because it does!
An ideal capacitor integrates the voltage across it. If you look at its frequency response you'd see that it's like a delta function at 0Hz, which represents a time domain integration.
he factors affecting the speed of a d.c. motor are, 1. The flux Φ 2. The voltage across the armature 3. The applied voltage V
Voltage is equal to the Current multiplied by the Resistance.Without changing the resistance, increasing the applied voltage in a circuit will increase current flow. There is a simple, direct relationship between voltage and current. Double the voltage, twice the current will flow. Triple the voltage, and the current will triple. As voltage (E) equals current (I) times resistance (R), when resistance is fixed, what happens to voltage will happen to current.
Ohms Law says that Voltage = Current * Ohms, so the twothings that can affect the voltage in a circuit are Current and Ohms. If have a non resistive impedance, i.e. a capacitor or inductor forming a reactance, then frequency can also affect the voltage but, mathematicaly, reactance is a frequency domain form of impedance, so my answer stands - Current and Ohms.
No. There are several factors that may affect the output voltage. For instance: Resistors, Transformer, Voltage regulators and others that can control the output voltage to a certain level.
If voltage varies then current varies with constant resistance.
Changing the voltage in a circuit will alter the current flowing through it. According to Ohm's Law, the current is directly proportional to the voltage in the circuit. Increasing the voltage will lead to an increase in current, and vice versa.
Changing the temperature increases the change in energy.
Increasing the number of parallel circuits in an electrical system does not affect the voltage. Voltage remains constant across all parallel circuits in the system.
It depends on where and how the resistor is placed in a circuit. A string of series resistors will split the voltage across all them depending on their values. All of the resistors in parallel will have the same voltage across all of them no matter what their resistance is.
The thickness of a wire, also known as gauge size, can affect the resistance of the wire which in turn can affect the voltage drop across the wire when current flows through it. Thicker wires have lower resistance, resulting in less voltage drop compared to thinner wires for the same current flow.
Connecting components in series increases the total voltage in a circuit, while connecting components in parallel keeps the voltage the same across all components.
Transfer payments and taxes affect aggregate spending indirectly by first changing disposable income and thereby changing consumption.
An ideal capacitor integrates the voltage across it. If you look at its frequency response you'd see that it's like a delta function at 0Hz, which represents a time domain integration.
No, changing the position of the voltmeter in a circuit can affect the reading due to the resistance and voltage drop across different components. It's essential to place the voltmeter in parallel with the component or points being measured to get an accurate reading.
The potential voltage is the force that pushes electric charges through a circuit. It is measured in volts. Higher voltage can increase the flow of current in a circuit, which can impact the performance and safety of electrical devices. It can also affect the resistance and power consumption of the circuit.
Resistance is affected by the length, cross-sectional area, and resistivity of the conductor. The resistivity, in turn, is affected by temperature. So only by changing one of these four factors will the resistance of a conductor change. Changing voltage will have no affect upon the conductor's resistance.