![]() ![]() Controls how many single-layer turns can be achieved around the core. ![]() N : Winding density at the toroid inner-diameter.Suppressor mode displays effective suppression frequency range in square brackets. (Pick lower μi for higher frequency applications.) Inductor mode shows initial permeability in square brackets. Material : Manufacturers material mix code.Size : Selects the size of the toroid.This limits the material selection as appropriate. Application : Selects the intended use of the toroid, either Inductor or Suppressor is currently supported.Section, where the user can select the application type, toroid material, toroid size, wire size, number of windings and excitation voltage. Schematic display, where a scaled image of the toroid and windings is presented to help with intuitive design. At the top is the chart display for showing frequency-dependent characteristics. The calculator has 4 separate display areas. To predict the component's characteristics. It uses the manufacturer's (Fair-Rite & Micrometals) published data including the toroid's dimensions and complex permeability characteristics You may also find the following Physics calculators useful.RF Toroid Calculator was developed to help users predict the RF characteristics of a ferrite or powdered-iron toroid wound as an inductor or suppressor. This allows you to learn about Electrostatics and test your knowledge of Physics by answering the test questions on Electrostatics. At the end of each Electrostatics tutorial you will find Electrostatics revision questions with a hidden answer that reveals when clicked. Each Electrostatics tutorial includes detailed Electrostatics formula and example of how to calculate and resolve specific Electrostatics questions and problems. The following Physics tutorials are provided within the Electrostatics section of our Free Physics Tutorials. Please provide a rating, it takes seconds and helps us to keep this resource free for all to useĮlectrostatics Physics Tutorials associated with the Electric Flux Calculator We believe everyone should have free access to Physics educational material, by sharing you help us reach all Physics students and those interested in Physics across the globe. This allows us to allocate future resource and keep these Physics calculators and educational material free for all to use across the globe. ![]() We hope you found the Electric Flux Calculator useful with your Physics revision, if you did, we kindly request that you rate this Physics calculator and, if you have time, share to your favourite social network. You can then email or print this electric flux calculation as required for later use. As you enter the specific factors of each electric flux calculation, the Electric Flux Calculator will automatically calculate the results and update the Physics formula elements with each element of the electric flux calculation. Please note that the formula for each calculation along with detailed calculations are available below. ![]() Surface area Note 1 ( |A|) m 2 Īngle between electric field lines and the area vector ( θ) ° Įlectric constant or vacuum permittivity ( ϵ 0) C 2/N∙m 2 The electric flux through a closed surface when the charge is given using the Gauss Law isĮlectric flux calculations for inward fluxĮlectric flux calculations for outward flux The electric flux (outward flux) through a closed surface when electric field is given is V ∙ m Electric Flux (Gauss Law) Calculator Results (detailed calculations and formula below) The electric flux (inward flux) through a closed surface when electric field is given is V ∙ m ![]()
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