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The resistance of a column of mercury 1 meter long and 1 square millimeter cross-sectional area at 0? C. (32? F.)
It is equal to .9431 legal ohm.
Resistance, Specific.
The relative resistance of a substance. It is expressed as the actual resistance of a cube of the substance which is one centimeter on each edge. For metals it is usually expressed in microhms, for liquids in ohms.
The resistances of a specified length of wire of specified diameter of different substances is often given, and is really a particular way of stating specific resistances.
Synonym--Specific Conduction Resistance.
Resistance, Spurious.
The counter-electro-motive force, q. v., operating to prevent a current being produced of what should be its full strength were the true resistance and actuating electro-motive force only concerned. Such counter-electro-motive force may be treated as a spurious resistance and such a value in ohms a.s.signed to it as would correspond to its proper effect.
468 STANDARD ELECTRICAL DICTIONARY.
In its effect on opposing a current and in resisting its formation it differs from true resistance. The latter in diminis.h.i.+ng current strength absorbs energy and develops heat; spurious resistance opposes and diminishes a current without absorption of energy or production of heat.
[Transcriber's note: "Spurious resistance" is now called reactance, consisting of capacitive reactance and inductive reactance. The combination of reactance and (Ohmic/true) resistance is called impedance. The calculation of impedance requires complex algebra, not just real values used in DC circuit a.n.a.lysis.]
Resistance, Steadying.
When arc lamps are connected in parallel or multiple arc a small resistance coil is sometimes placed in series with each lamp for steadying purposes. It reduces the percentage of variation of resistance in each lamp, which may be caused by a change in the position of the carbons.
Resistance, Swiss Unit of.
A unit constructed by the "Administration Suisse," based on the same data as the Breguet and the Digney Units. (See Resistance, Digney Unit of)
It is equal to 10.30 legal ohms.
Resistance, Thomson's Unit of.
A unit of resistance based on the foot and second.
It is equal to 0.3166 legal ohm.
Resistance, Unit.
Unit resistance is that of a conductor in which unit current is produced by unit electro-motive force.
Resistance, Varley's Unit of.
The resistance of a standard mile of a special copper wire 1/16 inch diameter.
It is equal to 25.33 ohms.
Resistance, Weber's Absolute Unit.
A metric system unit; (meter / second) * 1E7
It is equal to 0.9089 legal ohm.
Resonance, Electric.
A set of phenomena known as the Hertz experiments are grouped under this t.i.tle, which phenomena are incidents of and depend on the propagation of electric waves through wires or current conductors, as well as through the ether. Ordinarily a wire is only a seat of current, and is in its nature inconsistent with wave propagation through its ma.s.s. Such waves are virtually confined to the exterior of the wire. The point is that the current-producing force is supposed to enter the wire at all points from without, the current not being produced by an end-push. Hence in rapidly recurring waves which are produced by a rapidly pulsatory or alternating current, no time is afforded for the current-producing force, in this case the wave-producing force, to penetrate into the substance of the wire. In one of his experiments Dr. Hertz surrounded a wire by a gla.s.s tube chemically silvered. The coating was so thin as to be translucent. Through this metallic layer a current could be induced in the wire in its interior. Any mechanical layer of metal took up the induction itself, and protected the central wire. This gave a clue to the thickness of metal penetrated by the rapid induced waves used by Dr.
Hertz.
469 STANDARD ELECTRICAL DICTIONARY.
Fig. 295. ELECTRICAL RESONANCE EXCITER.
The method used for the production of rapid oscillations is the following. To the terminals of an induction coil two metal spheres AA1 are connected as shown. This apparatus is termed the exciter; in its discharge a series of isochronous discharges takes place, alternating in direction. The period of duration T of a single one is given by the formula T= 2* PI * squareRoot( LC ), in which C is the capacity and L is the self-induction. The spheres may be 30 centimeters (11.8 inches) in diameter, connected each to conductors 0.5 centimeter (.2 inch) in diameter and 40 centimeters (15.7 inches) long each. For the length of an undulation the formula gives for this apparatus 4.8 meters (15.75 feet) as the length of a wave, a.s.suming for them the velocity of propagation equal to that of light. The exciter may have 10,000 times the rate of oscillation possessed by the plain induction coil.
When this apparatus is worked it produces induced waves in every neighboring conductor. The resonance effects appear in the size of the spark induced. Thus a wire bent into a circle with its ends nearly touching will give a spark, but if made of proper electrostatic capacity, corresponding with the particular waves employed, the spark will be very much larger. The ring, with its spark gap is termed a resonator. It is used as an explorer to trace the waves.
Waves thus produced are transmitted by stone walls and nonconductors in general. A plate of zinc reflects part and transmits part. The reflected waves can be traced by the resonator, their angle of reflection being equal to their angle of incidence. They can be received by one parabolic reflector, reflected to another and brought to a focus. They can be reflected so as to produce interference or loops and nodes, and the loops and nodes can be traced by the resonator. By a prism of asphalt they are refracted exactly like light.
From all this it is concluded that an additional proof is furnished of the ident.i.ty of light and electro-magnetic waves, and a very strong experimental proof of Maxwell's theory of light is furnished.
Synonym--Hertz's Experiments.
470 STANDARD ELECTRICAL DICTIONARY.
Fig. 296. ELECTRICAL RESONATOR.
Resonator, Electric.
A small open electric circuit, with ends nearly touching. When exposed to electric resonance, or to a sympathetic electric oscillatory discharge, a spark pa.s.ses from across the gap. The production of this spark is altogether a matter of the inductance of the resonator. The simplest form is a circle of copper wire with its ends nearly touching.
The length of the gap is adjustable by bending. A screw adjustment may also be provided. Another form is shown in the cut, Fig. 296. Here sheets of tinfoil are used to regulate the electrostatic capacity, while at m is shown the finger piece for regulating the size of the spark gap a.
Synonym--Spark Micrometer.
Resultant.
The line indicating the result of the application of two or more forces to a point. Its direction and length give the elements of direction and intensity. (See Forces, Resolution of Forces, Composition of Components.)
Resultant Polarity.
The magnetic polarity imparted to a ma.s.s of iron acted on by two or more separate inducing forces or currents. It appears in dynamos and motors.
The final polarity is the resultant of the inducing effect of the field magnet poles and of the windings.