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Profiel
van André Kappert weergeven
A sort of Mifare Classic Tool for uFR Classic: ufr_Bold
Sound recordings are
mixed for listening with speakers. Even the best headphones can’t
hide this. It is as looking through a fishbowl, but than in sound.
Strongly enlarged, but also strongly bent, with strong dispersion of
frequencies. If a sound source moved in a straight line from the left
speaker to the right speaker, it will sound with a headphone as if
this movement is circular with a variable speed, from ear to ear. The
speed of this movement is also frequency dependent. In figure 1 you
see the arrangement of an ordinary sound system with 2 speakers.
Let's suppose you are listening to a choir with 120 members. The
members seems to be evenly distributed behind the speakers, the angle
limited by the angle of the speakers. What happens when listening
this with headphones is reflected in figure 2.
Problem 1:Every ear is reached by the sound of both speakers
but the sound of the opposite speaker is somehow damped. The higher
the frequency of the sound ,the more the damping. Because with
speakers the sound of 2 sources reaches the ear, the sound is
amplified. The amplification of the lower frequencies is stronger.
This doesn’t happen with headphones so the lower frequencies seems
to come from a longer distant the higher frequencies(red is
representing the lower frequencies, blue the higher frequencies, in
the speaker figure these spots overlap) . Every sound is a compound
of higher and lower frequencies. With headphones these sound
don’t seem come from one point but comes from an area. The
different frequencies are split. Not only the distant will vary but
also the angle will be different because the HRTF (human ratio
transfer function) is a function of frequency and angle. Some
headphones compensate for the weak low frequencies but this don’t
work for the diffraction as function of the angle.
Problem
2:When all the signal is on one channel, with speakers the source
seems to be come from behind one speaker, this is the largest
possible angle, and it still sounds natural. When listening with
headphones the sounds originated directly in one ear. The other
ear is in totally silence. This normally only happens when a mosquito
is near your ear and don’t sound pleasant. It can causes even
stress because these sound sources seems to come from very
close.
Problem 3:The hearing system is trying to calculate the
position of the sound source. It is doing this by using the
difference in amplitude and by using the difference in phase. Two
different systems with the best result for different frequency-bands.
But there is overlap at certain frequencies. For these frequencies
the systems had to come for the same result as location. These
frequencies are located in the most import frequency-band where the
hearing is most sensible (1000 Hz to 5000HZ). With headphones these
two system don’t give coherent results any more. It is tiring for
the hearing system to make sense from these 2 different results. It
should also be the reason that with listening to headphones the sound
always seems to come from behind.
Solution: Add to the signal of
one channel of the headphone, with a delay and filtered according the
HRTF, the signal of the other channel. A sort of artificial
head recording. The signal is now as it should be with listening with
speakers. The delay takes care of the right phase, the HRTF takes
care of the right amplitude. The problem is to find the right HRTF It
can be found with testing with a simple sinus test signal. My program
DVDtoHP can be used for fine adjustment of the HRTF.
I made a
LADSPA filter for doing this job. It can be used with sound editing
programs or media players, able to supporting LADSPA filters. In
figure 3 is a graphical representation of a test signal of pink
noise. Figure 4 is the resulting filtered version. The difference is
considerable.
Figure 3: Example consistent of pink noise
Figure 4:With stereotobinaural LADSPA treated example,
with gain =1.0
The same technique is used in the program
DVDtoHP, but expanded to the rear speakers and the front and LFE
speakers so you can listen to 5.1 recording with headphone. The
sound still seems to come from behind so I guess that this is not
caused by discrepancy between phase and amplitude information, so
there is still possibility for improvements if I understand what is
causing this. But the spreading of the sound is much improved.
You now can pinpoint the instruments exactly to the location, the
separation of the instrument is improved.
