scholarly journals Fast but Not Furious. When Sped Up Bit Rate of Information Drives Rule Induction

2021 ◽  
Vol 12 ◽  
Author(s):  
Silvia Radulescu ◽  
Areti Kotsolakou ◽  
Frank Wijnen ◽  
Sergey Avrutin ◽  
Ileana Grama
Keyword(s):  
Information Transmission ◽  
Channel Capacity ◽  
Channel Coding ◽  
Coding Theory ◽  
Accuracy Assessment ◽  
Assessment Method ◽  
Rule Induction ◽  
Theoretic Model ◽  
Bit Rate ◽  
Cognitive Limitations

The language abilities of young and adult learners range from memorizing specific items to finding statistical regularities between them (item-bound generalization) and generalizing rules to novel instances (category-based generalization). Both external factors, such as input variability, and internal factors, such as cognitive limitations, have been shown to drive these abilities. However, the exact dynamics between these factors and circumstances under which rule induction emerges remain largely underspecified. Here, we extend our information-theoretic model (Radulescu et al., 2019), based on Shannon’s noisy-channel coding theory, which adds into the “formula” for rule induction the crucial dimension of time: the rate of encoding information by a time-sensitive mechanism. The goal of this study is to test the channel capacity-based hypothesis of our model: if the input entropy per second is higher than the maximum rate of information transmission (bits/second), which is determined by the channel capacity, the encoding method moves gradually from item-bound generalization to a more efficient category-based generalization, so as to avoid exceeding the channel capacity. We ran two artificial grammar experiments with adults, in which we sped up the bit rate of information transmission, crucially not by an arbitrary amount but by a factor calculated using the channel capacity formula on previous data. We found that increased bit rate of information transmission in a repetition-based XXY grammar drove the tendency of learners toward category-based generalization, as predicted by our model. Conversely, we found that increased bit rate of information transmission in complex non-adjacent dependency aXb grammar impeded the item-bound generalization of the specific a_b frames, and led to poorer learning, at least judging by our accuracy assessment method. This finding could show that, since increasing the bit rate of information precipitates a change from item-bound to category-based generalization, it impedes the item-bound generalization of the specific a_b frames, and that it facilitates category-based generalization both for the intervening Xs and possibly for a/b categories. Thus, sped up bit rate does not mean that an unrestrainedly increasing bit rate drives rule induction in any context, or grammar. Rather, it is the specific dynamics between the input entropy and the maximum rate of information transmission.

scholarly journals Analisis Kinerja FBMC OQAM menggunakan Kode Konvolusi

2021 ◽  
Vol 9 (4) ◽  
pp. 775
Author(s):  
MIFTAKHUDIN YUSUF ◽  
ANGGUN FITRIAN ISNAWATI ◽  
SOLICHAH LARASATI
Keyword(s):  
Channel Capacity ◽  
Channel Coding ◽  
Viterbi Algorithm ◽  
Convolutional Code ◽  
Bit Rate ◽  
Digital Modulation ◽  
Data Rates ◽  
Better Than

ABSTRAKSistem FBMC merupakan teknologi MCM yang dapat menyediakan laju data bit yang tinggi. Modulasi digital OQAM digunakan untuk meningkatkan bit rate. Pengkodean kanal digunakan untuk mengoreksi kesalahan yang diakibatkan noise. Penilitian ini menggunakan pengkodean kanal kode konvolusi yang digunakan pada bagian pengirim dan algortima viterbi pada bagian penerima. Simulasi dilakukan pada FBMC OQAM dengan kode konvolusi dan tanpa kode konvolusi dengan perbandingan parameter BER dan kapasitas kanal terhadap SNR. Hasil penelitian menunjukan FBMC OQAM dengan kode konvolusi lebih baik daripada FBMC OQAM tanpa kode konvolusi pada SNR tinggi. Pada FBMC OQAM untuk mencapai BER 10-3 membutuhkan SNR 17 dB sedangkan pada FBMC OQAM dengan kode konvolusi membutuhkan SNR 16 dB. Peningkatan SNR dapat meningkatkan kapasitas kanal yang dihasilkan, pada SNR 0 dB menghasilkan 0,4535 bps/Hz dan SNR 20 dB menghasilkan 5,858 bps/Hz.Kata kunci: kode konvolusi, algoritma viterbi, FBMC, OQAM, BER ABSTRACTThe FBMC system is an MCM technology that can provide high bit data rates. OQAM digital modulation is used to increase the bit rate. Channel coding is used to correct errors caused by noise. This research uses convolutional code channel coding used on the sender and viterbi algorithms on the receiver. Simulations are carried out on FBMC OQAM with convolutional code and without convolutional code with a comparison of BER parameters and channel capacity to SNR. The results showed that FBMC OQAM with convolutional code was better than FBMC OQAM without convolutional code at high SNR. In FBMC OQAM to reach BER 10-3 requires SNR of 17 dB while in FBMC OQAM with convolutional code requires SNR of 16 dB. Increasing SNR can increase the resulting channel capacity, at 0 dB SNR it produces 0.4535 bps / Hz and SNR 20 dB produces 5.858 bps / Hz.Keywords: convolutional code, viterbi algorithm, FBMC, OQAM, BER

