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عنوان
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Low-Voltage Implementation of Neuromorphic Circuits for a Spike-Based Learning Control Module
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نوع پژوهش
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مقاله چاپشده در مجلات علمی
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کلیدواژهها
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Neuron, WTA, spike-based, low-voltage, neuromorphic, control module
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چکیده
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Recent brain emulation engines have been configured using thousands of neurons and billions of synapses. These components make a significant impact on the whole system in terms of power consumption and silicon area. In this work, several upgraded neuromorphic circuits are used to configure an efficient and compact spike-based learning control module that is capable of operating under ultralow-voltage supplies offering a low energy consumption per spike. In this way, a conductance-based silicon neuron is developed using the simplest highly efficient analog circuits. Moreover, an upgraded winner-take-all (WTA) circuit is used to form a low-voltage multi-threshold current comparator to determine whether to increase or decrease the synaptic weight. Other components such as low-speed amplifier, differential pair integrator (DPI)-based synapse, and weight update controller are designed such that they properly operate under a 0.5V supply voltage. Simulation results in TSMC 0.18 μm CMOS process show an energy consumption of 2.5 pJ for the upgraded learning control module, while its stop-learning mechanism improves the performance of the system by avoiding overfitting.
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پژوهشگران
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کیی-تایونگ تنگ (نفر دوم)، میثم اکبری (نفر اول)
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