Yes.
Voltage is equal to amperage time resistance. V=IR Therefore, I'd say voltage times amperage is equal to amperage squared times resistance. VI=IIR Really there's no point in multiplying the two. However, if you were to divide voltage by amperage, you would have the resistance of the circuit. V/I=R
To find the circuit's capacity you have to look at the breaker or fuse that protects that circuit. On the handle of the breaker you will see a number. that number is the tripping capacity of that particular breaker. On a glass screw in fuse you will see a coloured disk with a number on it that is the capacity that the fuse can handle before opening the circuit. On cartridge fuses the voltage and amperage rating will be printed on the body of the fuse.
You can connect a maximum of 24 100-W bulbs in parallel on a 120-V home circuit without tripping the 20-A breaker. This is calculated by dividing the total circuit wattage (2400 W) by the wattage of each bulb (100 W) to find the number of bulbs that can be safely connected.
The maximum number of standard lighting outlets on a 20 ampere circuit can vary depending on the wattage of the light fixtures and the local electrical code regulations. In general, as a rule of thumb, you can typically have around 10-13 standard lighting outlets on a 20 ampere circuit.
It makes no difference whether the circuit is parallel, series or complex. The number of electrons travelling (or oscillating back and forth for AC) is determined by the current (amps). 1 amp = 1 coulomb/second. 1 coulomb = the charge represented by 6.24150962915265 x 1018 electrons. The current in each leg of a parallel circuit has to be worked out separately.
Amperage.
The amperage of the circuit increases and the voltage drop across the appliances will tend to increase.
The supply voltage in a parallel circuit remains the same regardless of the number of additional resistors connected. The voltage across each resistor in a parallel circuit is the same as the supply voltage. Adding more resistors in parallel will increase the total current drawn from the supply.
In a parallel circuit, each component is connected directly to the power source, resulting in multiple electrical paths. The number of electrical paths in a parallel circuit is equal to the number of components connected in parallel.
In a parallel circuit the voltage across each component is the same.
A resistance 'network' consists of a number of resistors connected together in series, or in parallel, or in series-parallel, or as a complex circuit. A 'complex' circuit is one that is not series, parallel, or series-parallel.
A resistance 'network' consists of a number of resistors connected together in series, or in parallel, or in series-parallel, or as a complex circuit. A 'complex' circuit is one that is not series, parallel, or series-parallel.
The voltage stays the same as a single battery but the amperage multiplies by the number of batteries in the circuit. Example: Three 12 volt batteries with a CCA or 300 amps each wired together in parallel will produce 12 volts and 900 CCA.
energy source :)
If you increase the number of bulbs in a circuit, the resistance in the circuit will increase, causing the motor's speed to decrease. If you decrease the number of bulbs, the resistance in the circuit will decrease, causing the motor's speed to increase.
In a parallel circuit, the hypothesis is that when components are connected in parallel, the total current flowing into the junction equals the total current flowing out. Essentially, the hypothesis states that the total current remains constant regardless of the number of parallel paths.
Some key differences between a Serial and Parallel Adder are that a Serial Adder is slower, a Parallel adder is a combinational circuit and the time required for addition depends on the number of bits in a Serial, but not a Parallel. A Serial Adder is a sequential circuit while a Parallel is a combinational circuit.