Analysis of information sources in references of the Wikipedia article "Algorithmic state machine" in English language version.
The second annual IEEE Workshop on Microprocessors (now called the Asilomar Microcomputer Workshop, or AMW) was held Wednesday–Friday, April 28–30, 1976, near Monterey, California […] My Wednesday evening talk described tools that enabled a very different design methodology—Algorithmic State Machine design (ASM)—using Lyapunov state-variable mathematics, and derivative techniques pioneered at HP by Chris Clare and Dave Cochran for the spectacularly successful handheld scientific calculators (e.g., HP 35) […] My point: circuit design was no longer an element-by-element issue, but a question of "state flow" at lots of nodes—the sequential "words" of registers rather than the voltages of device pins. In effect, it argued that electronic voltages, whether analogic or switched, would "lose out" to software instructions, and "data states." Systems would be designed and analyzed for proper state sequencing rather than analogic signal distortion or digital switching times. […] I'd already seen the power of pre-publication books. Clare's insightful ASM methodology text, Designing Logic Systems Using State Machines, swept through the HPdesign community […] Stanford's electrical engineering department was not so sanguine, however, canceling Clare's course in 1974, saying that "it is a little bit too unconventional" […] Stanford preferred Quine–McCluskey minimization techniques. Fittingly, Mead's Caltech colleague Ivan Sutherland prepared a Scientific American article (1977) […] about the challenge microelectronics posed to computing theory and practice, noting that since most of a chip's surface was occupied by "wires" (conducting pathways) rather than "components" (transistors), decades of minimization theory in logic design had become irrelevant […](4 pages)
The second annual IEEE Workshop on Microprocessors (now called the Asilomar Microcomputer Workshop, or AMW) was held Wednesday–Friday, April 28–30, 1976, near Monterey, California […] My Wednesday evening talk described tools that enabled a very different design methodology—Algorithmic State Machine design (ASM)—using Lyapunov state-variable mathematics, and derivative techniques pioneered at HP by Chris Clare and Dave Cochran for the spectacularly successful handheld scientific calculators (e.g., HP 35) […] My point: circuit design was no longer an element-by-element issue, but a question of "state flow" at lots of nodes—the sequential "words" of registers rather than the voltages of device pins. In effect, it argued that electronic voltages, whether analogic or switched, would "lose out" to software instructions, and "data states." Systems would be designed and analyzed for proper state sequencing rather than analogic signal distortion or digital switching times. […] I'd already seen the power of pre-publication books. Clare's insightful ASM methodology text, Designing Logic Systems Using State Machines, swept through the HPdesign community […] Stanford's electrical engineering department was not so sanguine, however, canceling Clare's course in 1974, saying that "it is a little bit too unconventional" […] Stanford preferred Quine–McCluskey minimization techniques. Fittingly, Mead's Caltech colleague Ivan Sutherland prepared a Scientific American article (1977) […] about the challenge microelectronics posed to computing theory and practice, noting that since most of a chip's surface was occupied by "wires" (conducting pathways) rather than "components" (transistors), decades of minimization theory in logic design had become irrelevant […](4 pages)
The second annual IEEE Workshop on Microprocessors (now called the Asilomar Microcomputer Workshop, or AMW) was held Wednesday–Friday, April 28–30, 1976, near Monterey, California […] My Wednesday evening talk described tools that enabled a very different design methodology—Algorithmic State Machine design (ASM)—using Lyapunov state-variable mathematics, and derivative techniques pioneered at HP by Chris Clare and Dave Cochran for the spectacularly successful handheld scientific calculators (e.g., HP 35) […] My point: circuit design was no longer an element-by-element issue, but a question of "state flow" at lots of nodes—the sequential "words" of registers rather than the voltages of device pins. In effect, it argued that electronic voltages, whether analogic or switched, would "lose out" to software instructions, and "data states." Systems would be designed and analyzed for proper state sequencing rather than analogic signal distortion or digital switching times. […] I'd already seen the power of pre-publication books. Clare's insightful ASM methodology text, Designing Logic Systems Using State Machines, swept through the HPdesign community […] Stanford's electrical engineering department was not so sanguine, however, canceling Clare's course in 1974, saying that "it is a little bit too unconventional" […] Stanford preferred Quine–McCluskey minimization techniques. Fittingly, Mead's Caltech colleague Ivan Sutherland prepared a Scientific American article (1977) […] about the challenge microelectronics posed to computing theory and practice, noting that since most of a chip's surface was occupied by "wires" (conducting pathways) rather than "components" (transistors), decades of minimization theory in logic design had become irrelevant […](4 pages)
The second annual IEEE Workshop on Microprocessors (now called the Asilomar Microcomputer Workshop, or AMW) was held Wednesday–Friday, April 28–30, 1976, near Monterey, California […] My Wednesday evening talk described tools that enabled a very different design methodology—Algorithmic State Machine design (ASM)—using Lyapunov state-variable mathematics, and derivative techniques pioneered at HP by Chris Clare and Dave Cochran for the spectacularly successful handheld scientific calculators (e.g., HP 35) […] My point: circuit design was no longer an element-by-element issue, but a question of "state flow" at lots of nodes—the sequential "words" of registers rather than the voltages of device pins. In effect, it argued that electronic voltages, whether analogic or switched, would "lose out" to software instructions, and "data states." Systems would be designed and analyzed for proper state sequencing rather than analogic signal distortion or digital switching times. […] I'd already seen the power of pre-publication books. Clare's insightful ASM methodology text, Designing Logic Systems Using State Machines, swept through the HPdesign community […] Stanford's electrical engineering department was not so sanguine, however, canceling Clare's course in 1974, saying that "it is a little bit too unconventional" […] Stanford preferred Quine–McCluskey minimization techniques. Fittingly, Mead's Caltech colleague Ivan Sutherland prepared a Scientific American article (1977) […] about the challenge microelectronics posed to computing theory and practice, noting that since most of a chip's surface was occupied by "wires" (conducting pathways) rather than "components" (transistors), decades of minimization theory in logic design had become irrelevant […](4 pages)
