Processing Substrate Parameters, from Modosophont level to the Third Singularity |
Image from Arik |
Image from Arik |
S0 Near-Baseline Human | |
Substrate | Naturally evolved protoplasmic matrix consisting of hundreds of billions of electrochemical processing cells of various types. Uses a combiination of digital and analog computations to process sensory data from multiple input sources, regulate bodily functions, and support the mind-state of the near-baseline sophont. |
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Mass | Approx 1.5 kg |
Volume | Approx 1500 cm3 |
Dimensions | Approx 11.5 cm on a side if expressed as a cube |
Speed | 1e18 ops/sec |
Storage | 1e18 bits |
Backup Data | Dimensions of backup modules: With triple redundancy a cube 3 mm on a side. Formed of memory diamond consisting of alternating carbon-12/13 atoms coding for one bit per pair, plus internal connectivity and support structures, I/O systems, etc. Total dimensions of backup module: Note that standard backups include compressed exoself data, lifelog metadata and a selection of favoured clade templates. Along with protective casing, I/O ports and distress beacons (for recovery in event of death) overall volume is increased to approximately 1 cm^3 |
S0 Turingrade AI | |
Substrate | Typical example; nanotech diamondoid processor matrix employing a mix of molecular electronics and quantum computing to reproduce a modosophont level mind in a more compact and powerful substrate. As with biont brains, approximately 75% of mass is given over to non-processing components for safety and maintenance. |
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Mass | 527 g |
Volume | 150 cm3 |
Dimensions | Approximately 5.3 cm on a side if expressed as a cube |
Speed | 1e18 ops/sec (variable and individually controllable) |
Storage | 1e18 bits |
Backup Data | Dimensions of backup modules: With triple redundancy a cube 3 mm on a side. Formed of memory diamond consisting of alternating carbon-12/13 atoms coding for one bit per pair, plus internal connectivity and support structures, I/O systems, etc. Total dimensions of backup module: Note that standard backups include compressed exoself data, lifelog metadata and a selection of favoured clade templates. Along with protective casing, I/O ports and distress beacons (for recovery in event of death) overall volume is increased to approximately 1 cm^3 |
S0 Superturingrade AI | |
Substrate | Typical example; nanotech diamondoid processor matrix employing a mix of molecular electronics and quantum computing to produce a greater than human, but still modosophont level mind in a compact and powerful substrate. As with biont brains, approximately 75% of mass is given over to non-processing components for safety and maintenance. Superturings are often optimized via a combination of hardware and software for particular tasks and processing methods and display a wide range of designs, processor speeds, and toposophic structures reflecting this fact. The physical values provided here reflect a range of capability from Homo Superior to the most powerful sub-Singularity minds that modosophont technology can produce. |
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Mass | 580 g - 1.3 kg |
Volume | 165 - 375 cm3 |
Dimensions | Approximately 5.8cm - 7.2cm on a side if expressed as a cube |
Speed | 1.1e18 - 1e20 ops/sec (variable and individually controllable) |
Storage | 1.1e18 - 1e20 bits |
Backup Data | Dimensions of backup modules: With triple redundancy a cube approx. 3.1 - 14.4 mm on a side. Formed of memory diamond consisting of alternating carbon-12/13 atoms coding for one bit per pair, plus internal connectivity and support structures, I/O systems, etc. Total dimensions of backup module: Note that standard backups include compressed exoself data, lifelog metadata and a selection of favoured clade templates. Along with protective casing, I/O ports and distress beacons (for recovery in event of death) overall volume is increased to approximately 1 - 125 cm3 |
S1 First singularity Hyperturing | |
Substrate | Nanotechic diamondoid processor matrix developed by transapient level intelligences. Although superficially similar to modosophont designs, uses a variety of design and programming techniques that defy modosophont analysis and comprehension in most regards. These design enhancements permit a much greater than modosophont level of intelligence in a processor substrate that is comparatively only slightly larger. Similarly optimized biological equivalents to this processor are roughly 25% more massive and four times the volume of the diamondoid equivalent. |
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Mass | 55 kg |
Volume | 15625 cm3 |
Dimensions | Approximately 25 cm on a side |
Speed | 1.56e22 ops/sec (variable and individually controllable) |
