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Additions to Section 13.3 of WSJT-X User Guide: "Phase Equalkization".
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@8124 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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@ -77,6 +77,7 @@ d). Edit lines as needed. Keeping them in alphabetic order help see dupes.
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:launchpadki7mt: https://launchpad.net/~ki7mt[KI7MT PPA's]
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:log4om: http://www.log4om.com[Log4OM]
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:lunarEchoes: http://physics.princeton.edu/pulsar/K1JT/LunarEchoes_QEX.pdf[QEX]
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:msk144: http://physics.princeton.edu/pulsar/k1jt/MSK144_Protocol_QEX.pdf[QEX]
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:msys_url: http://sourceforge.net/projects/mingwbuilds/files/external-binary-packages/[MSYS Download]
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:ntpsetup: http://www.satsignal.eu/ntp/setup.html[Network Time Protocol Setup]
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:osx_instructions: http://physics.princeton.edu/pulsar/K1JT/OSX_Readme[Mac OS X Install Instructions]
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@ -72,60 +72,61 @@ slow modes, select *Measure reference spectrum* from the *Tools* menu.
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Wait for about a minute and then hit the *Stop* button. A file named
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`refspec.dat` will appear in your log directory.
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[ ... TBD ... ]
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[ ... more to come ... ]
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=== Phase Response and Equalization
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=== Phase Equalization
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*Measure phase response* under the *Tools* menu is for advanced MSK144
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users. Phase equalization is used to compensate for group-delay
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variation across the passband of receiver filters. Careful application
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of this facility can reduce intersymbol interference, resulting in
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improved decoding sensitivity. If you use a software-defined receiver
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with linear-phase filters there is no need to apply phase
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equalization.
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variation across your receiver passband. Careful application of this
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facility can reduce intersymbol interference, resulting in improved
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decoding sensitivity. If you use a software-defined receiver with
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linear-phase filters there is no need to apply phase equalization.
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After a received frame is decoded *Measure phase response* generates
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an undistorted waveform whose Fourier transform is used as a
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frequency-dependent phase reference to compare with the phase of the
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received frame's Fourier coefficients. Phase differences between the
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reference and the received waveform include contributions from the
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originating station's transmit filter, the propagation channel, and
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filters in the receiver. If the received frame originates from a
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station known to transmit signals having little phase distortion (say,
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a station known to use a properly adjusted
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software-defined-transceiver) and if the received signal is relatively
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free from multipath distortion so that the channel phase is close to
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linear, the measured phase differences will be representative of the
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local receiver's phase response.
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After a frame of received data has been decoded, *Measure phase
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response* generates an undistorted audio waveform equal to the one
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generated by the transmitting station. Its Fourier transform is then
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used as a frequency-dependent phase reference to compare with the
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phase of the received frame's Fourier coefficients. Phase differences
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between the reference spectrum and received spectrum will include
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contributions from the originating station's transmit filter, the
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propagation channel, and filters in the receiver. If the received
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frame originates from a station known to transmit signals having
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little phase distortion (say, a station known to use a properly
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adjusted software-defined-transceiver) and if the received signal is
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relatively free from multipath distortion so that the channel phase is
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close to linear, the measured phase differences will be representative
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of the local receiver's phase response.
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Complete the following steps to generate a phase equalization curve:
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- Record a number of wav files that contain decodable signals from
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your chosen reference station. Best results will be obtained when the
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SNR of the reference signals is at least 9 dB.
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aignal-to-noise ratio of the reference signals is 10 dB or greater.
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- Enter the callsign of the reference station in the DX Call box.
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- Select *Measure phase response* from the *Tools* menu, and process
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the wav files. The mode character will change from `&` to `^` while
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_WSJT-X_ is measuring the phase response and it will change back to
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`&` after the measurement is completed. The program needs to average a
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number of high-SNR frames to accurately estimate the phase, so it may
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be necessary to process several wav files. The measurement can be
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aborted at any time by selecting *Measure phase response* again to
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toggle the phase measurement off.
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- Select *Measure phase response* from the *Tools* menu, and open each
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of the wav files in turn. The mode character on decoded text lines
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will change from `&` to `^` while _WSJT-X_ is measuring the phase
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response, and it will change back to `&` after the measurement is
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completed. The program needs to average a number of high-SNR frames to
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accurately estimate the phase, so it may be necessary to process
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several wav files. The measurement can be aborted at any time by
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selecting *Measure phase response* again to toggle the phase
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measurement off.
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+
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When the measurement is complete _WSJT-X_ will save the measured
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phase response in the *Log directory*, in a file with suffix
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".pcoeff". The filename will contain the callsign of the reference
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station and a timestamp. For example: K0TPP_170923_112027.pcoeff
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station and a timestamp, for example `K0TPP_170923_112027.pcoeff`.
