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Paper detail

High-Throughput CNN Inference on Embedded ARM big.LITTLE Multi-Core Processors

IoT Edge intelligence requires Convolutional Neural Network (CNN) inference to take place in the edge devices itself. ARM big.LITTLE architecture is at the heart of prevalent commercial edge devices. It comprises of single-ISA heterogeneous cores grouped into multiple homogeneous clusters that enable power and performance trade-offs. All cores are expected to be simultaneously employed in inference to attain maximal throughput. However, high communication overhead involved in parallelization of computations from convolution kernels across clusters is detrimental to throughput. We present an alternative framework called Pipe-it that employs pipelined design to split convolutional layers across clusters while limiting parallelization of their respective kernels to the assigned cluster. We develop a performance-prediction model that utilizes only the convolutional layer descriptors to predict the execution time of each layer individually on all permitted core configurations (type and count). Pipe-it then exploits the predictions to create a balanced pipeline using an efficient design space exploration algorithm. Pipe-it on average results in a 39% higher throughput than the highest antecedent throughput.

preprint2020arXivOpen access
Siqi WangGayathri AnanthanarayananYifan ZengNeeraj GoelAnuj PathaniaTulika Mitra
PerformanceMachine LearningDistributed, Parallel, and Cluster Computing
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Siqi WangGayathri AnanthanarayananYifan ZengNeeraj GoelAnuj PathaniaTulika Mitra

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