1. What is Transmitted Voltage?

Transmitted Voltage is defined as the Voltage wave that is traveling through the Load of the Transmission line.

2. How Does the Calculator Work?

The calculator uses the formula:

Where:

• \( V_t \) — Transmitted Voltage (Volt)
• \( \tau_i \) — Transmission Coefficient of Current
• \( V_i \) — Incident Voltage (Volt)
• \( Z_2 \) — Impedance of Secondary Winding (Ohm)
• \( Z_1 \) — Impedance of Primary Winding (Ohm)

Explanation: This formula calculates the transmitted voltage based on the transmission coefficient of current, incident voltage, and the ratio of secondary to primary winding impedances.

3. Importance of Transmitted Voltage Calculation

Details: Calculating transmitted voltage is crucial for analyzing power transmission efficiency, designing transmission systems, and ensuring proper voltage levels across different components of electrical networks.

4. Using the Calculator

Tips: Enter all values as positive numbers. The transmission coefficient of current, incident voltage, and both impedances must be greater than zero for accurate calculation.

5. Frequently Asked Questions (FAQ)

Q1: What is the transmission coefficient of current?
A: The transmission coefficient of current is defined as the ratio of the transmitted current to the incident current of the Transmission line during transient conditions.

Q2: How is incident voltage determined?
A: The incident voltage on the transmission line is typically equal to half the generator voltage in many transmission line models.

Q3: What are typical values for winding impedances?
A: Winding impedance values vary significantly depending on the transformer design, material, and application, ranging from fractions of an ohm to several ohms.

Q4: Can this formula be used for AC and DC systems?
A: This formula is primarily used for AC systems where impedance concepts are most relevant, though it can be adapted for DC systems using resistance instead of impedance.

Q5: What factors affect the accuracy of this calculation?
A: Accuracy depends on precise measurement of input parameters, proper modeling of the transmission system, and accounting for real-world factors like temperature effects and component tolerances.