On Fri, 22 Jun 2007 14:28:57 +0200, "Martin Blume" <mblume@socha.net>
wrote:
>"Rune Allnor" schrieb
>> >
>> > > Oh, and the Love waves.
>> >
>> > Love waves, sounds great.
>> > We should have more of those.
>> >
>> > SCNR
>> > Martin
>>
>> No, one would probably not want any more of those
>> around than are already there.
>>
>> The Love waves makes the earth move beneath you.
>> These are transversal shear surface waves that belong
>> to the class of waves which makes people see stars
>> -- mainly because the houses fall down around
>> (or on top) of them.
>>
>Well, these are definitely not those I had in mind.
>Thanks for the explanation.
>
>Martin
Maybe it was...remember the Carol King song:
I feel the earth move under my feet
I feel the sky tumbling down, tumbling down
I feel my heart start to trembling
Whenever you're around
Love waves, baby... ;)
Eric Jacobsen
Minister of Algorithms
Abineau Communications
http://www.ericjacobsen.org
Reply by Scott Seidman●June 22, 20072007-06-22
"Martin Blume" <mblume@socha.net> wrote in news:467bd7d2$0$3790
$5402220f@news.sunrise.ch:
> "Scott Seidman" schrieb
>>
>> > In what respect do the earlaps enable elevation detection?
>> > I think that (at least mammal) ears are geared towards
>> > detection of sound
>>
>> The pinna creates notches in the spectrum. The notches move
>> around with the elevation of the noise source, so a notch detector
>> will correlate with elavation.
>>
> "The notches move around with elevation" -- but only with a moving
> source? So you need a moving source or you need to move your head.
>
> Thanks to Scott and Paul for the explanations of the pinna.
>
> Martin
>
>
>
Nope-- you don't need a moving source, but you need a source with some
spectrum width to it-- you can't identify a notch in a pure tone. The
brain, over the course of time, learns what frequencies are missing at what
elevation. Auditory localization in elevation isn't as good as in azimuth,
psychophysically.
--
Scott
Reverse name to reply
Reply by Martin Blume●June 22, 20072007-06-22
"Scott Seidman" schrieb
>
> > In what respect do the earlaps enable elevation detection?
> > I think that (at least mammal) ears are geared towards
> > detection of sound
>
> The pinna creates notches in the spectrum. The notches move
> around with the elevation of the noise source, so a notch detector
> will correlate with elavation.
>
"The notches move around with elevation" -- but only with a moving
source? So you need a moving source or you need to move your head.
Thanks to Scott and Paul for the explanations of the pinna.
Martin
Reply by Jerry Avins●June 22, 20072007-06-22
Eric Jacobsen wrote:
> On Thu, 21 Jun 2007 22:10:56 -0400, Jerry Avins <jya@ieee.org> wrote:
>
>> Eric Jacobsen wrote:
>>> On Thu, 21 Jun 2007 17:09:07 GMT, Richard Dobson
>>> <richarddobson@blueyonder.co.uk> wrote:
>>>
>>>> Sylvia wrote:
>>>>
>>>>> I meant two microphones that are inline horizontally(not vertically).i can
>>>>> ofcourse do azimuth detection by using ITD etc.if elevation detection
>>>>> cannot be done with this scenario,what additional info is required to do
>>>>> elevation detection?
>>>> Well, if you use a Soundfield microphone, you can do it with one of
>>>> them! Its actually four capsules internally - one omni (W) fort the
>>>> pressure component, three fig-8s for velocity (XYZ, where Z is height
>>>> component), in a tetrahedral configuration. the idea is to capture the
>>>> full periphonic soundfield at a point, so the capsules have to be as
>>>> close together as possible. I suppose if you are not interested in X or
>>>> Y (which are in effect a "mid+side" pair), you just need capsules for W
>>>> and Z ("mid+height"?). There is a lot of interest these days in
>>>> higher-order microphones (4 capsules = first-order), which in theory
>>>> give much better localisation. Making them is another matter, needless
>>>> to say.