A similar
product is the bs2b filter (Bauer
stereophonic-to-binaural DSP). The major difference is that my
version is specially made for 5.1 recordings, in the form of AC3 and
DTS files(Linux version), and it is also usable for stereo. Both are
crossfeeder, but bs2b seems to simulate an original analog filter. My
version keeps it simple, it uses a delay and a filter, almost the
same as in natural. Bs2b excludes the effect of comb filter in the
upper range of frequencies through the nonlinear property of
phase-frequency response of these filters. I see the comb filter
effect as unavoidable as in a normal speaker situation. With 2
speakers it is also happening. The provided delay gives a simulated
position of the speakers, the damping had to be adjusted so that the
damping and the delay leads to the same position. The filter is a
convolution filter.
The Linux version is a .deb installation program also used by Ubuntu. For Linux there is a VST and LADSPA version, for Windows there is a VST version. When working with a DAW, good monitors are necessary to listen the result. With this filter (stereotoheadphone filter) plugged in the master, it is also possible to mix and master with headphones (and remove the filter in the final result else the recording only sounds great when listened with headphones and not with speakers).
The surroundtoheadphone version is more difficult. In Ardour, create a 5 channel audio bus. Install the surroundtoheadphone plugin in this bus. The plugin has 5 input channels and 2 output channels. Right click the filter and select “Pin connections”. Activate “Manual Config” and adjust the “Audio out” number to 2. The bus output will be binaural. The 5 input channels will represent the speaker positions from left to right. Use the “routing grid” of the output of the instruments to connect to the different channels of the 5 channel bus. The same thing with surroundPosition (a panning plugin) plugin, create a 1 channel audio bus. Install the surroundLocation plugin in this bus. The plugin has 1 input channel and 5 output channels. Right click the filter and select “Pin connections”. Activate “Manual Config” and adjust the “Audio out” number to 5. The bus output will be surround. Bypass the standard panning device (the circle). Connect output with the surroundtoheadphone (5 channels) bus.
Download VST plugins for Windows 7,8
and 10
Download LADSPA
plugins and VST plugins for Linux
DVDtoHP is meant to convert (and has a tab for extract audio from
DVD) audio tracks to binaural This is about the Linux version, but
the Windows version is almost the same. There is also a Windows and a
Macintosh version (old, not updated) to download. The audio
information on DVD is mostly available in different forms. The best
quality is the .dts(5.1) track, second choice is the .ac3(5.1) track.
Sometimes there is a stereo track available (in ac3 or lpcm format).
The stereo tracks are often not the best quality, too much
compression and even clipping. It isn’t possible to recreate the
sound-image of 6 speakers with 2 speakers or it should be an
"artificial head" recording (or binaural recording) in a
surround-sound setup, listened with headphones. DVDtoHP simulates an
"artificial head" recording. Sound from a left channel
reaches first the left ear and with a delay it also reaches the right
ear. Higher frequencies are muffled more than lower frequencies. This
is simulated by deliver the signal from the left side filtered and
delayed to the right side and visa versa. The rear and front channels
get a different delay and filter. The rear channels get a longer
delay and are more muffled than the front channels.
It is
difficult to predict how this will sound to different people. Every
person has a different HRTF, Head Related Transfer Function caused by
different size and build of head and ears. In fact, a normal stereo
recording shouldn't be listen-able with a headphone. Sound is
delivered totally independent to the ears, in normal situations this
only happening when a bee is buzzing in one of your ears. The human
brain is still capable of processing these sounds. I believe the
human brain is even better capable to process the sound from the
artificial human head used in this program.
An example: take a
recording of a low frequency signal with one channel in anti-phase
with the other channel. When listening with speakers you will hear
almost nothing (sometimes this actual happened when the wires of a
speaker are wrongly connected), when listening with headphone, you
will hear the full power of the recording. A proof that a recording
can sound totally different when listened with headphone. When
processed by this program you will hear almost nothing as if you
where listen to it with speakers.
The program is able to convert
not only 5.1 audio but also stereo files ( wav, flac, mp3 etc.).
Listening to the converted files, sound as if you are listening to
speakers, giving the intended sound experience as meant by the mixer.
The CD's are mixed for speakers in the normal configuration, not for
headphones.
The program is capable of converting multiple files
at the same time, using the multi-core processors optimal. Multiple
files can be selected in the “Open” dialog. The converting could
be done in the background of normal computer use.
The program
has 4 tabs.
