Hardware Optimizations of Dense Binary Hyperdimensional Computing: Rematerialization of Hypervectors, Binarized Bundling, and Combinational Associative Memory

Schmuck, Manuel; Benini, Luca; Rahimi, Abbas

doi:10.1145/3314326

Cited by 59 publications

(49 citation statements)

References 31 publications

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“…As another alternative, projection to the binary HD vectors can be implemented by means of a cellular automaton [62], [63]. The input features in the original representation can be first binarized and then passed through several steps of computation with a cellular automaton.…”

Section: A Mapping To Hd Spacementioning

confidence: 99%

“…The ties should be broken randomly and reproducibly. It can be done for example by adding an additional random HD vector to the record; however it makes the encoder noncausal: two equal sets of input data in the original space become slightly dissimilar in the projected HD space [63]. Alternatively, using a constant HD vector would lead to all output HD vectors being slightly similar to each other even if they are supposed to be orthogonal.…”

Section: B Encodingmentioning

confidence: 99%

“…Alternatively, using a constant HD vector would lead to all output HD vectors being slightly similar to each other even if they are supposed to be orthogonal. To address this issue, instead of choosing a random/constant HD vector we compute an augmented HD vector [63] that is reproducible with the same set of input data, e.g., by further binding two already bound HD vectors:…”

Section: B Encodingmentioning

confidence: 99%

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Efficient Biosignal Processing Using Hyperdimensional Computing: Network Templates for Combined Learning and Classification of ExG Signals

et al. 2019

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Recognizing the very size of the brain's circuits, hyperdimensional (HD) computing can model neural activity patterns with points in a HD space, that is, with HD vectors. Key examined properties of HD computing include: a versatile set of arithmetic operations on HD vectors, generality, scalability, analyzability, one-shot learning, and energy efficiency. These make it a prime candidate for efficient biosignal processing where signals are noisy and nonstationary, training data sets are not huge, individual variability is significant, and energy efficiency constraints are tight. Purely based on native HD computing operators, we describe a combined method for multiclass learning and classification of various ExG biosignals such as electromyography (EMG), electroencephalography (EEG), and electrocorticography (ECoG). We develop a full set of HD network templates that comprehensively encode body potentials and brain neural activity recorded from different electrodes into a single HD vector without requiring domain expert knowledge or ad-hoc electrode selection process. Such encoded HD vector is processed as a single unit for fast one-shot learning, and robust classification. It can be interpreted to identify the most useful features as well. Compared to state-of-the-art counterparts, HD computing enables online, incremental, and fast learning as it demands less than a third as much training data as well as less preprocessing.

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Section: A Mapping To Hd Spacementioning

confidence: 99%

Section: B Encodingmentioning

confidence: 99%

Section: B Encodingmentioning

confidence: 99%

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Efficient Biosignal Processing Using Hyperdimensional Computing: Network Templates for Combined Learning and Classification of ExG Signals

et al. 2019

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“…Its relatively small size makes the timing simulation computationally tractable. We also selected another machine learning algorithm based on computing with hyperdimensional (HD) [49] vectors to detect two face/non-face classes among 10,000 web faces of a face detection dataset (FACE) from Caltech [50]. Fig.…”

Section: Resultsmentioning

confidence: 99%

FPGA Energy Efficiency by Leveraging Thermal Margin

Khaleghi

Salamat

Imani

et al. 2019

2019 IEEE 37th International Conference on Computer Design (ICCD)

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FPGA devices are continuously evolving to meet high computation and performance demand for emerging applications. As a result, cutting edge FPGAs are not energy efficient as conventionally presumed to be, and therefore, aggressive power-saving techniques have become imperative. The clock rate of an FPGA-mapped design is set based on worst-case conditions to ensure reliable operation under all circumstances. This usually leaves a considerable timing margin that can be exploited to reduce power consumption by scaling voltage without lowering clock frequency. There are hurdles for such opportunistic voltage scaling in FPGAs because (a) critical paths change with designs, making timing evaluation difficult as voltage changes, (b) each FPGA resource has particular power-delay trade-off with voltage, (c) data corruption of configuration cells and memory blocks further hampers voltage scaling. In this paper, we propose a systematical approach to leverage the available thermal headroom of FPGA-mapped designs for power and energy improvement. By comprehensively analyzing the timing and power consumption of FPGA building blocks under varying temperatures and voltages, we propose a thermal-aware voltage scaling flow that effectively utilizes the thermal margin to reduce power consumption without degrading performance. We show the proposed flow can be employed for energy optimization as well, whereby power consumption and delay are compromised to accomplish the tasks with minimum energy. Lastly, we propose a simulation framework to be able to examine the efficiency of the proposed method for other applications that are inherently tolerant to a certain amount of error, granting further power saving opportunity. Experimental results over a set of industrial benchmarks indicate up to 36% power reduction with the same performance, and 66% total energy saving when energy is the optimization target.

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“…Prior work has proposed various algorithmic and hardware innovations to tackle the computational challenges of HD. Acceleration in hardware has typically focused on FPGAs [16][17][18] or ASIC-ish accelerators [19,20]. FPGA-based implementations provide high parallelism and bit-level granularity of operations that significantly improves the effective utilization of resources and performance.…”

Section: Motivationmentioning

confidence: 99%

SHEAR er

Khaleghi

Salamat

Thomas

et al. 2020

Proceedings of the ACM/IEEE International Symposium on Low Power Electronics and Design

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Hyperdimensional computing (HD) is an emerging paradigm for machine learning based on the evidence that the brain computes on highdimensional, distributed, representations of data. The main operation of HD is encoding, which transfers the input data to hyperspace by mapping each input feature to a hypervector, followed by a bundling procedure that adds up the hypervectors to realize the encoding hypervector. The operations of HD are simple and highly parallelizable, but the large number of operations hampers the efficiency of HD in embedded domain. In this paper, we propose SHEAR , an algorithmhardware co-optimization to improve the performance and energy consumption of HD computing. We gain insight from a prudent scheme of approximating the hypervectors that, thanks to error resiliency of HD, has minimal impact on accuracy while provides high prospect for hardware optimization. Unlike previous works that generate the encoding hypervectors in full precision and then and then perform ex-post quantization, we compute the encoding hypervectors in an approximate manner that saves resources yet affords high accuracy. We also propose a novel FPGA architecture that achieves striking performance through massive parallelism with low power consumption. Moreover, we develop a software framework that enables training HD models by emulating the proposed approximate encodings. The FPGA implementation of SHEAR achieves an average throughput boost of 104,904× (15.7×) and energy savings of up to 56,044× (301×) compared to state-of-the-art encoding methods implemented on Raspberry Pi 3 (GeForce GTX 1080 Ti) using practical machine learning datasets.

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Hardware Optimizations of Dense Binary Hyperdimensional Computing: Rematerialization of Hypervectors, Binarized Bundling, and Combinational Associative Memory

Cited by 59 publications

References 31 publications

Efficient Biosignal Processing Using Hyperdimensional Computing: Network Templates for Combined Learning and Classification of ExG Signals

Efficient Biosignal Processing Using Hyperdimensional Computing: Network Templates for Combined Learning and Classification of ExG Signals

FPGA Energy Efficiency by Leveraging Thermal Margin

SHEAR er

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