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- Select *Equalization tools ...* under the *Tools* menu and click the
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*Phase ...* button to view the contents of the *Log directory*. Select
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the desired pcoeff file. The measured phase values will be plotted as
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discrete circles along with a fitted curve labeled "Proposed". This is
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filled circles along with a fitted red curve labeled "Proposed". This is
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the proposed phase equalization curve. It's a good idea to repeat the
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phase measurement several times, using different wav files for each
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measurement, to ensure that your measurements are repeatable.
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@ -135,55 +136,59 @@ to save the proposed response. The red curve will be replaced with a
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light green curve labeled "Current" to indicate that the phase
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equalization curve is now being applied to the received data. Another
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curve labeled "Group Delay" will appear. The "Group Delay" curve shows
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the group delay variation across the passband, in ms. Push the
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*Discard* button to remove the captured data, leaving only the applied
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the group delay variation across the passband, in ms. Click the
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*Discard* button to remove the captured data, leaving only the applied
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phase equalization curve and corresponding group delay curve.
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- To revert to no phase equalization, push the *Restore Defaults*
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button followed by the *Apply* button.
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The three numbers that are printed at the end of each MSK144 decode line
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can be used to assess the improvement provided by equalization. These numbers
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`N` `H` `E` are:
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`N` - Number of frames averaged,
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`H` - Number of bit errors corrected,
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`E` - Size of MSK eye diagram opening.
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The three numbers printed at the end of each MSK144 decode line can be
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used to assess the improvement provided by equalization. These numbers
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are: `N` = Number of frames averaged, `H` = Number of hard bit errors
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corrected, `E` = Size of MSK eye diagram opening.
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Here is a decode of K0TPP obtained while *Measure phase response* was measuring
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the phase response:
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103900 17 6.5 1493 ^ WA8CLT K0TPP +07 1 0 1.2
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The "^" symbol indicates that a phase measurement is being accumulated. The
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three numbers at the end of the line indicate that one frame was
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used to obtain the decode, there were no bit errors, and the
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eye-opening was 1.2. Here's how the same decode looks after phase equalization:
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The "^" symbol indicates that a phase measurement is being accumulated
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but is not yet finished. The three numbers at the end of the line
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indicate that one frame was used to obtain the decode, there were no
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hard bit errors, and the eye-opening was 1.2 on a -2 to +2
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scale. Here's how the same decode looks after phase equalization:
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103900 17 6.5 1493 & WA8CLT K0TPP +07 1 0 1.6
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In this case, equalization has increased the eye opening from 1.2 to 1.6.
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Larger eye openings are associated with reduced likelihood of bit errors and
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higher likelihood that a frame will be successfully decoded.
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In this case, the larger eye-opening
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tells us that phase equalization was successful, but it is important to note
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that this test does not tell us whether the applied phase equalization curve
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is going to improve decoding of signals other than those from the reference
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station, K0TPP!
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In this case, equalization has increased the eye opening from 1.2 to
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1.6. Larger positive eye openings are associated with reduced
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likelihood of bit errors and higher likelihood that a frame will be
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successfully decoded. In this case, the larger eye-opening tells us
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that phase equalization was successful, but it is important to note
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that this test does not by itself tell us whether the applied phase
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equalization curve is going to improve decoding of signals other than
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those from the reference station, K0TPP.
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We strongly advise you to carry out before and after comparisons
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using a large number of saved wav files with signals from many different
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stations to decide whether or not the equalization curve improves decoding for most
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signals. When doing before and after comparisons, keep in mind that
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equalization may cause _WSJT-X_ to successfully decode a frame
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that was not decoded before equalization was applied.
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For this reason, be sure that the time "T" of
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the two decodes are the same before comparing their end-of-line quality numbers.
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It's a good idea to carry out before and after comparisons using a
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large number of saved wav files with signals from many different
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stations, to help decide whether your equalization curve improves
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decoding for most signals. When doing such comparisons, keep in mind
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that equalization may cause _WSJT-X_ to successfully decode a frame
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that was not decoded before equalization was applied. For this
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reason, be sure that the time "T" of the two decodes are the same
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before comparing their end-of-line quality numbers.
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When comparing before and after decodes having the same "T", keep in mind
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that a smaller first number means that decoding has improved, even if the
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second and third numbers appear to be "worse". For example, suppose that the quality
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numbers before equalization are "2 0 0.2" and after equalization
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"1 5 -0.5". These numbers show improved decoding because
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the decode was obtained using only a single
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frame after equalization whereas a 2-frame average was needed before equalization.
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When comparing before and after decodes having the same "T", keep in
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mind that a smaller first number means that decoding has improved,
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even if the second and third numbers appear to be "worse". For
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example, suppose that the end-of-line quality numbers before
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equalization are `2 0 0.2` and after equalization `1 5 -0.5`. These
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numbers show improved decoding because the decode was obtained using
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only a single frame after equalization whereas a 2-frame average was
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needed before equalization. This implies that shorter and/or weaker
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pings could be decodable.
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NOTE: Further details on phase equalization and examples of fitted
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phase curves and eye diagrams can be found in the article on MSK144 by
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K9AN and K1JT published in {msk144}.
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