In simple terms, if flux density increases, then field strength increases and vice versa. The flux density is equivalent to field strength times with a variable.
g=GM/r2
There is no straightforward answer to your question. A tesla is the unit of measurement for magnetic flux density, defined in terms of magnetic flux per unit area. Magnetic flux density is determined by the magnetic field strength of the magnetic circuit in question which is expressed in ampere (turns) per metre. Unfortunately, the relationship between magnetic field strength and flux density isn't straightforward, as it depends on the shape of the B/H curve for the magnetic circuit's material. So, as you can see, there are too many unknown variables to give you a straightforward answer.
When the electric field in a circuit increases, the voltage between two points typically increases as well. This is because voltage is directly related to the electric field and the distance between the points, following the relationship ( V = E \cdot d ), where ( V ) is voltage, ( E ) is the electric field strength, and ( d ) is the distance. Thus, an increase in the electric field generally results in a higher voltage across the same distance.
The electric displacement field is a vector field, shown as D in equations and is equivalent to flux density. The electric field is shown as E in physics equations.
FIELD STRENGTH METERAn instrument used to give relative measurements of the radiation fields close to an operating transmitter.Generally used to determine the strength of the signal from a transmitter.An FM field strength meter can be used to find hidden bugs or trasmitting devices.I believe also that they can be used to determin the stregth of a magnet as well however they are refered to as a gauss meter or a magnetic field strength meter.
The magnetic energy density is directly proportional to the strength of a magnetic field. This means that as the strength of the magnetic field increases, the magnetic energy density also increases.
The density of equipotential lines is inversely proportional to the strength of the electric field in a given region. This means that where the equipotential lines are closer together, the electric field is stronger, and where they are farther apart, the electric field is weaker.
The relationship between magnetic field strength and distance in a magnetic field is inversely proportional. This means that as the distance from the source of the magnetic field increases, the strength of the magnetic field decreases.
The surface current density on a current sheet is directly proportional to the magnetic field it produces. This means that as the surface current density increases, the strength of the magnetic field also increases.
The relationship between charges and the strength of an electric field is that the strength of the electric field is directly proportional to the magnitude of the charges creating the field. This means that the stronger the charges, the stronger the electric field they produce. Additionally, the distance from the charges also affects the strength of the electric field as it decreases with increasing distance.
Neodymium is a type of rare earth magnet that is known for its strong magnetic properties. When neodymium magnets are used in a magnetic field, they can significantly increase the strength of the field due to their high magnetic flux density. This means that neodymium magnets can enhance the overall magnetic field strength when placed within it.
Planck's constant is a fundamental constant in quantum mechanics that relates the energy of a photon to its frequency. The relationship between Planck's constant and magnetic field strength is seen in the Zeeman effect, where the splitting of spectral lines in the presence of a magnetic field is proportional to the strength of the field and Planck's constant.
In a given system, the relationship between voltage and the electric field is that the electric field is directly proportional to the voltage. This means that as the voltage increases, the electric field strength also increases. Conversely, if the voltage decreases, the electric field strength will also decrease.
The strength of magnetic fields decreases as the distance between two magnets increases. This relationship follows an inverse square law, meaning that the magnetic field strength decreases exponentially with distance. Therefore, the closer the two magnets are, the stronger the magnetic field between them will be.
To determine the charge density from an electric field, you can use the formula: charge density electric field strength / (2 epsilon), where epsilon is the permittivity of the material. This formula relates the electric field strength to the charge density of the material.
The relative density of lines in a magnetic field diagram indicates the strength of the magnetic field in that region. A higher density of lines represents a stronger magnetic field, while a lower density indicates a weaker field. The spacing between the lines also gives an idea of the field's intensity, with closer lines indicating stronger magnetic force.
The volume charge density of an electric dipole affects the overall electric field distribution by influencing the strength and direction of the electric field lines around the dipole. A higher volume charge density results in a stronger electric field, while a lower volume charge density results in a weaker electric field. The distribution of the electric field lines is also influenced by the orientation and separation of the charges in the dipole.