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The Transmitted Voltage equation calculates the voltage wave traveling through the load of a transmission line using load impedance and transmitted current. This fundamental relationship helps in analyzing wave transmission characteristics in electrical systems.
The calculator uses the formula:
Where:
Explanation: The equation represents the fundamental relationship where transmitted voltage equals the product of load impedance and transmitted current in transmission line analysis.
Details: Accurate transmitted voltage calculation is crucial for transmission line design, power system analysis, impedance matching, and ensuring efficient power transfer in electrical networks.
Tips: Enter load impedance in Ohms and transmitted current in Amperes. Both values must be positive numbers greater than zero for accurate calculation.
Q1: What is transmitted voltage in transmission lines?
A: Transmitted voltage is the voltage wave that travels through the load of a transmission line, representing the portion of the incident wave that passes through the interface.
Q2: How does load impedance affect transmitted voltage?
A: Higher load impedance results in higher transmitted voltage for a given transmitted current, following the direct proportionality relationship V_t = I_l × I_t.
Q3: What are typical values for transmission line calculations?
A: Values vary widely depending on the system, but typical transmission lines operate with impedances ranging from 50-600 Ohms and currents from milliamps to hundreds of amperes.
Q4: Are there limitations to this equation?
A: This equation assumes ideal conditions and may need modification for complex impedance scenarios, frequency-dependent effects, or non-linear load characteristics.
Q5: How is this calculation used in practical applications?
A: It's used in power system design, telecommunications, antenna systems, and any application involving wave transmission through impedance interfaces.