11 Other formulas that you can solve using the same Inputs

Observed Frequency When Observer Moves Towards the source
Frequency Observed=((Velocity Sound+Velocity Object)/Velocity Sound)*frequency GO
Effective Wavelength When Source Moves Away From the Observer
Wavelength Of A Wave=(Velocity Sound+Velocity Source)/frequency GO
Effective Wavelength When Source Moves Towards the Observer
Wavelength Of A Wave=(Velocity Sound-Velocity Source)/frequency GO
Speed of an object in Circular Motion
Speed of object moving in circle=2*pi*Radius*frequency GO
Synchronous Speed
Synchronous Speed=(120*frequency)/Number of pole GO
Time Period ( Using Frequency )
Time Period Of Progressive Wave=1/frequency GO
Velocity OF A Progressive Wave(Using Frequency)
Velocity=Wavelength Of A Wave*frequency GO
Amplitude
A=Total Distance Traveled/frequency GO
Angular Frequency ( Using Frequency )
Angular Frequency=2*pi*frequency GO
Slip When Frequency Is Given
Slip=Rotor Frequency/frequency GO
Wavelength Of The Wave(Using Frequency)
Wavelength=Velocity/frequency GO

11 Other formulas that calculate the same Output

Area of a Triangle when sides are given
Area=sqrt((Side A+Side B+Side C)*(Side B+Side C-Side A)*(Side A-Side B+Side C)*(Side A+Side B-Side C))/4 GO
Area of a Rhombus when side and diagonals are given
Area=(1/2)*(Diagonal A)*(sqrt(4*Side^2-(Diagonal A)^2)) GO
Area of a Rectangle when breadth and diagonal are given
Area=Breadth*(sqrt((Diagonal)^2-(Breadth)^2)) GO
Area of a Rectangle when length and diagonal are given
Area=Length*(sqrt((Diagonal)^2-(Length)^2)) GO
Area of a Trapezoid
Area=((Base A+Base B)/2)*Height GO
Area of a Rhombus when diagonals are given
Area=(Diagonal A*Diagonal B)/2 GO
Area of a Square when diagonal is given
Area=1/2*(Diagonal)^2 GO
Area of a Triangle when base and height are given
Area=1/2*Base*Height GO
Area of a Rectangle when length and breadth are given
Area=Length*Breadth GO
Area of a Parallelogram when base and height are given
Area=Base*Height GO
Area of a Square when side is given
Area=(Side A)^2 GO

Area Of Core When EMF Induced In Primary Winding Is Given Formula

Area=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density)
More formulas
EMF Induced In Primary Winding GO
EMF Induced In Secondary Winding GO
Frequency When EMF Induced In Secondary Winding is Given GO
Number Of Turns In The Primary winding GO
Frequency When EMF Induced In Primary Winding is Given GO
Number Of Turns In The Secondary Winding GO
Maximum Flux In Core When Primary Winding Is Given GO
Maximum Flux In Core When Secondary Winding Is Given GO
Maximum Flux Density When Secondary Winding Is Given GO
Maximum Flux Density When Primary Winding Is Given GO
Area Of Core When EMF Induced In Secondary Winding Is Given GO
Voltage Transformation Ratio When Primary And Secondary Voltage Is Given GO
Voltage Transformation Ratio When Primary And Secondary Current Is Given GO
Voltage Transformation Ratio When Primary And Secondary Induced Voltage Is Given GO
Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given GO
EMF Induced In Primary Winding When Voltage Transformation Ratio Is Given GO
Number Of Turns In The Primary Winding When Voltage Transformation Ratio Is Given GO
Number Of Turns In The Secondary Winding When Voltage Transformation Ratio Is Given GO
EMF Induced In Secondary Winding When Voltage Transformation Ratio Is Given GO
Primary Voltage When Voltage Transformation Ratio Is Given GO
Secondary Voltage When Voltage Transformation Ratio Is Given GO
Secondary Current When Voltage Transformation Ratio Is Given GO
Primary Current When Voltage Transformation Ratio Is Given GO
Secondary Leakage Reactance GO
Primary Leakage Reactance GO
Self-Induced EMF In Primary GO
Self-Induced EMF In Secondary GO
Secondary Current When Secondary Leakage Reactance Is Given GO
Primary Current When Primary Leakage Reactance Is Given GO
The Reactance Of Primary Winding In Secondary GO
The Reactance Of Secondary Winding In Primary GO
The Equivalent Reactance Of Transformer From Primary Side GO
The Equivalent Reactance Of Transformer From Secondary Side GO
Voltage Transformation Ratio When Secondary Leakage Reactance Is Given GO
Voltage Transformation Ratio When Primary Leakage Reactance Is Given GO
Resistance Of Secondary Winding In Primary GO
Resistance Of Primary Winding In Secondary GO
Equivalent Resistance Of Transformer From Primary Side GO
Equivalent Resistance Of Transformer From Secondary Side GO
Primary Winding Resistance GO
Secondary Winding Resistance GO
Impedance Of Primary Winding GO
Impedance Of Secondary Winding GO
Equivalent Impedance Of Transformer From Primary Side GO
Equivalent Impedance Of Transformer From Secondary Side GO
Input Voltage When EMF Induced In Primary Winding Is Given GO
Output Voltage When EMF Induced In Secondary Winding Is Given GO
Reactance Of Primary In Secondary When Equivalent Reactance From Secondary Side Is Given GO
Reactance Of Secondary In primary When Equivalent Reactance From primary Side Is Given GO
Resistance Of Secondary In Primary When Equivalent Resistance From Primary Side Is Given GO
Resistance Of Primary In Secondary When Equivalent Resistance From Secondary Side Is Given GO
Equivalent Resistance From Primary Side When Secondary Winding Resistance GO
Equivalent Resistance From Secondary Side When Primary Winding Resistance GO
Secondary Winding Resistance When Equivalent Resistance From Primary Side Is Given GO
Primary Winding Resistance When Equivalent Resistance From Secondary Side Is Given GO
Voltage Transformation Ratio When Primary Leakage Resistance Is Given GO
Voltage Transformation Ratio When Secondary Leakage Resistance Is Given GO
Voltage Transformation Ratio When Equivalent Resistance From Primary Side Is Given GO
Voltage Transformation Ratio When Equivalent Resistance From Secondary Side Is Given GO
Primary Winding Resistance When Secondary Winding Resistance Is Given GO
Secondary Winding Resistance When Primary Winding Resistance Is Given GO
Secondary Leakage Reactance When Equivalent Reactance From Secondary Side Is Given GO
Primary Leakage Reactance When Equivalent Reactance From Secondary Side Is Given GO
Secondary Leakage Reactance When Equivalent Reactance From Primary Side Is Given GO
Voltage Transformation Ratio When Equivalent Reactance From Secondary Side Is Given GO
Voltage Transformation Ratio When Equivalent Reactance From Primary Side Is Given GO
Secondary Winding Resistance When Impedance Of Secondary Winding Is Given GO
Primary Winding Resistance When Impedance Of Primary Winding Is Given GO
Secondary Winding Reactance When Impedance Of Secondary Winding Is Given GO
Primary Winding Reactance When Impedance Of Primary Winding Is Given GO
Equivalent Resistance From Primary Side When Equivalent Impedance From Primary Side Is Given GO
Equivalent Reactance From Primary Side When Equivalent Impedance From Primary Side Is Given GO
Equivalent Resistance From Secondary Side When Equivalent Impedance From Secondary Side Is Given GO
Equivalent Reactance From Secondary Side When Equivalent Impedance From Secondary Side Is Given GO
EMF Induced In Secondary Winding When Output Voltage Is Given GO
EMF Induced In Primary Winding When Input Voltage Is Given GO
Impedance Of Primary Winding When Input Voltage Is Given GO
Secondary Current When Output Voltage Is Given GO
Primary Current When Input Voltage Is Given GO
Impedance Of Secondary Winding When Output Voltage Is Given GO

