...CT, (4). Hence, referring to the above equations (1), (2), (3) and (4), according to Ohm's law, (1) The current in amperes is equal to the electromotive...force in volts divided by the resistance in ohms. (2) The electromotive force in volts is equal to the product of the current in amperes, and the resistance...

...the resistance. 31. Q. What is the law for finding the cur36o 361 rent strength in amperes ? A. It is equal to the electro-motive force in volts divided by the resistance in ohms. 32. Q. What is a galvanometer ? A. Any instrument designed to measure the strength of an electric current....

...volts) is equal to the product of the current (in amperes) and the resistance (in ohms). It follows that the current (in amperes) is equal to the electromotive force (in volts) divided by the resistance (iu ohms), or E ri — \j — • H This is known as Ohm's Law. A similar law discovered by Poiseuille...

...of one volt, flowing through same, to one ampere, and is represented by K. According to Ohm' s law, the current in amperes is equal to the electromotive force in volts divided E by the resistance in ohms, thus, C = -rThe electromotive force in volts is equal to the product of...

...of one volt, flowing through same, to one ampere, and is represented by R. According to Ohm' s law, the current in amperes is equal to the electromotive force in volts divided E by the resistance in ohms, thus, C = -=5-- The electromotive force in volts is equal to the product...

...orQ=CT(4). Hence, referring to the above equations (i), (2), (3) and (4); according to Ohm's law: (I.) The current in amperes is equal to the electromotive force in volts divided by the resistance inohms. (2.) The electromotive force in volts is equal to the product of the current in amperes and...

...voltameters, and are explained on p. 132. The relation of these three units is expressed in Ohm's law. The Current (in amperes) is equal to the Electro-motive...Force (in volts) divided by the Resistance (in ohms). Any two terms being known, the third can be calculated ; for, if C = ^ -, then E = CXR and R ;-- ^...

...in which case they refer to the effective current. In any alternating current circuit with reactance the current in amperes is equal to the electromotive force in volts divided by the impedance in ohms. An ampere is also equal to a passage of one coulomb per second. The unit universally...

...in which case they refer to the effective current. In any alternating current circuit with reactance the current in amperes is equal to the electromotive force in volts divided by the impedance in ohms. An ampere is also equal to a passage of one coulomb per second. The unit universally...

...is measured in units like cubic feet per second. The current in amperes is, according to Ohm's law, equal to the electromotive force in volts divided by the resistance in ohms; or, according to Joule's law, to the power in watts divided by the volts; or to the square root of...