In the first tab are the conversion buttons. A
button for conversion to headphone audio and a button for conversion
to normal stereo(from multichannel audio or an unusual format). The
second tab has the conversion to headphone audio with using sofalizer
from ffmpeg.The conversion starts with selecting audio input file
(multiple files selectable), second it asks for the saving file name.
If the extension is mp3 or flac it will ask for meta data, and
automatically compress the audio file. Then a wait screen will start
with the progress. This is an independent window, allowing you to
start another conversions from the control program.
The program uses ffmpeg ( from ffmpeg package )to decompress the
file to a 6 channels floating points file.Then my program will
convert this file to a 2 Channels floating points file. Then it will
normalize and convert it to an ordinary microsoft wav 16 bits, 2
channels file. Last step. it could be compressed with lame program or
flac program if extension was flac or mp3.
The program depends
on the program ffmpeg of package ffmpeg for decompressing dts and ac3
files to floating points. For ripping the DVD it uses mplayer of
package mplayer. For compression it use Lame of package lame and Flac
of package flac. All these programs will automatic installed by the
deb installation program. For other Linux versions the bare program
is provided. The dependencies must be provided by the user.
It
is unclear for me if Package libdvdread4
(you have to activate it with "sudo
/usr/share/doc/libdvdread4/install-css.sh" in terminal) needs to
be installed. This is necessary for descrambling DVD. Somehow this
package was installed always automatically on my computer, so I
never checked the necessity of this Package (I had even forgotten the
existence of the package).
In the thirth tab you can start a window in which you can choose which audio track you want to extract from the DVD. It will be saved in the original format, no conversion will take place. The file will be saved in the original dts, ac3 or wav format. The program uses mplayer program to extract, so package mplayer must be installed. Most time it automatically can find the right location of the DVD.
Fourth tab:Added the ability to create and load a personalized version of the HRTF (head related transfer function). In the first version I had used a HRTF obtained from the Internet, randomly taken from a graphic found by coincidence. First version I had no big attention for an exact HRTF, because this would be a different function for every human and it is not easy to measure a personalized version of the HRTF. All listening with headphones sounds as if you were sitting with your back to the orchestra (a phenomenon normal for listening with headphone!). This problem should be caused by a not exactly correct HRTF, sadly this problem is not solved. I have tried versions with extra phase control and extra delay control, but this didn't solved it. The spreading of the sound over the space is now improved and it sounds more natural.
Delayfront: the delay caused by the longer distant from the left
front speaker to the right ear in comparison from the distance to the
left ear. 2.5e-4 seconds is 11 samples at 44100 samplingrate, and it
means 7.5 cm extra distant. I suggest not to change it, if to large
all the sounds seems to come from very near.
DelayBack: The
delay from the speaker on the left side to right ear in comparison to
the left ear. 6.12e-4 sec. Is 27 samples with 44100 samplingrate and
means 18 cm.
Beeplength:Length of the testbeep.
SampleFreq:
Sampling frequency of testbeep, not important.
Testlength:
Testbeep is repeated from left to right, this is the total length of
testsound.
The list headed “List of HRTF”: The actual HRTF
,first number is frequency, second number is the damp for the front
speakers, the third is the damp of the speakers on the right and left
side. Last frequency in list is always 24000 Hz, because DVD
recordings has a bandwidth of 24000 Hz .
The list headed
“Testfreq Width”:First number is frequency of testbeep, second
number is bandwidth of testbeep. More frequencies (lines) are
possible. I suggest to keep a bandwidth of 1 hz and only one
frequency.
HalfPulse checkbox:gives testbeep sharp attack, only
use it in final testing because it increases bandwidth
Nameof:Here
you can choose a name for the HRTF
Use headphone, push button “Test Front Audio”. If adjustment
is correct, the sound you hear should originated from speakers at an
angle of 30 degrees behind of you. If the sounds seems to come more
from the center, you had to make the second number for that frequency
in the HRTF list smaller. If the sound seems to come from to far
sideways, you have to make it larger. Repeat this for every frequency
in the HRTF list. If necessary add extra frequencies to the list. The
test signal should sound symmetrical. At frequencies between 1000 HZ
and 4000Hz something strange could happen. For my ears the test
signal was not longer symmetrical. This was caused by a wrong HRTF
for this frequency. The delay leads to another sound direction than
the information of the damping. The brain could not solve this
sound-image and comes for every ear with a different solution.
