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Related Concept Videos

Energy Losses in Transformers01:21

Energy Losses in Transformers

1.5K
In an ideal transformer, it is assumed that there are no energy losses, and, hence, all the power at the primary winding is transferred to the secondary winding. However, in reality,  the transformers always have some energy losses, and, hence, the output power obtained at the secondary winding is less than the input power at the primary winding due to energy losses.
There are four main reasons for energy losses in transformers.
The first cause can be  the high resistance of the...
1.5K
Transformers with Off-Nominal Turns Ratios01:25

Transformers with Off-Nominal Turns Ratios

661
In scenarios involving parallel transformers with disparate ratings, developing per-unit models requires accommodating off-nominal turns ratios. This situation arises when the selected base voltages are not proportional to the transformer’s voltage ratings. Consider a transformer where the rated voltages are related by the term a. If the chosen voltage bases satisfy a relationship involving term b, term c is defined as the ratio of these bases. This ratio is then substituted into the...
661
Reducing Line Loss01:18

Reducing Line Loss

433
In a three-phase circuit, line loss is an indicator of energy dissipated as heat due to the resistance of transmission lines. To address this, incorporating transformers into the system—a step-up transformer at the source and a step-down transformer at the load—is a strategic solution. Two three-phase transformers are introduced to improve this.
With a step-up transformer at the source, the voltage is increased, thereby reducing the current in the transmission lines since power loss in...
433
Equivalent Circuits for Practical Transformers01:28

Equivalent Circuits for Practical Transformers

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The practical equivalent circuits of single-phase two-winding transformers exhibit significant deviations from their idealized versions due to the inherent properties of winding resistance and finite core permeability. These properties result in real and reactive power losses, affecting the transformer's performance. Understanding these deviations is crucial for designing more efficient transformers.
In a practical transformer, each winding exhibits resistance and leakage reactance. The...
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Masking and Demasking Agents01:19

Masking and Demasking Agents

3.9K
EDTA titrations may necessitate masking and demasking agents to temporarily protect a particular metal ion in a mixture from the EDTA reaction. These agents facilitate the sequential analysis of the metal ions by forming stable complexes with some—but not all—metal ions during certain steps.
There are many masking agents, such as cyanide, fluoride, triethanolamine, thiourea, and 2,3-bis(sulfanyl)propan-1-ol (formerly 2,3-dimercapto-1-propanol), with the masking agent chosen based on...
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Power System Three-Phase Short Circuits01:21

Power System Three-Phase Short Circuits

614
Determining the subtransient fault current in a power system involves representing transformers by their leakage reactances, transmission lines by their equivalent series reactances, and synchronous machines as constant voltage sources behind their subtransient reactances. In this analysis, certain elements are excluded, such as winding resistances, series resistances, shunt admittances, delta-Y phase shifts, armature resistance, saturation, saliency, non-rotating impedance loads, and small...
614

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Related Experiment Videos

Causal Mask in Transformer via Transfer Entropy Estimation from Vector Autoregressive Learning for Multivariate Time

Chengli Zhou1, Zicheng Wang2, Yaqun Huang1

  • 1School of Information Science and Engineering, Yunnan University, South Waihuan Road, University City East, Kunming, Yunnan, P. R. China.

International Journal of Neural Systems
|March 19, 2026
PubMed
Summary
This summary is machine-generated.

ARCausal enhances time series forecasting by integrating causal discovery with Transformer models. This approach improves prediction accuracy and interpretability by identifying true causal relationships, reducing spurious correlations.

Keywords:
Causal maskautoregressive causalitytime series forecastingvector autoregressive learning

Related Experiment Videos

Area of Science:

  • Data Science
  • Machine Learning
  • Time Series Analysis

Background:

  • Time series forecasting is complex due to spurious correlations in finance and climate science.
  • Existing methods struggle to disentangle autocorrelation from cross-variable causal effects.

Purpose of the Study:

  • To propose ARCausal, a novel forecasting framework combining transfer entropy-based causal discovery and Transformer attention.
  • To improve predictive performance and interpretability in time series forecasting.

Main Methods:

  • Integrating transfer entropy (TE) for causal discovery with Transformer attention modeling.
  • Developing a sparse causal masking mechanism derived from TE and refined using vector autoregression (VAR).
  • The mask suppresses noninformative dependencies and differentiates autocorrelation from cross-variable causal effects.

Main Results:

  • Consistent improvements over strong baselines across nine benchmark datasets.
  • Achieved up to [Formula: see text] reduction in Mean Squared Error (MSE).
  • Demonstrated enhanced interpretability of learned causal structures through visualizations.

Conclusions:

  • ARCausal effectively captures dynamic causal interactions for improved time series forecasting.
  • The framework offers a computationally efficient and interpretable solution for complex forecasting tasks.
  • Publicly available code facilitates further research and application.