188,916 research outputs found
Near-capacity iterative decoding of binary self-concatenated codes using soft decision demapping and 3-D EXIT charts
In this paper 3-D Extrinsic Information Transfer (EXIT) charts are used to design binary Self-Concatenated Convolutional Codes employing Iterative Decoding (SECCC-ID), exchanging extrinsic information with the soft-decision demapper to approach the channel capacity. Recursive Systematic Convolutional (RSC) codes are selected as constituent codes, an interleaver is used for randomising the extrinsic information exchange of the constituent codes, while a puncturer helps to increase the achievable bandwidth efficiency. The convergence behaviour of the decoder is analysed with the aid of bit-based 3-D EXIT charts, for accurately calculating the operating EbN0 threshold, especially when SP based soft demapper is employed. Finally, we propose an attractive system configuration, which is capable of operating within about 1 dB from the channel capacity
Improving a 3-D Convolutional Neural Network Model Reinvented from VGG16 with Batch Normalization
It is challenging to build and train a Convolutional Neural Network model that can achieve a high accuracy rate for the first time. There are many variables to consider such as initial parameters, learning rate, and batch size. Unsuccessfully training a model is one of the most inevitable problems. In some cases, the model struggles to find a lower Loss Function value which results in a poor performance. Batch Normalization is considered as a remedy to overcome this problem. In this paper, two models reinvented from VGG16 are created with and without using Batch Normalization to evaluate their model performance. It is clear that the model using Batch Normalization provides a better result in terms of Loss Function value and model accuracy, which also achieves a very high accuracy rate. It also reaches the saturation point of the highest model accuracy faster than the model without Batch Normalization. This paper also finds that the accuracy of 3D Convolutional Neural Network model reinvented from VGG16 with Batch Normalization is at 91.2% which can beat many benchmarking results on UCF101 such as IDT [5], Two-Stream [10], and Dynamic Image Networks IDT [4]. The technique introduced in this paper shows a fast, reliable and accurate estimation of human activity type and could be used in smart environments
Toward accurate quantitative photoacoustic imaging: learning vascular blood oxygen saturation in three dimensions
Significance: Two-dimensional (2-D) fully convolutional neural networks have been shown
capable of producing maps of sO2 from 2-D simulated images of simple tissue models.
However, their potential to produce accurate estimates in vivo is uncertain as they are limited
by the 2-D nature of the training data when the problem is inherently three-dimensional (3-D),
and they have not been tested with realistic images.
Aim: To demonstrate the capability of deep neural networks to process whole 3-D images and
output 3-D maps of vascular sO2 from realistic tissue models/images.
Approach: Two separate fully convolutional neural networks were trained to produce 3-D maps
of vascular blood oxygen saturation and vessel positions from multiwavelength simulated
images of tissue models.
Results: The mean of the absolute difference between the true mean vessel sO2 and the network
output for 40 examples was 4.4% and the standard deviation was 4.5%.
Conclusions: 3-D fully convolutional networks were shown capable of producing accurate sO2
maps using the full extent of spatial information contained within 3-D images generated under
conditions mimicking real imaging scenarios. We demonstrate that networks can cope with some
of the confounding effects present in real images such as limited-view artifacts and have the
potential to produce accurate estimates in vivo
A simulation study of the performance of the NASA (2,1,6) convolutional code on RFI/burst channels
In an earlier report, the LINKABIT Corporation studied the performance of the (2,1,6) convolutional code on the radio frequency interference (RFI)/burst channel using analytical methods. Using an R(sub 0) analysis, the report concluded that channel interleaving was essential to achieving reliable performance. In this report, Monte Carlo simulation techniques are used to study the performance of the convolutional code on the RFI/burst channel in more depth. The basic system model under consideration is shown. The convolutional code is the NASA standard code with generators g(exp 1) = 1+D(exp 2)+D(exp 3)+D(exp 5)+D(exp 6) and g(exp 2) = 1+D+D(exp 2)+D(exp 3)+D(exp 6) and d(sub free) = 10. The channel interleaver is of the convolutional or periodic type. The binary output of the channel interleaver is transmitted across the channel using binary phase shift keying (BPSK) modulation. The transmitted symbols are corrupted by an RFI/burst channel consisting of a combination of additive white Gaussian noise (AWGN) and RFI pulses. At the receiver, a soft-decision Viterbi decoder with no quantization and variable truncation length is used to decode the deinterleaved sequence
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