Adjusting the level of damping to the right HRTF level made this more
symmetrical, because the information from delay and the information
of damping are no longer conflicting. Exactly this is the reason for
creating your own HRTF, and why headphone listening with the
sound-processing from this program is more pleasant.
With “Test
Side Audio” button the testbeep should become from your side. First
try to make the number of the last column for the testfreq larger. If
the sound seems to come from a point not exactly from the side (more
centered) then make this number again smaller. Find this boundary. If
you make it to small the origin seems to getting to close to your
head, and this is difficult to hear from the test signal. (These
numbers are not used with stereo recordings, only DVD has this
channels). Repeat this for all the frequencies in the HRTF list.
Test
both buttons for all frequencies again with the “HalfPulse
checkbox” checked.
In the list of test frequencies you can set
the testfrequency, The second number is the bandwidth of the
testfrequency. The testfrequency is generated by filtering a delta
function or white noise width the bandwidth. The source is chosen by
checkbox "white noise".
Save the result with the
“save file” button. If saved with the name”default.hrtf” in
the home directory, the HRTF will be automatically loaded every time
with the start of program.
The examples are just from stereo recordings, because it should be royalty free. The best quality should come from DTS recordings. The recording(Example1) is made with Hydrogen drumcomputer, just the stick and the kick moving from left to the right. The original sound as if the first hit comes from a point near your left ear, the next from an unclear point in the middle, the last from a point near the right ear. The converted file sounds as if the instrument made a normal trajectory. The most extreme positioning (absolutely left or right) doesn't come from a point near to your ear. The converted to binaural audio examples sound much more natural. The original versions sound annoying if listened with headphone. Sometimes it sounds as 2 mono signals. A more extreme example is Example2, Noise on one channel. In the original, the sound originate in your ear and is totally unnatural. The converted version sound as if its originate of a speaker at an angle of 30 degrees right behind you, and is much natural. It is still coming from behind you, but nicely placed in space. At home I listen only to converted recordings with headphone because I find it more pleasant. If the original was a 5.1 recording the binaural converted recording should sound much wider. There exists a version of "Aero" of Jean Michel Jarre specified as a "Dolby headphone" version. I think for making this, they used a similar process. I thought my version from ripping the DVD sounds better.
Example1: Original and Converted Binaural
Example2 (Extreme example):Original and converted Binaural
For the same effect I have created a LADSPA (experimental) filter version. In goes the normal stereo or 5.1 version, out comes a version adapted for listening with headphone. Windows version is 32bits also working in windows 64 bits. For working with Audacity, place the stereotobinaural.dll file in the directory “C:\Program files(x86)\Audacity\Plug_Ins” . Enable it in the Effect menu. The effect is now visible as “stereo to binaural”. In Linux, just double click the deb installation file. For visibility in Audacity, enable it in the Effect menu. In OSX place the libstereotoheadphone.so in the directory "Application/Audacity/Plug-Ins". For visibility in Audacity, enable it in the Effect menu. The effect is now visible as “stereo to binaural”.
Updated 11 july 2018:(Linux)Dependencies libav-tools and libqt4pas5 removed because not available in modern repository of Linux Mint.
Updated 14 august 2018:(Linux,Windows)Added support for DSF and DFF files (from Super Audio CD's)
Updated 07 july 2019:(Linux,Windows)Added support for not only stereo and 5.1, but also every format between (like 5.0)
Update 05 august 2019: Added support for sofalizer from ffmpeg. For experimenting with sofa files. First try, I found ClubFritz1.sofa gives a good result. I tried with ClubFritz6 and ClubFritz11 with gives distortion. I tried dtf_nh2.sofa which gives a result without frequencies below 300Hz. So be careful which sofa files you choose. Solved: problem was with type=time, now use type=freq option.
Update 07 september 2019:added support for opus format, import and export.
