Your search keyword '"Ieong, Chio-In"' showing total 6 results

1. SDP: Spiking Diffusion Policy for Robotic Manipulation with Learnable Channel-Wise Membrane Thresholds

Author

Hou, Zhixing, Gao, Maoxu, Yu, Hang, Yang, Mengyu, and Ieong, Chio-In

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence

Abstract

This paper introduces a Spiking Diffusion Policy (SDP) learning method for robotic manipulation by integrating Spiking Neurons and Learnable Channel-wise Membrane Thresholds (LCMT) into the diffusion policy model, thereby enhancing computational efficiency and achieving high performance in evaluated tasks. Specifically, the proposed SDP model employs the U-Net architecture as the backbone for diffusion learning within the Spiking Neural Network (SNN). It strategically places residual connections between the spike convolution operations and the Leaky Integrate-and-Fire (LIF) nodes, thereby preventing disruptions to the spiking states. Additionally, we introduce a temporal encoding block and a temporal decoding block to transform static and dynamic data with timestep $T_S$ into each other, enabling the transmission of data within the SNN in spike format. Furthermore, we propose LCMT to enable the adaptive acquisition of membrane potential thresholds, thereby matching the conditions of varying membrane potentials and firing rates across channels and avoiding the cumbersome process of manually setting and tuning hyperparameters. Evaluating the SDP model on seven distinct tasks with SNN timestep $T_S=4$, we achieve results comparable to those of the ANN counterparts, along with faster convergence speeds than the baseline SNN method. This improvement is accompanied by a reduction of 94.3\% in dynamic energy consumption estimated on 45nm hardware.

Published

2024

2. FusionMamba: Dynamic Feature Enhancement for Multimodal Image Fusion with Mamba

Author

Xie, Xinyu, Cui, Yawen, Ieong, Chio-In, Tan, Tao, Zhang, Xiaozhi, Zheng, Xubin, and Yu, Zitong

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Multi-modal image fusion aims to combine information from different modes to create a single image with comprehensive information and detailed textures. However, fusion models based on convolutional neural networks encounter limitations in capturing global image features due to their focus on local convolution operations. Transformer-based models, while excelling in global feature modeling, confront computational challenges stemming from their quadratic complexity. Recently, the Selective Structured State Space Model has exhibited significant potential for long-range dependency modeling with linear complexity, offering a promising avenue to address the aforementioned dilemma. In this paper, we propose FusionMamba, a novel dynamic feature enhancement method for multimodal image fusion with Mamba. Specifically, we devise an improved efficient Mamba model for image fusion, integrating efficient visual state space model with dynamic convolution and channel attention. This refined model not only upholds the performance of Mamba and global modeling capability but also diminishes channel redundancy while enhancing local enhancement capability. Additionally, we devise a dynamic feature fusion module (DFFM) comprising two dynamic feature enhancement modules (DFEM) and a cross modality fusion mamba module (CMFM). The former serves for dynamic texture enhancement and dynamic difference perception, whereas the latter enhances correlation features between modes and suppresses redundant intermodal information. FusionMamba has yielded state-of-the-art (SOTA) performance across various multimodal medical image fusion tasks (CT-MRI, PET-MRI, SPECT-MRI), infrared and visible image fusion task (IR-VIS) and multimodal biomedical image fusion dataset (GFP-PC), which is proved that our model has generalization ability. The code for FusionMamba is available at https://github.com/millieXie/FusionMamba.

Published

2024

3. BaPipe: Exploration of Balanced Pipeline Parallelism for DNN Training

Author

Zhao, Letian, Xu, Rui, Wang, Tianqi, Tian, Teng, Wang, Xiaotian, Wu, Wei, Ieong, Chio-in, and Jin, Xi

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Artificial Intelligence

Abstract

The size of deep neural networks (DNNs) grows rapidly as the complexity of the machine learning algorithm increases. To satisfy the requirement of computation and memory of DNN training, distributed deep learning based on model parallelism has been widely recognized. We propose a new pipeline parallelism training framework, BaPipe, which can automatically explore pipeline parallelism training methods and balanced partition strategies for DNN distributed training. In BaPipe, each accelerator calculates the forward propagation and backward propagation of different parts of networks to implement the intra-batch pipeline parallelism strategy. BaPipe uses a new load balancing automatic exploration strategy that considers the parameters of DNN models and the computation, memory, and communication resources of accelerator clusters. We have trained different DNNs such as VGG-16, ResNet-50, and GNMT on GPU clusters and simulated the performance of different FPGA clusters. Compared with state-of-the-art data parallelism and pipeline parallelism frameworks, BaPipe provides up to 3.2x speedup and 4x memory reduction in various platforms.

Published

2020

4. A 0.12-mm2 1.2-to-2.4-mW 1.3-to-2.65-GHz Fractional-N Bang-Bang Digital PLL With 8-$\mu$ s Settling Time for Multi-ISM-Band ULP Radios

Author

Un, Ka-Fai, primary, Qi, Gengzhen, additional, Yin, Jun, additional, Yang, Shiheng, additional, Yu, Shupeng, additional, Ieong, Chio-In, additional, Mak, Pui-In, additional, and Martins, Rui P., additional

Published

2019

5. Wide Input Range Supply Voltage Tolerant Capacitive Sensor Readout Using On-Chip Solar Cell

Author

Fan, Suyan, primary, Law, Man-Kay, additional, Li, Mingzhong, additional, Chen, Zhiyuan, additional, Ieong, Chio-In, additional, Mak, Pui-In, additional, and Martins, Rui P., additional

Published

2015

6. Wide Input Range Supply Voltage Tolerant Capacitive Sensor Readout Using On-Chip Solar Cell.

Author

Fan, Suyan, Law, Man-Kay, Li, Mingzhong, Chen, Zhiyuan, Ieong, Chio-In, Mak, Pui-In, and Martins, Rui P.

Subjects

SOLAR cells, ELECTRIC potential, MULTIPROCESSORS, INFORMATION technology, INTEGRATED circuits, MICROELECTRONICS

Abstract

In this paper, a wide input range supply voltage tolerant capacitive sensor readout circuit using on-chip solar cell is presented. Based on capacitance controlled oscillators (CCOs) for ultra-low voltage/power consumption, the sensor readout circuit is directly powered by the on-chip solar cell to improve the overall system energy efficiency. An extended sensing range with high sensing accuracy is achieved using a two-step successive approximation register (SAR) and delta-sigma () analog-to-digital (A/D) conversion (ADC) scheme. Digital controls are generated on-chip using a customized sub-threshold digital standard cell library. Systematic error analysis and optimization including the finite switch on-resistance, buffer input-dependent delay, and SAR quantization nonlinearity are also outlined. High power supply rejection ratio (PSRR) is ensured by using a pseudo-differential topology with ratiometric readout. The complete sensing system is implemented using a standard 0.18m complementary metal-oxide-semiconductor (CMOS) process. Simulation results show that the readout circuit achieves a wide input range from 1.5pF to 6.5pF with a worst case PSRR of 0.5% from 0.3V to 0.42V (0.67% from 0.3V to 0.6V). With a 3.5pF input capacitance and a 0.3V supply, the stage achieves a resolution of 7.1-bit (corresponding to a capacitance of 2.2fF/LSB) with a conversion frequency of 371Hz. With an average power consumption of 40nW and a sampling frequency of 47.5kHz, a figure-of-merit (FoM) of 0.78pJ/conv-step is achieved. [ABSTRACT FROM AUTHOR]

Published

2016