Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Vector Product (Cross Product)01:17

Vector Product (Cross Product)

10.5K
Vector multiplication of two vectors yields a vector product, with the magnitude equal to the product of the individual vectors multiplied by the sine of the angle between both the vectors and the direction perpendicular to both the individual vectors. As there are always two directions perpendicular to a given plane, one on each side, the direction of the vector product is governed by the right-hand thumb rule.
Consider the cross product of two vectors. Imagine rotating the first vector about...
10.5K
Cartesian Vector Notation01:28

Cartesian Vector Notation

914
Cartesian vector notation is a valuable tool in mechanical engineering for representing vectors in three-dimensional space, performing vector operations such as determining the gradient, divergence, and curl, and expressing physical quantities such as the displacement, velocity, acceleration, and force. By using Cartesian vector notation, engineers can more easily analyze and solve problems in various areas of mechanical engineering, including dynamics, kinematics, and fluid mechanics. This...
914
Curvilinear Motion: Rectangular Components01:23

Curvilinear Motion: Rectangular Components

590
Curvilinear motion characterizes the movement of a particle or object along a curved path, notably evident when envisioning a car navigating a winding road. If the car starts at point A, its position vector is established within a fixed frame of reference, where the ratio of the position vector to its magnitude signifies the unit vector pointing in the position vector's direction.
As the car advances, its position evolves over time. Quantifying the car's velocity involves computing the...
590
Dot Product01:29

Dot Product

414
The dot product is an essential concept in mathematics and physics.
In engineering, the dot product of any two vectors is the product of the magnitudes of the vectors and the cosine of the angle between them. It is denoted by a dot symbol between the two vectors.
Consider a vehicle pulling an object along the ground using a rope. If the rope makes an angle with the horizontal axis, the work done can be calculated using the dot product of the force applied and the object's displacement.
The dot...
414
Position and Displacement Vectors01:00

Position and Displacement Vectors

10.1K
To describe the motion of an object, one should first be able to describe its position (where it is at any particular time). More precisely, the position needs to be specified relative to a convenient frame of reference. A frame of reference is an arbitrary set of axes from which the position and motion of an object are described. Earth is often used as a frame of reference to describe the position of an object in relation to stationary objects on Earth.
Further, several important kinds of...
10.1K
Cartesian Form for Vector Formulation01:26

Cartesian Form for Vector Formulation

713
The Cartesian form for vector formulation is a process to calculate  the moment of force using the position and force vectors. The moment of force is defined as the cross-product of these vectors, making it a vector quantity. The Cartesian form of the position and force vectors involves unit vectors, which can be used to express the cross-product in determinant form.
713

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Multiscale-Information-Embedded Universal Toxicity Prediction Framework.

Environmental science & technology·2025
Same author

Efficient Variants of Wasserstein Distance in Hyperbolic Space via Space-Filling Curve Projection.

IEEE transactions on neural networks and learning systems·2025
Same author

Hilbert Curve Projection Distance for Distribution Comparison.

IEEE transactions on pattern analysis and machine intelligence·2024
Same author

Regularized Optimal Transport Layers for Generalized Global Pooling Operations.

IEEE transactions on pattern analysis and machine intelligence·2023
Same author

The COVID-19 vaccination decision-making preferences of elderly people: a discrete choice experiment.

Scientific reports·2023
Same author

Differentiable Hierarchical Optimal Transport for Robust Multi-View Learning.

IEEE transactions on pattern analysis and machine intelligence·2022
Same journal

A Comprehensive Survey on Multimodal Recommender Systems: Taxonomy, Evaluation, and Future Directions.

IEEE transactions on pattern analysis and machine intelligence·2026
Same journal

Benchmarking the Robustness of Autonomous Driving to Environmental Illusions: A Lane Perception Perspective.

IEEE transactions on pattern analysis and machine intelligence·2026
Same journal

Learning Topology-Aware Representations via Test-Time Adaptation for Anomaly Segmentation.

IEEE transactions on pattern analysis and machine intelligence·2026
Same journal

TraGraph-GS: Trajectory Graph-based Gaussian Splatting for Arbitrary Large-Scale Scene Rendering.

