The main difference between microamps and milliamps is their size. Microamps are one millionth of an ampere, while milliamps are one thousandth of an ampere. In other words, a milliamp is larger than a microamp.
The amount of current produced in a photocell depends on the intensity of light that hits the cell. Higher light intensity will generate more current, while lower light intensity will generate less current. The current produced is generally in the range of microamps to milliamps.
The phase difference between two waves is directly proportional to the path difference between them. The phase difference is a measure of how much the wave has shifted along its oscillation cycle, while the path difference is a measure of the spatial separation between two points where the waves are evaluated.
The equation for calculating the phase difference between two waves is: Phase Difference (2 / ) (x) Where: Phase Difference is the difference in phase between the two waves is the wavelength of the waves x is the difference in position between corresponding points on the waves
The formula for calculating the phase difference between two waves is: Phase Difference (2 / ) (x) Where: Phase Difference is the difference in phase between the two waves is the wavelength of the waves x is the difference in position between corresponding points on the waves
The difference between 164 and 220 is 56.
The answer depends on the units which were used for 0.026. For example, 0.026 milliamps would be 0.026 milliamps while 0.026 microamps would be 0.000026 milliamps.
Electrical current is measured in amperes, or amps for short. Smaller currents might be measured in milliamps or microamps.
The movement of charges in response to a potential difference is called an electric current. This flow of charged particles creates an electric field and is the basis for the operation of electrical circuits.
2 volts across 100 kOhms produces 0.02 milliamps (or 20 microamps) of current. Ohm's law: Voltage = Amperes * Ohms, so Amperes = Voltage / Ohms.
No, 50 microamps (0.050 milliamps) is generally insufficient to light up a standard incandescent or LED bulb, which typically requires much higher current levels to operate. Most light bulbs need at least several hundred milliamps to produce visible light. However, certain specialized low-power LED indicators designed for very low current could potentially light up at that level, but they would be exceptions rather than the norm.
1,000 milliAmps (mA) = 1Amp (A) 1,000,000 microAmps (uA) = 1Amp (A) so 1Amp is larger
It's called, `current`. It's rated in amps, milliamps, microamps, etc., representing a fraction of an amp. The simple explanation is that the voltage is the `carrier`, and the current is the `power` which actually provides the energy to do the work.
The amount of current produced in a photocell depends on the intensity of light that hits the cell. Higher light intensity will generate more current, while lower light intensity will generate less current. The current produced is generally in the range of microamps to milliamps.
1 amp = 1000 milliamps so 1700 milliamps = 1.7 amps.
There are 0.075 amps in 75 milliamps.
7500 milliamps is equivalent to 7.5 amps. To convert milliamps to amps, you divide by 1000.
1,000 milliamps = 1 amp 180 milliamps = 0.18 amp