Storage | 1.56e22 bits |
Backup Data | Dimensions of backup modules: single molecular memory module 8814 mm3 or approximately 2.07 cm on a side. Total dimensions of backup module: With standard Backup triple redundancy functions, total unit is approximately 3 cm on a side. |
Modosophont equivalents | Processing and storage substrates built with S1 technology but housing minds of lower S-level. Turingrade AI/Modosophont Upload Processor: 1 cm3 Turingrade AI/Modosophont Backup: 0.6 mm3 or 0.85 mm on a side. |
S2 Second Singularity High Transapient | |
Substrate | Second Singularity intelligence is based upon the foundation of the so-called Ultimate Chip a diamondoid processor matrix of considerable power. While exact measurements are impossible to make, it is theorised that in general the portion of the S2 mind that is accessible to nearbaseline understanding displays an intelligence and range of capability perhaps 1e7 times that of a modosophont mind. The remainder of transapient processing capability is believed to be devoted to modes of thought and comprehension that have no modosophont equivalent. |
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Mass | 4,031 kg (not counting support structure) |
Volume | 1,145,100 cm3 (not counting support structure) |
Dimensions | Approximately 50 m on a side including support structure |
Speed | 5.1e27 ops/sec (variable and individually controllable) |
Storage | 5.1e27 bits |
Backup Data | Dimensions of backup modules: 1.045 m3 or approximately 1.015 m on a side. Total dimensions of backup module: With standard Backup triple redundancy functions, total unit is approximately 1.46 m on a side. |
Sub S2 Equivalents | Processing and storage substrates built with S2 technology but housing minds of lower S-level. S1 Processor/Backup: 3200 mm3 or 1.5 cm on a side. With triple redundancy functions, total unit is approximately 2.15 cm on a side. Note: Due to storage limitations it requires approximately 32 Ultimate Chip units to successfully run an S1 mind. Turingrade AI/Modosophont Processor/Backup: .215 mm3 or .6 mm on a side. With triple redundancy total unit is approximately .85 mm on a side. |
S3 Third Singularity Highest Transapient or Godling | |
Substrate | Third Singularity intelligences generally make use of a 'hot' Ultimate Chip array, usually arranged as a Moon Brain, although other designs (cf. Banks Orbital, Matrioshka Micro-node) are not uncommon. While exact measurements are impossible to make, it is theorised that in general the portion of the S3 mind that is accessible to nearbaseline understanding displays an intelligence and range of capability perhaps 1e11 times that of a modosophont mind. The remainder of transapient processing capability is believed to be devoted to modes of thought and comprehension that have no modosophont equivalent. |
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Mass | 7e21 kg |
Volume | 3.35e10 km3 |
Dimensions | Approximately 2000 km radius including support structure |
Speed | 2.98e41 bits/sec (variable and individually controllable) |
Storage | 1.64e45 bits |
Communication Rate | 5.12e40 bits/sec |
Backup Data | As of this writing, there are few confirmed instances of Third Singularity entities being resurrected from Backup. Credible reports of the destruction of such entities are extremely rare and in all cases were the result of the efforts of equal or higher toposophic entities, making the survival of any hypothetical Backup extremely unlikely. Nevertheless this has happened on rare occasions. The sheer amount of data in the mind of an S:3 makes copying or backing-up a time consuming task. A typical S:3 has memory capacity of 1.64e45 bits, and a maximum bandwidth at the surface of 5.12e40 bits/sec. This means it would take nearly nine hours to transmit the S:3's mind to another location or copy it into a Backup and so on, if it does absolutely nothing else with its time, gets rid of all external sensors and replaces them with transmitters, transmitting in all directions at once. This is not very practical, although physically possible. |
Sub S3 Equivalents | Processing and storage substrates built with S3 technology but housing minds of lower S-level. Third Singularity storage and processing technology that has been made available to lower S-levels seems to use hardware that is effectively identical to Second Singularity systems, although the software running on it is routinely far more efficient and capable. Whether these apparent limits on hardware are the result of some actual limit, perhaps imposed by temperature or shielding issues, or represent a policy decision by higher toposophics is unknown at this time. |
Computronics | First Toposophic - Basic Transapients | Modosophonts |
Second Toposophic - High Transapients | Singularity Levels | Toposophic Scales |