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Stromteilungsrechner

Berechnen Sie mit unserem Stromteiler-Rechner, wie sich der Strom zwischen parallelen Widerständen aufteilt. Erhalten Sie sofortige Ergebnisse, Schaltpläne und Echtzeit-Diagramme.

Circuit Inputs

R1:
R2:

Calculated Branch Currents

Total Equivalent Resistance

How It Works: The Current Divider Rule

The Current Divider Rule (CDR) is a fundamental principle in electronics that describes how electric current is distributed among parallel branches in a circuit. The current divides in inverse proportion to the resistance of each branch—meaning the path of least resistance gets the most current.

Interactive Circuit Diagram

The General Formula

To find the current (Ix) flowing through a specific resistor (Rx), you can use the general current divider formula:

Ix = Itotal × (Req / Rx)

Where:

  • Ix is the current in the branch with resistor Rx.
  • Itotal is the total current entering the parallel combination.
  • Req is the total equivalent resistance of all parallel resistors.
  • Rx is the resistance of the branch you are calculating for.

Two-Resistor Shortcut

For the common case of just two parallel resistors (R1 and R2), the formula for the current in the first branch (I1) simplifies to:

I1 = Itotal × (R2 / (R1 + R2))

Visualize the Current Division

This chart provides a dynamic, real-time visualization of how the total current is distributed among the different resistor branches. Change the input values above to see how the chart reacts instantly.

Frequently Asked Questions

A current divider splits current between parallel components, while a voltage divider splits voltage between series components. The key difference is the circuit configuration: parallel for current division, and series for voltage division.
The CDR applies to linear, bilateral circuits. You cannot use it directly if the circuit contains non-linear elements like diodes or transistors in the parallel branches, or if it has dependent sources. In those cases, other analysis techniques like nodal analysis are needed.
Current dividers are fundamental in many areas. They are used in transistor biasing circuits to set the proper operating conditions. They are also integral to ammeters with multiple ranges, where they are used as shunts to divert a specific fraction of the current away from the sensitive meter movement. Additionally, they are found in various sensor circuits.

Built for educational and developmental purposes.

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