E-HIPA: An Energy-Efficient Framework for High-Precision Multi-Target-Adaptive Device-Free Localization

AbstractData-intensive computing operations, such as training neural networks, are essential for applications in artificial intelligence but are energy intensive. One solution is to develop specialized hardware onto which neural networks can be directly mapped, and arrays of memristive devices can, for example, be trained to enable parallel multiply–accumulate operations. Here we show that memcapacitive devices that exploit the principle of charge shielding can offer a highly energy-efficient approach for implementing parallel multiply–accumulate operations. We fabricate a crossbar array of 156 microscale memcapacitor devices and use it to train a neural network that could distinguish the letters ‘M’, ‘P’ and ‘I’. Modelling these arrays suggests that this approach could offer an energy efficiency of 29,600 tera-operations per second per watt, while ensuring high precision (6–8 bits). Simulations also show that the devices could potentially be scaled down to a lateral size of around 45 nm.

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Hardware-Efficient Stochastic Binary CNN Architectures for Near-Sensor Computing

Frontiers in Neuroscience ◽

10.3389/fnins.2021.781786 ◽

2022 ◽

Vol 15 ◽

Author(s):

Vivek Parmar ◽

Bogdan Penkovsky ◽

Damien Querlioz ◽

Manan Suri

Keyword(s):

Artificial Intelligence ◽

High Precision ◽

Energy Efficient ◽

Pathogen Detection ◽

Proof Of Concept ◽

Stochastic Sampling ◽

Stochastic Computing ◽

Microscopy Image ◽

With Memory

With recent advances in the field of artificial intelligence (AI) such as binarized neural networks (BNNs), a wide variety of vision applications with energy-optimized implementations have become possible at the edge. Such networks have the first layer implemented with high precision, which poses a challenge in deploying a uniform hardware mapping for the network implementation. Stochastic computing can allow conversion of such high-precision computations to a sequence of binarized operations while maintaining equivalent accuracy. In this work, we propose a fully binarized hardware-friendly computation engine based on stochastic computing as a proof of concept for vision applications involving multi-channel inputs. Stochastic sampling is performed by sampling from a non-uniform (normal) distribution based on analog hardware sources. We first validate the benefits of the proposed pipeline on the CIFAR-10 dataset. To further demonstrate its application for real-world scenarios, we present a case-study of microscopy image diagnostics for pathogen detection. We then evaluate benefits of implementing such a pipeline using OxRAM-based circuits for stochastic sampling as well as in-memory computing-based binarized multiplication. The proposed implementation is about 1,000 times more energy efficient compared to conventional floating-precision-based digital implementations, with memory savings of a factor of 45.

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RTK-LoRa: High-Precision, Long-Range and Energy-Efficient Localization for Mobile IoT devices

2020 IEEE Sensors Applications Symposium (SAS) ◽

10.1109/sas48726.2020.9220057 ◽

2020 ◽

Cited By ~ 1

Author(s):

Philipp Mayer ◽

Michele Magno ◽

Armin Berger ◽

Luca Benini

Keyword(s):

Long Range ◽

High Precision ◽

Energy Efficient ◽

Iot Devices

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A High-Precision Energy-Efficient GPS Time-Sync Method for High-Density Seismic Surveys

Applied Sciences ◽

10.3390/app10113768 ◽

2020 ◽

Vol 10 (11) ◽

pp. 3768

Author(s):

Ruyun Tian ◽

Junjie Zhang ◽

Shuai Zhang ◽

Longxu Wang ◽

Hongyuan Yang ◽

...

Keyword(s):

High Precision ◽

Seismic Data ◽

Energy Efficient ◽

Time Synchronization ◽

High Density ◽

Seismic Survey ◽

Data Synchronization ◽

Synchronization Method ◽

Synchronization Accuracy ◽

Synchronization Performance

Large numbers of seismic channels and high-density energy-efficient acquisition systems are the development trend of seismic instruments and have attracted high R&D interests in recent years. The combination of remote sensing and wireless sensor network technology provides superior observation capabilities for high-density seismic exploration. However, large-scale and multi-node acquisition methods place higher requirements on time synchronization performance. Seismic data with poor time synchronization will cause considerable errors in the interpretation of seismic data and even have no practical significance. Thus, the strict time synchronization performance is the prerequisite and basis for the application of cable-less storage seismograph in high-density seismic array applications. The existing time synchronization methods have high power consumption and poor time synchronization accuracy, which is not suitable for the long-time task. In addition, these methods are affected by the number of nodes and the distance. This paper presents an energy-efficient time-sharing indexed interpolation intercept method for the seismic data synchronization. The time synchronization method uses the high-precision TCXO as the main clock and records GPS time in the SD card at intervals to achieve the high-precision time-stamp for the seismic data. Then the seismic data is intercepted intermittently based on precise time stamps, which achieves the strict seismic data synchronization. Performance analysis shows that the time synchronization accuracy of the proposed method is 0.6 μs and saves 73% energy of the time-sync periods compared to the common GPS timing method. The field measurement results indicate that the time synchronization accuracy is not associated with the working time and the distance between nodes so that the proposed synchronization method is suitable for the high-density seismic survey.

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