Theoretical Elements of Electrical Engineering Formula Map

Formula Map

Review layer: these are OCR/PDF-text formula candidates. Promote only after scan verification, mathematical transcription, and notation review.

300

Formula and equation candidates.

102

Strong formula candidates.

111

Reviewable relation candidates.

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Formula Families

Family	Candidates
Inductance, Capacity, And Stored Energy	120
General Equation Candidates	87
Power, Energy, Work, And Efficiency	38
Symbolic AC And Complex Quantities	30
Magnetism, Hysteresis, And Core Loss	11
Waves, Lines, Radiation, And Frequency	8
Impedance, Reactance, And Admittance	3
Engineering Mathematics Foundations	2
Apparatus, Machines, And Power Systems	1

Highest-Priority Candidates

Candidate	Family	OCR/PDF text	Routes
`theoretical-elements-electrical-engineering-eq-candidate-0102` strong-formula-candidate	symbolic-ac	e = 2 7r/n $sin r the instantaneous generated e.m.f.</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-03/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-03/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0132</code><br/><small>strong-formula-candidate</small></td><td>symbolic-ac</td><td><code>If an alternating current i = I0 sin 6 passes through a resist-</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-04/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-04/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0138</code><br/><small>strong-formula-candidate</small></td><td>symbolic-ac</td><td><code>e.m.f., e = EQ sin 6.</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-04/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-04/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0049</code><br/><small>strong-formula-candidate</small></td><td>symbolic-ac</td><td><code>cos r = - - - - = 0.4</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-01/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-01/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0061</code><br/><small>strong-formula-candidate</small></td><td>general-equation-candidates</td><td><code>2$ = 0.4 X 105 / log, TT^ = 0.4 X 105 X 4.70 I = 0.188 X 106 7,	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0071` strong-formula-candidate	symbolic-ac	`iron is /z4 = 280 at B4 = 2850. Thus the field intensity/ H = - j`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0105` strong-formula-candidate	symbolic-ac	e = 2 irfn $sin 2 IT} (t - ti)</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-03/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-03/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0106</code><br/><small>strong-formula-candidate</small></td><td>symbolic-ac</td><td><code>or, e = 2-jrfn& sin (6 - 0i),</code></td><td><a href="/source-texts/theoretical-elements-electrical-engineering/section-03/">source</a><br/><a href="/chapter-workbench/theoretical-elements-electrical-engineering/section-03/">research review</a></td></tr> <tr><td><code>theoretical-elements-electrical-engineering-eq-candidate-0108</code><br/><small>strong-formula-candidate</small></td><td>general-equation-candidates</td><td><code>E = 4/n$ > = generated e.m.f. ($ in megalines, / in	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0133` strong-formula-candidate	symbolic-ac	`i*r = 702r sin2 0 = ^r C1 ~ cos 2 0),`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0168` strong-formula-candidate	symbolic-ac	`e = E0 sin (0 - 0i) = 273 sin (0 - 0i) ;`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0170` strong-formula-candidate	symbolic-ac	`e = 273 sin 210 (t - h).`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0197` strong-formula-candidate	symbolic-ac	`e = - -j-. L 108 absolute units`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0244` strong-formula-candidate	inductance-capacity	`e-o.296 1 = 0.5, - 0.296 Mog e = log 0.5, t =`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0284` strong-formula-candidate	symbolic-ac	`34. An alternating current i = IQ sin 2irft or i - I0 sin 0`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0288` strong-formula-candidate	symbolic-ac	`i = /0 sin 2 IT/ (t - t’),`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0291` strong-formula-candidate	symbolic-ac	`i = IQ sin 6 passes through a circuit of resistance r and induc-`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0297` strong-formula-candidate	symbolic-ac	`2 irft = /o sin 0) of effective value`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0298` strong-formula-candidate	symbolic-ac	`e’2 = - xI0 cos 2 irft = - xIQ cos 6,`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0300` strong-formula-candidate	symbolic-ac	`e’z = - xIQ cos 0,`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0290` strong-formula-candidate	symbolic-ac	`If such a sine wave of alternating current i = IQ sin 2 irft or`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0053` strong-formula-candidate	waves-radiation	`line carrying 7 amperes of current, if Id = 0.82 cm. is the diam-`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0243` strong-formula-candidate	inductance-capacity	`(a) M strength: i = ~, hence (1 - €-°-29«0 = 0.5.`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0246` strong-formula-candidate	symbolic-ac	`(b) %0 strength: i = 0.9 *0j hence (1 - e-°-2960 = 0.9, and`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0277` strong-formula-candidate	inductance-capacity	`(d) If i = 0 at * = 0.0005, then`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0280` strong-formula-candidate	inductance-capacity	`(e) If t = - I = - 90 at t = 0.001, then`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0047` strong-formula-candidate	symbolic-ac	`sin T = 0.2 mlo sin r, the torque of the current is`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0050` strong-formula-candidate	symbolic-ac	`In equilibrium, 0.2 mlQ sin r = 0.4 mlQ cos r, or tan r = 2,`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0083` strong-formula-candidate	general-equation-candidates	`ated e.m.f. is E = 12.5 volts.`	source research review
`theoretical-elements-electrical-engineering-eq-candidate-0100` strong-formula-candidate	general-equation-candidates	`E = 4 fn& is the average generated e.m.f.,`	source research review