>>>>
>>>> Worth asking on the sursound list, lots of experts in Ambisonics, etc.
>>>>
>>>> Richard Dobson
>>> That sounds like the acoustic equivalent of a monopulse radar. It's
>>> still a multi-sensor array, it's just arranged efficiently so that
>>> simple algorithms can be used.
>>>
>>> In radar, the idea is that a flat-plate antenna (or similar) is
>>> divided up into four quadrants, so that there are top and bottom
>>> halves, and left and right halves, that can be summed and differenced
>>> independently.
>>>
>>> The sum of all four quadrants makes the usual directive beam with a
>>> sinx/x sidelobe pattern in both azimuth and elevation. A
>>> "difference" beam, with a cosine response across azimuth, i.e., a
>>> "positive" lobe on one side and a "negative" lobe on the other
>>> (phase-wise), is created by taking the difference of the signal in the
>>> two received halves. Then taking the ratio of what is received in
>>> the sum and difference beams gives a nice mono-pulse imaging system in
>>> essentially three dimensions, since the radar can also provide range
>>> information and can discrimate location between the left and right
>>> halves and the top and bottom.
>>>
>>> Since the cosine response crosses zero at the boresight, the ratio of
>>> the sum beam to the difference beams peaks there. This makes it
>>> great for fire-control radar where you really just want to be able to
>>> steer so that the target stays in the boresight.
>>>
>>> I don't know why doing the same wouldn't work acoustically, assuming
>>> the sensor mechanics work out reasonably well.
>> Sylvia asked for two microphones, not two microphone stands. Can I aim a
>> laser beam to center on a photocell? Sure, if I use a four-quadrant
>> device. Does that meet the problem statement? Ask Sylvia.
>>
>> Jerry
>
> But he clarified that the two microphones are on a horizontal line, so
> some non-spatial technique must be used to get elevation resolution.
>
> Richard described a possible technique using an unusual microphone and
> I was just responding that there may be a related, fairly simple,
> signal processing technique to go with it.
>
> It's kind of related to the mention of the penna in the ear, I think,
> i.e., using a co-located sensor system to discriminate direction.
That's why I suggested considering microphones of differently varying
frequency response depending on source altitude. You and I would
probably make them by combining the outputs of differently baffled
microphones possibly with differently filtered outputs, but only because
we don't know a better way. I have a feeling that in the end, only two
signals are to be delivered for analysis.
Jerry
--
Engineering is the art of making what you want from things you can get.
¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯¯
Reply by Martin Blume●June 22, 20072007-06-22
"Rune Allnor" schrieb
> >
> > > Oh, and the Love waves.
> >
> > Love waves, sounds great.
> > We should have more of those.
> >
> > SCNR
> > Martin
>
> No, one would probably not want any more of those
> around than are already there.
>
> The Love waves makes the earth move beneath you.
> These are transversal shear surface waves that belong
> to the class of waves which makes people see stars
> -- mainly because the houses fall down around
> (or on top) of them.
>
Well, these are definitely not those I had in mind.
Thanks for the explanation.
Martin
Reply by Scott Seidman●June 22, 20072007-06-22
Paul Russell <prussell@sonic.net> wrote in news:5e1kioF36oe2mU1
@mid.individual.net:
> f you then amputate your pinnae you will find that
> you will no longer be able to do this.
>
You'll still do fairly well in azimuth, but not in elevation.
--
Scott
Reverse name to reply
Reply by Scott Seidman●June 22, 20072007-06-22
"Martin Blume" <mblume@socha.net> wrote in news:467b92b5$0$3783
$5402220f@news.sunrise.ch:
> In what respect do the earlaps enable elevation detection?
> I think that (at least mammal) ears are geared towards detection of
> sound
The pinna creates notches in the spectrum. The notches move around with
the elevation of the noise source, so a notch detector will correlate with
elavation.
