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When proton-coupled carbon-13 spectra are simplified by a broadband proton decoupling technique, structural information about the coupled protons is lost. Distortionless enhancement by polarization transfer (DEPT) is a technique that provides information on the number of hydrogens attached to each carbon in a molecule. While the DEPT experiment utilizes complex pulse sequences, the pulse delay and flip angle are specifically manipulated. The resulting signals have different phases depending on...
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Deconvolution, also known as inverse filtering, is the process of extracting the impulse response from known input and output signals. This technique is vital in scenarios where the system's characteristics are unknown, and they must be inferred from the observable signals.
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The distribution law or Nernst's distribution law is the law that governs the distribution of a solute between two immiscible solvents. This law, also known as the partition law, states that if a solute is added to the mixture of two immiscible solvents at a constant temperature, the solute is distributed between the two solvents in such a way that the ratio of solute concentrations in the solvents remains constant at equilibrium.
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The probability of having two carbon-13 atoms next to each other is negligible because of the low natural abundance of carbon-13. Consequently, peak splitting due to carbon-carbon spin-spin coupling is not observed in spectra. However, protons up to three sigma bonds away split the carbon signal according to the n+1 rule, resulting in complicated spectra.
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Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...
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Metal ions can be separated from one another by complexation with organic ligands–the chelating agent– to form uncharged chelates. Here, the chelating agent must contain hydrophobic groups and behave as a weak acid, losing a proton to bind with the metal. Since most organic ligands used in this process are insoluble or undergo oxidation in the aqueous phase, the chelating agent is initially added to the organic phase and extracted into the aqueous phase. The metal-ligand complex is...
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DeepTensor: Low-Rank Tensor Decomposition With Deep Network Priors.

Vishwanath Saragadam, Randall Balestriero, Ashok Veeraraghavan

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    This summary is machine-generated.

    DeepTensor uses deep networks for efficient low-rank tensor decomposition, outperforming classical methods like SVD and PCA. This robust framework handles various data distributions and accelerates complex tensor operations.

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    Area of Science:

    • Computational mathematics
    • Machine learning
    • Signal processing

    Background:

    • Classical low-rank decomposition methods like SVD and PCA struggle with nonlinear structures and non-Gaussian noise.
    • Deep generative networks (DNs) offer implicit regularization, enabling capture of complex signal patterns.

    Purpose of the Study:

    • To introduce DeepTensor, a novel framework for efficient low-rank tensor decomposition using deep generative networks.
    • To demonstrate DeepTensor's robustness and computational efficiency compared to existing methods.

    Main Methods:

    • Decomposing tensors into low-rank factors generated by self-supervised deep networks.
    • Minimizing mean-square approximation error during network training.
    • Evaluating performance across hyperspectral image denoising, 3D MRI tomography, and image classification.

    Main Results:

    • DeepTensor effectively captures nonlinear signal structures missed by SVD and PCA.
    • The framework exhibits robustness to various data distributions, unlike SVD and PCA.
    • Achieved a 6 dB SNR improvement in Poisson noise denoising and 60x speedup in 3D tensor decomposition.

    Conclusions:

    • DeepTensor provides a computationally efficient and robust alternative to traditional low-rank decomposition techniques.
    • The implicit regularization of deep networks is key to uncovering complex, nonlinear data patterns.
    • DeepTensor demonstrates significant advantages in real-world applications requiring efficient and accurate tensor analysis.