SUPS

In computational neuroscience, SUPS (for Synaptic Updates Per Second) or formerly CUPS (Connections Updates Per Second) is a measure of a neuronal network performance, useful in fields of neuroscience, cognitive science, artificial intelligence, and computer science.

Computing

For a processor or computer designed to simulate a neural network SUPS is measured as the product of simulated neurons $N$ and average connectivity $c$ (synapses) per neuron per second:

$SUPS = c \times N$

Depending on the type of simulation it is usual equal to the total number of synapses simulated.

In an "asynchronous" dynamic simulation if a neuron spikes at $\upsilon$ Hz, the average rate of synaptic updates provoked by the activity of that neuron is $\upsilon cN$ . In a synchronous simulation with step $\Delta t$ the number of synaptic updates per second would be $\frac{cN}{\Delta t}$ . As $\Delta t$ has to be chosen much smaller than the average interval between two successive afferent spikes, which implies $\Delta t < \frac{1}{\upsilon N}$ , giving an average of synaptic updates equal to $\upsilon c N^2$ . Therefore, spike-driven synaptic dynamics leads to a linear scaling of computational complexity O(N) per neuron, compared with the O(N²) in the "synchronous" case.^[1]

Records

Developed in the 1980s Adaptive Solutions' CNAPS-1064 Digital Parallel Processor chip is a full neural network (NNW). It was designed as a coprocessor to a host and has 64 sub-processors arranged in a 1D array and operating in a SIMD mode. Each sub-processor can emulate one or more neurons and multiple chips can be grouped together. At 25 MHz it is capable of 1.28 GMAC.^[2]

After the presentation of the RN-100 (12 MHz) single neuron chip at Seattle 1991 Ricoh developed the multi-neuron chip RN-200. It had 16 neurons and 16 synapses per neuron. The chip has on-chip learning ability using a proprietary backdrop algorithm. It comes in a 257-pin PGA encapsulation and develops 3.0 W (max). It was capable of 3 GCPS (1 GCPS at 32 MHz). ^[3]

In 1991-97, Siemens developed the MA-16 chip, SYNAPSE-1 and SYNAPSE-3 Neurocomputer. The MA-16 is a fast matrix-matrix multiplier that can be combined to form systolic arrays. It can process 4 patterns of 16 elements each (16-bit), with 16 neuron values (16-bit) at a rate of 800 MMAC or 400 MCPS at 50 MHz. The SYNAPSE3-PC PCI card contains 2 MA-16 with a peak performance of 2560 MOPS (1.28 GMAC); 7160 MOPS (3.58 GMAC) when using three boards.^[4]

In 2013, the K computer was used to simulate a neural network of 1.73 billion neurons with a total of 10.4 trillion synapses (1% of the human brain). The simulation ran for 40 minutes to simulate 1 s of brain activity at a normal activity level (4.4 on average). The simulation required 1 Petabyte of storage.^[5]

References

↑ Lua error in package.lua at line 80: module 'strict' not found.
↑ Real-Time Computing: Implications for General Microprocessors Chip Weems, Steve Dropsho
↑ Lua error in package.lua at line 80: module 'strict' not found.
↑ Neural Network Hardware Clark S. Lindsey , Bruce Denby , Thomas Lindblad, 1998
↑ Fujitsu supercomputer simulates 1 second of brain activity Tim Hornyak, CNET, August 5, 2013

External links

[Mattia1998-1] Lua error in package.lua at line 80: module 'strict' not found.

[Weems-2] Real-Time Computing: Implications for General Microprocessors Chip Weems, Steve Dropsho

[Almeida2003-3] Lua error in package.lua at line 80: module 'strict' not found.

[Lindsey1998-4] Neural Network Hardware Clark S. Lindsey , Bruce Denby , Thomas Lindblad, 1998

[CNET20130805-5] Fujitsu supercomputer simulates 1 second of brain activity Tim Hornyak, CNET, August 5, 2013

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SUPS

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