Update 05 november 2019:Open dialog has now support for multiple file selection. Multiple files or all files in map can now be converted in one batch.
Update 01 January 2020 Created OS X version. Tested in Mojave.
Update 11 July 2020: Deb installation wouldn’t install on last Mint version (20 and probably Ubuntu20). There was a problem with libdvdread4 dependencies (moved to libdvdread7). Updated dvdtohp3_4_1 Linux versions.
Update 21 May 2021:Added audio extraction from files like mp4, vob, webm and iso. Version 3.5
Update 1 July 2021:More stable version 3.5.2
Update 16 August 2021: Command line interface (only the conversion part)
Update 09 October 2022:3.5.3 version, Length of audiostreams of DVD is shown in DVD ripping section.
Download address for sofa files
Download dvdtohp3.5.3 Windows and Linux version with all dependencies
Download dvdtohp3_5_2 Windows, Linux and OSX version with all dependencies
Download dvdtohp3.5.3_amd64.deb GUI version.
Download dvdtohp3_5_2_amd64.deb GUI version.
Download dvdtohp3_5_2_OSX_x86_64.zip
Download dvdtohpcli1_1_1_amd64.deb CLI Linux version (usage: dvdtohpcli --help).
Download VST plugins for Windows.
Download LADSPA and VST
plugins for Linux
The Windows version uses ffmpeg.exe, mplayer.exe, sox.exe,
lame.exe and flac.exe. They are all placed in the download file
because their locations and versions are more controllable. Downloads
and info of the used programs are on the next websites.
Download location for ffmpeg (ffmpeg.exe)
Download location for mplayer.exe (I used the generic version)
A location to download lame.exe
The OS X version uses ffmpeg, mplayer. They are all placed in the download file because their locations and versions are more controllable. Downloads and info of the used programs are on the next websites.
Download location for ffmpeg (ffmpeg)
With use of mfcuk, mfoc and nfc-mfclassic you can make a copy of Mifare classic 1k cards. Even if you don’t know all the keys. These programs make use of a weakness in the design of the card.
The ufr Classic from D-Logic isn’t capable of this. A disadvantage. A simple copy of a Mifare card with an unknown key is impossible. But Mifare Classic tool (for android)uses a different approach. It don’t use the weakness in design, but the laziness of the users of the cards. The 6 bytes keys gives 2^48 possible values. They seem to use only a few. Just try to use keys from a key list until you get a positive result. My program uses this approach.
The program can’t copy the manufacturer block/UID. It is a limitation from the device or driver. And to be fair, it is not in the specification of the Mifare Card. It is a hack. But the device can check if the card UID is changeable. That’s also not in the specification. And Mifare Classic tool has also problems copying the 0 block.
If you need to make such a copy: This program can copy the content to file in the format used by mfcuk, mfoc and nfc-mfclassic.
And you will need a special ‘Magic’ Chinese Mifare card.
The DL533N device from D-Logic is capable for copying the manufacturer block.
Linux:
The program is expecting the libuFCoder-x86_64.so driver on location '/usr/local/lib/libuFCoder-x86_64.so'. The same location I installed the FTDI drivers.
D-Logic is a little unclear on the right location of the driver. You can make a copy there or the program will ask you, every time the program starts, the location.
Windows:
libuFCoder-x86_64.dll driver is and should be in same directory of program.
Last update 23 may 2024
Download linux version ufr_Bold 0.5.0
Download Windows version ufr_Bold
A graphical interface for cdparanoia. The program gets CD info
with abcde, if it is not on the CDDB server it search for CD text
info with cd-info from package libcdio-utils and compresses the
ripped audio file with LAME to mp3 or with flac to flac files. It
automatic places the cd info in the mp3 file. While ripping a new
track it compresses at the same time the previous ripped tracks,
making use of more cores of the processor. If there were any errors
during ripping it displaces the errors location in a clear way. The
messages of cdparanoia aren’t always that clear. The button "Rip
Cd to Headphone audiofile" rips the whole Cd in one file and
also creates a binaural soundfile for headphone( see DVDtoHP). This
is my personal favorite button.
