Uniform magnetic field depends on the position of its surrounding. A non uniform magnetic field changes its position from one place to another.
A uniform magnetic field has the same strength and direction at all points in space. In contrast, a non-uniform magnetic field is one where the strength and/or direction varies from point to point. Uniform magnetic fields are often created in laboratory settings, while non-uniform magnetic fields can occur naturally or in more complex magnetic systems.
The answer depends on the source of the magnetic field. For instance, the magnetic field due to a current carrying wire is given by the formula mu*I/(2*pi*r). Magnetic fields follow the principle super position so they can be added up no problem.
Yes, the magnetic field inside a solenoid is generally uniform.
The formula for a uniform magnetic field is B I / (2 r), where B is the magnetic field strength, is the permeability of free space, I is the current, and r is the distance from the current.
A uniform magnetic field can be represented by field lines that are parallel and evenly spaced. Mathematically, it is represented by a vector field where the magnetic field strength (B) is constant in both magnitude and direction throughout the region of interest.
A uniform magnetic field has the same strength and direction at all points in space. In contrast, a non-uniform magnetic field is one where the strength and/or direction varies from point to point. Uniform magnetic fields are often created in laboratory settings, while non-uniform magnetic fields can occur naturally or in more complex magnetic systems.
A magnetic needle kept in uniform magnetic field will experience zero net force but non-zero net torque........Since the magnetic lines are uniform,the force acting on each end of the needlewill be equal and opposite.So it will cancel each other resulting zero net force.
The answer depends on the source of the magnetic field. For instance, the magnetic field due to a current carrying wire is given by the formula mu*I/(2*pi*r). Magnetic fields follow the principle super position so they can be added up no problem.
Yes, the magnetic field inside a solenoid is generally uniform.
A uniform magnetic field is a field where the magnetic field strength and direction are consistent throughout the region. This means that the magnetic field lines are parallel and evenly spaced, creating a uniform magnetic force on objects placed within the field. Uniform magnetic fields are often used in scientific experiments and applications due to their predictable behavior.
If a magnetic dipole placed in a magnetic field exhibits both rotational and translational motion, it suggests that the magnetic field is not uniform. A non-uniform magnetic field will exert torque on the magnetic dipole, causing it to rotate, and may also impart a force causing translational motion. These observations can help characterize the spatial variation of the magnetic field.
The formula for a uniform magnetic field is B I / (2 r), where B is the magnetic field strength, is the permeability of free space, I is the current, and r is the distance from the current.
Non-uniform magnetic field and a phase shift of 120 electrical degrees will occur.
A uniform magnetic field can be represented by field lines that are parallel and evenly spaced. Mathematically, it is represented by a vector field where the magnetic field strength (B) is constant in both magnitude and direction throughout the region of interest.
straight parallel lines
Yes, the magnetic field inside a long solenoid is generally uniform.
The magnitude of the magnetic flux through a circle due to a uniform magnetic field depends on the strength of the magnetic field, the area of the circle, and the angle between the magnetic field and the normal to the circle. The formula for magnetic flux is given by Φ = BAcos(θ), where B is the magnetic field strength, A is the area of the circle, and θ is the angle between the magnetic field and the normal to the circle.