Vector Dot Product

3. Vector Physics Cube Notes (Vector Dot Product) PDF File.pdf

Understanding Work Done and the Dot Product in Physics

Calculating Work with Force and Displacement

The concept of work in physics is straightforward when a force is applied parallel to displacement: it's simply the force multiplied by the displacement. However, complexities arise when the force is at an angle to the displacement. In such cases, only the horizontal component of the force contributes to work, as the vertical component, having no displacement, doesn't add to the work done.

Multiplying Scalars and Vectors

Scalar Multiplication

When a vector is multiplied by a scalar, the resulting vector has a length that is the product of the scalar and the original vector's length, and it maintains the same direction. If the scalar is negative, the new vector reverses direction.

Vector Multiplication

Dot Product: This scalar product gives a scalar value. The dot product of vectors A and B, denoted as A · B, equals AB cos(θ), where A and B are the magnitudes, and θ is the angle between them. It can be calculated using the horizontal and vertical components of the vectors.

Cross Product: This type of multiplication results in a vector.

H2: Dot Product Characteristics

Commutative Property: A · B equals B · A.

Maximum Value: The dot product is greatest when vectors are parallel or antiparallel (0° or 180°).

Zero Value: The dot product is zero when vectors are perpendicular (90°).

Dot Product in Coordinate Notation

The dot product in i, j, k notation is given by A · B = AₓBₓ + AᵧBᵧ + AzBz, where Aₓ, Aᵧ, Az and Bₓ, Bᵧ, Bz are the respective components of vectors A and B.

Practical Examples

Calculating Dot Product

Short Method: For A = 4, B = 5, angle = 77°, A · B = 4 * 5 * cos(77°) = 4.5.

Long Method: For Aₓ = 3, Aᵧ = -4, Az = 0, Bₓ = -2, Bᵧ = 0, Bz = 3, A · B = (3 * -2) + (-4 * 0) + (0 * 3) = -6.

Finding the Angle Between Vectors

Given vectors a = 3i - 4j and b = -2i + 3k, calculate their magnitudes (|a| = 5, |b| = 3.61), find the dot product (a · b = -6), and use the equation -6 = (5 * 3.61) * cos(θ) to solve for θ, the angle between the vectors.

Conclusion

The dot product is an invaluable tool in physics, particularly for calculating work when forces are applied at an angle to displacement. Grasping the dot product and its properties is crucial for understanding vector interactions and their applications in physics.

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