This paper presents a mixed-signal neuromorphic accelerator architecture designed for accelerating inference with event-based neural network models. This fully CMOS-compatible accelerator utilizes analog computing to emulate synapse and neuron operations. A C2C ladder structure implements synapses, while operational amplifiers (op-amps) are used to realize neuron functions. To enhance hardware resource utilization and power efficiency, we introduce the concept of a virtual neuron, where a single neuron engine emulates a set of model neurons, leveraging the sparsity inherent in event-based neuromorphic systems. Additionally, we propose a memory-based control technique to manage events in each layer, which improves performance while maintaining the flexibility to support various layer types. We also introduce an integer linear programming (ILP)-based mapping approach for efficiently allocating the model onto the proposed accelerator. The accelerator is a general-purpose neuromorphic platform capable of executing linear and convolutional neural models. The effectiveness of the proposed architecture is evaluated using two specially designed neuromorphic accelerators and two event-based datasets. The results show that the proposed architecture achieves 12.1 TOPS/W energy efficiency when accelerating a model trained on CIFAR10-DVS.
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