What is induced EMF?

Alternating flux gets linked with the primary winding, and because of the phenomenon of mutual induction, an EMF gets induced in the primary winding. The magnitude of this induced EMF can be found by using the following EMF equation of the transformer.

How to Calculate Area Of Core When EMF Induced In Primary Winding Is Given?

Area Of Core When EMF Induced In Primary Winding Is Given calculator uses Area=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density) to calculate the Area, The Area Of Core When EMF Induced In Primary Winding Is Given formula is defined as the amount of two-dimensional space taken up by an object. The magnitude of this induced emf can be found by using the following EMF equation of the transformer. Area and is denoted by A symbol.

How to calculate Area Of Core When EMF Induced In Primary Winding Is Given using this online calculator? To use this online calculator for Area Of Core When EMF Induced In Primary Winding Is Given, enter frequency (f), EMF Induced In The Primary Winding (E1), Maximum flux density (B) and Number of Turns in Primary winding (N1) and hit the calculate button. Here is how the Area Of Core When EMF Induced In Primary Winding Is Given calculation can be explained with given input values -> 0.000313 = 10/(4.44*90*20*4).

FAQ

What is Area Of Core When EMF Induced In Primary Winding Is Given?
The Area Of Core When EMF Induced In Primary Winding Is Given formula is defined as the amount of two-dimensional space taken up by an object. The magnitude of this induced emf can be found by using the following EMF equation of the transformer and is represented as A=E1/(4.44*f*N1*B) or Area=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density). Frequency refers to the number of occurrences of a periodic event per time and is measured in cycles/second, EMF induced in the primary winding is the production of voltage in a coil because of the change in magnetic flux through a coil, Maximum flux density is the measure of the number of magnetic lines of force per unit of cross-sectional area and The number of Turns in Primary winding is the number of turns primary winding has.
How to calculate Area Of Core When EMF Induced In Primary Winding Is Given?
The Area Of Core When EMF Induced In Primary Winding Is Given formula is defined as the amount of two-dimensional space taken up by an object. The magnitude of this induced emf can be found by using the following EMF equation of the transformer is calculated using Area=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density). To calculate Area Of Core When EMF Induced In Primary Winding Is Given, you need frequency (f), EMF Induced In The Primary Winding (E1), Maximum flux density (B) and Number of Turns in Primary winding (N1). With our tool, you need to enter the respective value for frequency, EMF Induced In The Primary Winding, Maximum flux density and Number of Turns in Primary winding and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Area?
In this formula, Area uses frequency, EMF Induced In The Primary Winding, Maximum flux density and Number of Turns in Primary winding. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Area=1/2*Base*Height
  • Area=sqrt((Side A+Side B+Side C)*(Side B+Side C-Side A)*(Side A-Side B+Side C)*(Side A+Side B-Side C))/4
  • Area=Length*Breadth
  • Area=Length*(sqrt((Diagonal)^2-(Length)^2))
  • Area=Breadth*(sqrt((Diagonal)^2-(Breadth)^2))
  • Area=(Side A)^2
  • Area=1/2*(Diagonal)^2
  • Area=(Diagonal A*Diagonal B)/2
  • Area=(1/2)*(Diagonal A)*(sqrt(4*Side^2-(Diagonal A)^2))
  • Area=Base*Height
  • Area=((Base A+Base B)/2)*Height
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