'.
Spectrogram of an FM signal. In this case the signal frequency is modulated with a sinusoidal frequency vs. time profile

Spectrograms are usually created in one of two ways: approximated as a filterbank that results from a series of bandpass filters (this was the only way before the advent of modern digital signal processing), or calculated from the time signal using the FFT. These two methods actually form two different Time-Frequency Distributions, but are equivalent under some conditions.

The bandpass filters method usually uses analog processing to divide the input signal into frequency bands; the magnitude of each filter's output controls a transducer that records the spectrogram as an image on paper.[2]

Creating a spectrogram using the FFT is a digital process. Digitally sampled data, in the time domain, is broken up into chunks, which usually overlap, and Fourier transformed to calculate the magnitude of the frequency spectrum for each chunk. Each chunk then corresponds to a vertical line in the image; a measurement of magnitude versus frequency for a specific moment in time. The spectrums or time plots are then "laid side by side" to form the image or a three-dimensional surface,[3] or slightly overlapped in various ways, windowing.

The spectrogram of a signal s(t) can be estimated by computing the squared magnitude of the STFT of the signal s(t), as follows:[4]

\mathrm{spectrogram}(t,\omega)=\left|\mathrm{STFT}(t,\omega)\right|^2

Applications

Spectrogram of dolphin vocalizations; chirps, clicks and harmonizing are visible as inverted Vs, vertical lines and horizontal striations respectively
Great Tit : song
Spectrogram of Great Tit song
  • Early analog spectrograms were applied to a wide range of areas including the study of bird calls (such as that of the Great Tit), with current research continuing using modern digital equipment[5] and applied to all animal sounds. Contemporary use of the digital spectrogram is especially useful for studying frequency modulation (FM) in animal calls. Specifically, the distinguishing characteristics of FM chirps, broadband clicks, and social harmonizing are most easily visualized with the spectrogram.
  • Spectrograms are useful in assisting in overcoming speech defects and in speech training for the portion of the population that is profoundly deaf[6]
  • The studies of phonetics and speech synthesis are often facilitated through the use of spectrograms.[7][8]
  • By reversing the process of producing a spectrogram, it is possible to create a signal whose spectrogram is an arbitrary image. This technique can be used to hide a picture in a piece of audio and has been employed by several electronic music artists.[9] See also steganography.
  • Some modern music is created using spectrograms as an intermediate medium; changing the intensity of different frequencies over time, or even creating new ones, by drawing them and then inverse transforming. See Audio timescale-pitch modification and Phase vocoder.
  • Spectrograms can be used to analyze the results of passing a test signal through a signal processor such as a filter in order to check its performance.[10]
  • High definition spectrograms are used in the development of RF and microwave systems[11]
  • Spectrograms are now used to display S-parameters measured with vector network analyzers[12]
  • The US Geological Survey now provides real-time spectrogram displays from seismic stations[13]

Limitations and resynthesis

From the formula above, it appears that a spectrogram contains no information about the exact, or even approximate, phase of the signal that it represents. For this reason, it is not possible to reverse the process and generate a copy of the original signal from a spectrogram, though in situations where the exact initial phase is unimportant it may be possible to generate a useful approximation of the original signal. The Analysis & Resynthesis Sound Spectrograph [2] is an example of a computer program that attempts to do this. The Pattern Playback was an early speech synthesizer, designed at Haskins Laboratories in the late 1940s, that converted pictures of the acoustic patterns of speech (spectrograms) back into sound.

In fact, there is some phase information in the spectrogram, but it appears in another form, as time delay (or group delay) which is the dual of the Instantaneous Frequency .

The size and shape of the analysis window can be varied. A smaller (shorter) window will produce more accurate results in timing, at the expense of precision of frequency representation. A larger (longer) window will provide a more precise frequency representation, at the expense of precision in timing representation.

See also

References

  1. ^ JL Flanagan, Speech Analysis, Synthesis and Perception, Springer- Verlag, New York, 1972
  2. ^ Illustration of an electro-mechanical spectrograph
  3. ^ Spectrogram definition
  4. ^ STFT spectrogram details
  5. ^ Bird Songs and Spectrograms of Southern Tuscany
  6. ^ A wearable tactile sensory aid for profoundly deaf children
  7. ^ Spectrogram Reading
  8. ^ Praat - doing phonetics by computer
  9. ^ Several sound spectrogram examples, including the one by Aphex Twin
  10. ^ Example of using spectrograms to check filter responses
  11. ^ High definition spectrograms of common RF signals
  12. ^ Spectrograms for vector network analyzers
  13. ^ Real-time spectrogram displays from seismic stations

External links

  • See an online spectrogram of speech or other sounds captured by your computer's microphone.
  • Generating a tone sequence whose spectrogram matches an arbitrary text, online
  • Further information on creating a signal whose spectrogram is an arbitrary image
  • Article describing the development of a software spectrogram
  • History of spectrograms & development of instrumentation
  • How to identify the words in a spectrogram from a linguistic professor's Monthly Mystery Spectrogram publication.
This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and USA.gov, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for USA.gov and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
 
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
 
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.
 



Copyright © World Library Foundation. All rights reserved. eBooks from World eBook Library are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.