Linux Ubuntu or Mint deb installation file 64 bit Download
Small screen images
Large screen image
Iaddi (1+1 in letters) Calculator with text input, 3 variables.
Calculates numerical integration and numerical differentiation.
Creates a graphic of the function. Does not need any permissions.
Functions: *, / , + , - , ^ ( power of), sin(), cos(), tan, asin,
acos, atan, sinh, cosh, tanh, asinh, acosh, atanh, sqr, sqrt, exp,
ln, log, abs, rnd, random, rndg (random met Gaussian distribution),
cot, csc, sec, acot, acsc, asec, coth, csch, sech, acoth, acsch,
asech, sign, round, torad (from degree to rad), todegr (from rad to
degree).
Boundaries for drawing graphic and
integration can be given by using Start x, End x, start y and end
y.
If start x and end x are the same, the
boundaries for y are calculated automatically.
If start y and end y are the same, the boundaries for y are
calculated automatically.
Warning:Integration can not recognize singularities, input
of infinity is not possible. When a graphic with a singularity is
drawn it is necessary to restrict the y boundaries by fill in start y
and end y
Updated 17 November 2022:checked for latest android.
Download android version iaddi_android
A send in letter from me was publicized in the Dutch magazine “Elektuur” January 2001. This letter regards the recording quality of cd's, especially about clipping. On the Internet I found there where a few translations or summarizing in German ,French and English. Recently I found a few references in Germany to this letter. That's why I placed the original letter and English translation on this site.
Dear Editor — roughly a year ago you had an article in Elektor Electronics about CDs that were supposedly recorded with overdriven signals. An oscilloscope was used to look at the outputsignal of a CD player playing Jean Michel Jarre’s ‘Oxygen 7- 13’. It was clear that the peaks of the waveform were flat where the signal was greater than what could be reproduced by the CD. This is also known as clipping. Using an oscilloscope in this way can’t really tell us how much the CD player affects the signal quality. Between the CD and oscilloscope will be an oversampling digital filter, a digital-to-analogue converter and finally an analogue filter. The most accurate way to check a CD is to extract the track digitally and store it as a WAV file. This will be an exact digital copy of the CD, assuming there were no read errors. The creation of the WAV file shouldn’t be a problem since it is a function that is found in most current CD ‘rippers’. A computer program can then be used to analyse the contents of this WAV file. A WAV file consists of a header followed by the thousands of samples that make up the digitised sound. The 16-bit format used on CDs gives these samples a range from -32768 to 32767. In order to have a closer look at these WAV files I have written a program that can analyse them. As the first step, the program creates a histogram of the WAV file. This counts how often each sample value occurs in the WAV file, and gives a display as shown in Figure 1.
Figure 1
The values near zero occur most often; the more you go to the extremes of –32768 and 32767, the less often they occur. If there was any clipping at the recording stage, all strong signals will be rounded to the extremes of -32768 and 32767, which results in two peaks at the ends of the histogram. This way you can see if there is any clipping present and at what level (it is possible for it to occur at different values than -32768 and 32767, due to badly set up A/D converters). Next, the program displays the actual waveform stored in the WAV file. This window has a search facility that searches for clipping values, as determined by the previous histogram function. I have used this program to analyse the track “...Baby One More Time” by Britney Spears, from her CD “...baby one more time”. It was obvious that there was a lot of clipping in this track, but the display returned by the histogram was the most surprising. This is shown in Figure 2.
Figure 2
It contains the number of occurrences in the WAV file for samples with values from 4 to 515. After every two values that occur over a 1000 times, there follows a value that rarely or never occurs at all. You could only get such a histogram when a 16-bit recording is re-recorded after amplification by a factor of 1.5. Samples with values of 1, 2, 3, 4, 5, 6, 7 etc. are multiplied by 1.5 to give 1.5, 3.0, 4.5, 6.0, 7.5, 9.0, 10.5 etc. These values then have to be rounded to integers before being written to the CD. This gives the result 2, 3, 5, 6, 8, 9, 11 etc. You’ll see that every third value is missing from this series of numbers. By looking at the waveform where clipping occurs, it is possible to deduce by how much the recording of the CD was overdriven. I estimate this to be a factor of about 1.5. From this I conclude that the original mix, which was recorded perfectly, was remixed with an amplification of 1.5, causing clipping in the new recording. The track “Gloria, lonely boy” on the CD “Metamorphose” by Jean Michel Jarre was then analysed, in order to see if his latest CD had signs of clipping. Here too it seemed that the recording was overdriven. But once more it was the histogram that returned some fascinating information (Figure 3).