IEEE transactions on pattern analysis and machine intelligence·2026
Same journal

SWIFT: A Small-World Interaction Framework for Flow-Aware Trajectory Prediction in Autonomous Driving.

IEEE transactions on pattern analysis and machine intelligence·2026
Same journal

HardFlow: Hard-Constrained Sampling for Flow-Matching Models Via Trajectory Optimization.

IEEE transactions on pattern analysis and machine intelligence·2026
See all related articles

Related Experiment Video

Updated: Aug 30, 2025

Quantifying Learning in Young Infants: Tracking Leg Actions During a Discovery-learning Task
11:18

Quantifying Learning in Young Infants: Tracking Leg Actions During a Discovery-learning Task

Published on: June 1, 2015

10.7K

Fast Quaternion Product Units for Learning Disentangled Representations in [Formula: see text].

Shaofei Qin, Xuan Zhang, Hongteng Xu

    IEEE Transactions on Pattern Analysis and Machine Intelligence
    |August 29, 2022
    PubMed
    Summary
    This summary is machine-generated.

    We introduce the Quaternion Product Unit (QPU), a novel neuron model for 3D rotation data. This model enhances neural network performance on 3D tasks by preserving data structure and improving rotation robustness.

    More Related Videos

    Methods for Measuring the Orientation and Rotation Rate of 3D-printed Particles in Turbulence
    12:34

    Methods for Measuring the Orientation and Rotation Rate of 3D-printed Particles in Turbulence

    Published on: June 24, 2016

    10.2K
    Swin-PSAxialNet: An Efficient Multi-Organ Segmentation Technique
    04:48

    Swin-PSAxialNet: An Efficient Multi-Organ Segmentation Technique

    Published on: July 5, 2024

    486

    Related Experiment Videos

    Last Updated: Aug 30, 2025

    Quantifying Learning in Young Infants: Tracking Leg Actions During a Discovery-learning Task
    11:18

    Quantifying Learning in Young Infants: Tracking Leg Actions During a Discovery-learning Task

    Published on: June 1, 2015

    10.7K
    Methods for Measuring the Orientation and Rotation Rate of 3D-printed Particles in Turbulence
    12:34

    Methods for Measuring the Orientation and Rotation Rate of 3D-printed Particles in Turbulence

    Published on: June 24, 2016

    10.2K
    Swin-PSAxialNet: An Efficient Multi-Organ Segmentation Technique
    04:48

    Swin-PSAxialNet: An Efficient Multi-Organ Segmentation Technique

    Published on: July 5, 2024

    486

    Area of Science:

    • Computer Vision
    • Machine Learning
    • Geometric Deep Learning

    Background:

    • Real-world 3D data (point clouds, skeletons) exist on 3D rotation groups.
    • Existing neural networks struggle with 3D rotation data due to Euclidean space limitations, leading to performance issues.
    • This mismatch hinders effective learning on 3D geometric tasks.

    Purpose of the Study:

    • To propose a novel neural network component for effectively processing 3D rotation data.
    • To address the limitations of Euclidean-based neural networks in handling 3D rotation groups.
    • To improve the performance and robustness of deep learning models on 3D tasks.

    Main Methods:

    • Introduced the Quaternion Product Unit (QPU), a non-real neuron model utilizing quaternion algebra for 3D rotation data.
    • Developed a fast QPU (fQPU) with reduced computational complexity (O(logN)) using tree-structured indexing and parallel computing.
    • Constructed Quaternion Neural Networks (QNNs), including QMLP and QMP, leveraging the fQPU module.

    Main Results:

    • QPUs mathematically preserve the SO(3) structure of 3D rotation data during inference.
    • QNNs disentangle representations into rotation-invariant and rotation-equivariant features.
    • Experiments show QNNs outperform real-valued models, especially in rotation-robust scenarios.

    Conclusions:

    • The proposed QPU and resulting QNNs offer a principled approach to learning on 3D rotation groups.
    • QNNs demonstrate superior performance and robustness for 3D point cloud and skeleton data processing.
    • This work provides a foundation for more effective deep learning on geometric data.