AI Article Synopsis
- Recent advancements in machine learning and hardware design are enabling the use of deep neural networks on low-power devices for various tasks, but there’s still potential for optimizing these networks, especially concerning power consumption and real-time performance.
- The work introduces a new framework called MicroAI, which focuses on training, quantization, and deploying deep neural networks specifically on low-power 32-bit microcontrollers, providing flexibility for different use cases.
- The framework is evaluated against existing inference engines through various datasets and demonstrates improvements in memory and power efficiency using ARM Cortex-M4F-based microcontrollers.
Article Abstract
Embedding Artificial Intelligence onto low-power devices is a challenging task that has been partly overcome with recent advances in machine learning and hardware design. Presently, deep neural networks can be deployed on embedded targets to perform different tasks such as speech recognition, object detection or Human Activity Recognition. However, there is still room for optimization of deep neural networks onto embedded devices. These optimizations mainly address power consumption, memory and real-time constraints, but also an easier deployment at the edge. Moreover, there is still a need for a better understanding of what can be achieved for different use cases. This work focuses on quantization and deployment of deep neural networks onto low-power 32-bit microcontrollers. The quantization methods, relevant in the context of an embedded execution onto a microcontroller, are first outlined. Then, a new framework for end-to-end deep neural networks training, quantization and deployment is presented. This framework, called MicroAI, is designed as an alternative to existing inference engines (TensorFlow Lite for Microcontrollers and STM32Cube.AI). Our framework can indeed be easily adjusted and/or extended for specific use cases. Execution using single precision 32-bit floating-point as well as fixed-point on 8- and 16 bits integers are supported. The proposed quantization method is evaluated with three different datasets (UCI-HAR, Spoken MNIST and GTSRB). Finally, a comparison study between MicroAI and both existing embedded inference engines is provided in terms of memory and power efficiency. On-device evaluation is done using ARM Cortex-M4F-based microcontrollers (Ambiq Apollo3 and STM32L452RE).
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8122998 | PMC |
| http://dx.doi.org/10.3390/s21092984 | DOI Listing |
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