Figure 3
The smallest and largest samples found in the recording were -32022 and 32021 respectively (0.977 of the maximum range). These were also the levels at which clipping occurred. From the histogram it can be seen that every fortieth value is twice as large as its neighbours are. From these observations you can conclude that this CD is a remix of an original CD recording. The samples have been multiplied by 0.977 before being converted back into CD format. This raises the question why this meaningless conversion was carried out on the recording. The only reason I can think of is that the remix was made to hide the fact that the recording was overdriven. Anybody who uses an oscilloscope to look for clipping would set the trigger level at the largest possible signal level, about 99.9% of the maximum signal possible. The remix would cause the signal to remain below this level so the oscilloscope would never trigger and the clipping would remain undetected. The person making the remix would have known that clipping occurred and was determined to hide this fact. The correct procedure would have been to make a slightly softer remix from the master tape and avoid any clipping that way. The record industry is currently promoting the new Super Audio CD (SACD), which has an improved quality. They would be better off stopping the messing around with the recordings. These fudges also sound bad in SACD format and making careful recordings in CD format will result in bigger improvements than the change to SACD format.
A. Kappert, Deventer
Some people think that these results are caused by compression. But at making cd's, compression means reinforcing the weak passages, reinforcing the strong passages is not possible because these already reach their limit. With a sound editing program the wave shape can be examined. Here is the result made with the provided program of”… baby one more time” at the position 114.885 sec.
Figure 4
Every pixel to the right is a new sample. One of the channels shows clear clipping over a large length and in severe degree. The wave shape have been clearly damaged because of this. Compression will change the envelope of a signal but won't affect the shape. Long before the signal becomes to large the volume will be slowly turned down to prevent clipping. An estimation can be made over the original signal size,I estimate it 1.5 larger. Remains the question about why this signal is strengthens. It appears that by comparison of sound quality of Hi Fi signals, the first preference goes out to the strongest signal. Also at radio broadcasts, the recordings with the largest sound strength attract the most attention.
Figure 5
To addition in figure 5 “oxygen 7”of J. M. Jarre on 27.37 seconds. Here clearly the “saw tooth” is cut off, in this way losing a lot of harmonics in the sound. At “Methamorphoses” the signal appeared to be weakened with 2,5%. It appeared that cd mastering equipment is protected against clipping. To get around this protection, it is necessary to weaken the signal, but at that moment it is known that clipping occurred.
To Download ( updated ) analyse program (cdwavanalyse,windows 7, 32bits)
To Download ( updated ) analyse program (cdwavanalyse,linux Ubuntu or Mint, 64 bits deb)
Old windows version with only wav file support
To
Download analyse program (cdwavanalyse,windows, 32bits)
This program draws Mandelbrot fractals. With a left mouse click you can zoom in, with a right mouse click you can zoom out. It is possible to zoom in with factor 1E16.
For training Python programming I made a Python version of Mandelbrot program. I used numpy module for the calculation, Pil (or actually Pillow fork ) for the image building and PyInstaller for creating an one file executable. The best version I made was 2 times slower then the Lazarus (Free Pascal) version. But this version used multiprocessing, so actually it was 6 times slower. The multiprocessing module had problems after being processed by PyInstaller (strangely no problem in the uncompiled version). The python file needed an extra addition for the right form of spawning. Another problem was the inability to use a more precise version of float64 in Windows. Intel processors use internally float80. Free pascal has not a problem with this (extended type), so using the intel processor more efficient. Under Linux Mint I had to use float128, while internally the precision was only float80. A strange use of types? It makes it unclear what floating version to use and the actual precision version used.