The relationship between voltage and temperature can vary based on the material or device in question. In general, an increase in temperature can lead to an increase in resistance, which in turn can affect the voltage drop across a circuit. It is important to consider the specific characteristics of the material or device when analyzing the relationship between voltage and temperature.
The relationship between wavelength and peak voltage depends on the type of wave. In electromagnetic waves like light or radio waves, there is no direct correlation between wavelength and peak voltage. However, in signals like electrical voltage waveforms, the peak voltage is often correlated with the frequency of the wave.
A volt is the unit of measurement for electrical potential difference, while an ampere is the unit of measurement for electrical current. The relationship between them is defined by Ohm's Law, which states that voltage equals current multiplied by resistance (V = I x R). In other words, voltage is proportional to current when resistance is constant.
In the graph of voltage vs current, the relationship between voltage and current is linear. This means that as voltage increases, current also increases proportionally.
The current vs voltage graph shows that there is a linear relationship between current and voltage in the given circuit. This means that as voltage increases, the current also increases proportionally.
In electrical circuits, the relationship between voltage and temperature is that an increase in temperature can lead to an increase in voltage. This is because temperature affects the resistance of the materials in the circuit, which in turn can impact the voltage.
Your question is unclear. But, if you are asking what the relationship between voltage and the distance between conductors is, then the higher the voltage, the greater the distance must be.
0.7
voltage depend on current and resistance r.p.m depend on no of pole
voltage and frequency both are different quantity.. don't mix it...
The relationship between wavelength and peak voltage depends on the type of wave. In electromagnetic waves like light or radio waves, there is no direct correlation between wavelength and peak voltage. However, in signals like electrical voltage waveforms, the peak voltage is often correlated with the frequency of the wave.
Vrms=1.414xVpk to pk
V=IR where V is the voltage (volts), I is current (amps) and R is resistance (ohms)
q=cv q=dv/dt
In a capacitor ckt, current will be lead ahead from voltage by an angle 90 degree. Because for a capacitor the relationship between voltage and current is given as v=(jx)i , where v= voltage i= current jx=capacitive reactance
Scroll down to related links and look at "Electrical voltage V, amperage I, resistivity R, impedance Z, wattage P".
voltage is inversly proportional to speed speed and current are directly proportional to each other but voltage and current are directly proportional to each other..
q=cv so current changes with change in voltage keeping c constant