thanks to IrionDaRonin 
It can work either way. Sometimes pure maths does influence engineering. A lot of wireless communication systems rely on the maths of imaginary numbers. I could mention another more famous example but that would probably send the entire thread to HPC.whyterabbyt wrote:Indeed. I'd tend to see mathematics as a tool of analysis (with prediction and description both falling under 'analysis'). I don't necessarily see it as a tool of invention ("hey, I'm going to invent a replacement for the gas lamp, pass me my maths textbooks and i'll calculate up something based on hot bits of wire")spaceman wrote:If it were the case, then I would definitely be very interested to find out who formulated it and for what reason. I always thought mathematics worked in the opposite direction.
It may influence engineering but I can't think of many(or any) cases where it was the model for an invention. It's not as if the engineer looked at imaginary numbers and then decided to do build a communications network that models them.Gamma-UT wrote: It can work either way. Sometimes pure maths does influence engineering. A lot of wireless communication systems rely on the maths of imaginary numbers. I could mention another more famous example but that would probably send the entire thread to HPC.
No problem. I agree with your definition - emulation obviously implies intent.whyterabbyt wrote:Do you need it rephrased or something?hakey wrote:Intent = "nebulous shite"?whyterabbyt wrote:Emulating something has an intrinsic notion of intent.
Emulation is specifically deliberate, copying can be accidental. Does that help with your problem?
I think I see where we were not communicating. You are parsing the words down far to low a level. This is a discussion of ANALOG vs DIVA. It is also, a bit tongue in cheek.Aroused by JarJar wrote:..It's just an example of how the idea that digital synthesis amounts to putting analog circuits into code is false.
Both digital and analog synthesis are ultimately "emulations" of "real" synthesis, which is abstract (mathematical).
The original idea was to get rid of the filter IIRC. Analog filters are expensive and if you can replace that with scanning thru a table of increasingly filtered waveforms you could build a cheaper synth. Not that PPGs were ever cheap but i believe that was the general idea to begin with. Turns out it wasn't such a good idea as it initially seemed as they added filters to later models..whyterabbyt wrote:What 'abstract mathematical' synthesis does a PPG-style scanned wavetable 'emulate,' then, for example?Analog and digital synthesizers are both imperfect "emulations" of abstract mathematical synthesis.
When Hancock and Lucky and others developed quadrature amplitude modulation the hardware didn't exist that could implement it - it was about a decade later that anyone started building on their entirely theoretical work. The Viterbi algorithm - used by every cellphone in production and in DSL modems - was developed in 1967 to "help prove an asymptotically optimum upper bound on the error probability of convolutional codes" (The Viterbi Algorithm: A Personal History, G David Forney, http://arxiv.org/pdf/cs/0504020v2.pdf). Again, it took years before it was use in real-world systems. Andrew Viterbi did later cofound Qualcomm and make a ton of money out of it.spaceman wrote:It may influence engineering but I can't think of many(or any) cases where it was the model for an invention. It's not as if the engineer looked at imaginary numbers and then decided to do build a communications network that models them.Gamma-UT wrote: It can work either way. Sometimes pure maths does influence engineering. A lot of wireless communication systems rely on the maths of imaginary numbers. I could mention another more famous example but that would probably send the entire thread to HPC.
It's really good for making a product popular. When I saw this thread "Diva Vs. Real Analog" with 65 pages, my first thought was: Wow, it must sound pretty darn analog if it takes people 65 pages of discussion to figure out how close it is 
But doesnt that paper state the opposite in places; that the applications came after the theory, that the theory wasn't developed with the purpose of creating a new invention.Gamma-UT wrote:The Viterbi algorithm - used by every cellphone in production and in DSL modems - was developed in 1967 to "help prove an asymptotically optimum upper bound on the error probability of convolutional codes" (The Viterbi Algorithm: A Personal History, G David Forney, http://arxiv.org/pdf/cs/0504020v2.pdf). Again, it took years before it was use in real-world systems. Andrew Viterbi did later cofound Qualcomm and make a ton of money out of it.
the Viterbi algorithm for convolution codes... came out of my teaching... I found information theory difficult to teach so I started developing my tools...
Nobody though that it had any potential for practical value
Andy has always said that Jerry heller was the first person to realize that the VA might be practical.
It does appear as if he did say both things in that paper. I'm wondering if he actually did intend that though or was it some kind of mistake though.whyterabbyt wrote:But doesnt that paper state the opposite in places; that the applications came after the theory, that the theory wasn't developed with the purpose of creating a new invention.Gamma-UT wrote:The Viterbi algorithm - used by every cellphone in production and in DSL modems - was developed in 1967 to "help prove an asymptotically optimum upper bound on the error probability of convolutional codes" (The Viterbi Algorithm: A Personal History, G David Forney, http://arxiv.org/pdf/cs/0504020v2.pdf). Again, it took years before it was use in real-world systems. Andrew Viterbi did later cofound Qualcomm and make a ton of money out of it.
"the Viterbi algorithm for convolution codes... came out of my teaching... I found information theory difficult to teach so I started developing my tools""Andy has always said that Jerry heller was the first person to realize that the VA might be practical."
Either way it is a good read. 
Actually, that was the point I was making: that the application came out of the maths rather than someone using maths to work out whether some real-world approach was plausible. The Viterbi one is arguably a funny example as the same person devised the theory and then managed to apply it.whyterabbyt wrote:But doesnt that paper state the opposite in places; that the applications came after the theory, that the theory wasn't developed with the purpose of creating a new invention.Gamma-UT wrote:The Viterbi algorithm - used by every cellphone in production and in DSL modems - was developed in 1967 to "help prove an asymptotically optimum upper bound on the error probability of convolutional codes" (The Viterbi Algorithm: A Personal History, G David Forney, http://arxiv.org/pdf/cs/0504020v2.pdf). Again, it took years before it was use in real-world systems. Andrew Viterbi did later cofound Qualcomm and make a ton of money out of it.
the Viterbi algorithm for convolution codes... came out of my teaching... I found information theory difficult to teach so I started developing my tools...Nobody though that it had any potential for practical valueAndy has always said that Jerry heller was the first person to realize that the VA might be practical.
ah, sorry. too much multitasking on my part, losing track.Gamma-UT wrote: Actually, that was the point I was making: that the application came out of the maths rather than someone using maths to work out whether some real-world approach was plausible.
Felt is wool... wool is static electricity-o-rama. Might not be the best choice for electronics?AdmiralQuality wrote:I think felt would probably be a more appropriate material here than either the original foam, or leather
But if I'm allowed to be a bit pedantic here, the algorithms in question serve a bigger system. No one ever built a quadrature amplitude modulator for the sole purpose of modulating quadrature amplitudes. Again, its processing serves a bigger system and a more complex problem. Whereas someone here tried to imply that sound synthesis was entirely based on maths conceived with the sole purpose of synthesising sound.Gamma-UT wrote: Actually, that was the point I was making: that the application came out of the maths rather than someone using maths to work out whether some real-world approach was plausible. The Viterbi one is arguably a funny example as the same person devised the theory and then managed to apply it.
Wool itself tends not to accumulate a static charge as it's strongly hygroscopic -- it absorbs water from the air, and being made of fibers wool has a huge surface area. The thin coating of moisture on wool fibers conducts away and dissipates static.zerocrossing wrote:Felt is wool... wool is static electricity-o-rama. Might not be the best choice for electronics?AdmiralQuality wrote:I think felt would probably be a more appropriate material here than either the original foam, or leather
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