--
Scott
Reverse name to reply
Reply by Paul Russell●June 22, 20072007-06-22
Martin Blume wrote:
> "Paul Russell" schrieb
>>> i require links about sound elevation detection algorithms using
> only
>>> two microphones.i will appreciate any
> references,papers,algorithms etc.
>> This is why humans and other animals have pinnae - they enable us
> to
>> localise sound from all directions.
>>
> In what respect do the earlaps enable elevation detection?
> I think that (at least mammal) ears are geared towards detection of
> sound
> in a plane (earth surface) and are slightly suboptimal for detection
> of sound
> coming from above (birds) or below (moles).
> AFAICT, Human ears have a reception diagram that is maximized in
> the
> bore sight of vision. Sidewards and behind, there is detection, but
> not
> accurate localization. In order to localize better, you'll have to
> turn your head.
> Having turned the head, you may also see what the sounds represents.
> You may also turn your head upwards to get a better estimation of
> the heght
> of the dragon approaching you.
>
> It is interesting to note that some animals can turn their ears.
> Turning the ear
> (a) amplifies the sound coming from that direction, enhancing the
> sensitivity
> and (b) enables better direction finding due to (probably, I guess
> here)
> already knowing the angle of the ear and using the enhanced
> sensitivity.
>
> But I believe that this sensitivity is essentially planar.
>
Try closing your eyes and keeping your head still and listen to the
sounds around you - you should be able to localise sounds both
front-back and up-down, in addition to basic localisation in a
horizontal plane. If you then amputate your pinnae you will find that
you will no longer be able to do this.
Paul
Reply by Richard Dobson●June 22, 20072007-06-22
Martin Blume wrote:
..
>
> In what respect do the earlaps enable elevation detection?
> I think that (at least mammal) ears are geared towards detection of
> sound
> in a plane (earth surface) and are slightly suboptimal for detection
> of sound
> coming from above (birds) or below (moles).
I think "slightyly suboptimal" is probably about right - there
definnitely is a degree of elevation detection, at least in the
relatively near field. It is based on each brain learning the behaviour
of the particular ears connected to it. This is all covered by the topic
of Head-Related Transfer Functions (HRTF, q.v.). Some success has been
had synthesizing general HRTFs such that listening to binaural
recordings over headphones successfully gives the impression of elevated
positions. Typcically the main problem in these cases is front/rear
ambiguity. However, when in-ear recordings are made, and then played
back via headphones on those same ears (so the HRTF's correspond
exactly) the illusion is, apparently, virtually total. So there is a
general form of HRTF that works ~quite~ well for lots of people, and a
personal HRTF (ostensibly as unique as a fingerprint) that works a whole
lot better for that individual.
Of course, microphones such as the Soundfield do not deal with HRTFs at
all, they try to record the whole 3D soundfield at that point. The
recording has to be played back ("decoded" from B-format) using a
precisely arranged (preferably regular) array of speakers (e.g minimum
square for horizontal, cube for periphonic, but more is better), in
order to reconstruct the original soundfield which we can then listen to
as if we were there. The tricky part is getting the "sweet spot" where
this all works, to be of a reasonable size.
We now have a wikipedia on Ambisonics:
http://en.wikipedia.org/wiki/Ambisonics
Richard Dobson
Reply by Rune Allnor●June 22, 20072007-06-22
On 22 Jun, 11:16, "Martin Blume" <mbl...@socha.net> wrote:
> "Rune Allnor" schrieb
>
> > Oh, and the Love waves.
>
> Love waves, sounds great.
> We should have more of those.
>
> SCNR
> Martin
No, one would probably not want any more of those around
than are already there.
The Love waves makes the earth move beneath you. These are
transversal shear surface waves that belong to the class of
waves which makes people see stars -- mainly because the
houses fall down around (or on top) of them.
Rune