Method of Assessment of Casting Accuracy and Minimization of Machining Allowances

2012 ◽  
Author(s):  
Andrzej Gessner ◽  
Roman Staniek
Keyword(s):  
Machine Tool ◽  
Accuracy Assessment ◽  
Assessment Method ◽  
Machining Process ◽  
Shape Accuracy ◽  
Construction Design ◽  
Optical Scanner ◽  
Course Of Action ◽  
Reference Design ◽  
Method Of Assessment

The publication demonstrates an accuracy assessment method for machine tool body casting utilizing an optical scanner and a reference design of the machine tool body. The process allows assessing the casting shape accuracy, as well as determining whether the size of the allowances of all work surfaces is sufficient for appropriate machining, corresponding to the construction design. The described method allows dispensing with the arduous manual operation - marking out. Marking out, depending on the size and complexity, might take several working shifts for prototype casting. In case of large and elaborate casts, as those of machine tool bodies, marking out is often restricted only to the first cast of the desired body produced in a given casting mold. Such course of action is based on an assumption that casting is reproducible; hence, no need to assess each and every individual cast. While this approach saves time, it often results in late detection of casting errors (allowance shifts or insufficiencies) during the actual machining process. That, in turn, results in considerable losses due to the disruption of the work process and often demands cast repair. The aim of the hereby presented study is to introduce a new technological premise dispensing with manual marking out as well as allowing fast verification of the cast shapes.

Information-Transmission Method for Expressing Short-Term Memory Span as Channel Capacity

1976 ◽  
Vol 42 (2) ◽  
pp. 491-496 ◽  
Author(s):  
Stefan Slak
Keyword(s):  
Information Transmission ◽  
Channel Capacity ◽  
Short Term Memory ◽  
Memory Span ◽  
Absolute Judgment ◽  
Memory Storage ◽  
Short Term ◽  
Transmission Method ◽  
Term Memory ◽  
Computational Aspects

A general method, including procedural and computational aspects, for expressing short-term memory span as channel capacity is described. The method is then illustrated on an experiment performed to determine the channel capacity for short-term memory storage of decimal digits of two subjects. Curves representing transmitted information as a function of input information are similar in shape to those obtained in information-transmission experiments on absolute judgment.

scholarly journals Channel coding: The road to channel capacity

2007 ◽  
Vol 95 (6) ◽  
pp. 1150-1177 ◽  
Author(s):  
Daniel J. Costello ◽  
G. David Forney
Keyword(s):  
Channel Capacity ◽  
Channel Coding ◽  
The Road

Computer-aided alignment of castings and machining optimization

2014 ◽  
Vol 229 (3) ◽  
pp. 485-492 ◽  
Author(s):  
Andrzej Gessner ◽  
Roman Staniek ◽  
Tomasz Bartkowiak
Keyword(s):  
Machine Tool ◽  
Computer Aided Design ◽  
Reference Model ◽  
Accuracy Assessment ◽  
Assessment Method ◽  
Assessment Process ◽  
Shape Accuracy ◽  
Optical Scanner ◽  
Computer Aided ◽  
Machining Optimization

The presented publication demonstrates an accuracy assessment method for machine tool body casting utilizing an optical scanner and reference model of the machine tool body. The process allows assessing the casting shape accuracy, as well as determining whether the size of the allowances of all work surfaces is sufficient for appropriate machining, corresponding to the construction design. The described method enables dispensing with the arduous manual operation of marking out as well as shortening the time of aligning and fixing the casting body for machining. For the experimental setup, four rotary indexing table castings were investigated according to the method principles. The geometric accuracy of each casting was examined by comparing their scans with the computer-aided design model, and the machining allowances were evaluated to determine casting qualification for machining. The nominal volume of material to be removed was established and subsequently optimized to reduce the volume to be machined. Thus, a rapid method of aligning a casting in a machine tool according to the planned optimized distribution of machining allowances was developed. For the set of measured castings, it was proven that their poor geometric quality precluded the possibility of further machining according to standard marking out instructions. However, by following the presented methodology, it was possible to successfully process the entire set while reducing the overall volume of the material removed by 4.5–9.6%, as compared with nominal values. The obtained results ultimately confirmed that manual marking out could be eliminated from the casting assessment process.

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