Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Formula Map

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300

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109

Strong formula candidates.

73

Reviewable relation candidates.

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Formula Families

Family	Candidates
Transients, Oscillation, And Damping	300

Highest-Priority Candidates

Candidate	Family	OCR/PDF text	Routes
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0195 strong-formula-candidate	transients-oscillation	i = io cos (0 - 7) = io cos 7 cos <j> + i0 sin 7 sin	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0220 strong-formula-candidate	transients-oscillation	if = 140 cos 0.2 1 - 80 sin 0.2 1,	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0014 strong-formula-candidate	transients-oscillation	w=j*pdt, (10)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0037 strong-formula-candidate	transients-oscillation	(B = -j =/z JClinespercm2.	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0039 strong-formula-candidate	transients-oscillation	7 = -j = yG am-	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0178 strong-formula-candidate	transients-oscillation	io = eo y j = e02/o. (11)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0185 strong-formula-candidate	transients-oscillation	ii = IQ cos 7 = initial transient current. (14)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0186 strong-formula-candidate	transients-oscillation	e = e0 sin (0 - 7), (15)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0187 strong-formula-candidate	transients-oscillation	ei = - e0 sin 7 = initial value of transient voltage. (16)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0196 strong-formula-candidate	transients-oscillation	i = i\ cos 1/001 sin - , (21)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0197 strong-formula-candidate	transients-oscillation	e = e\ cos - + z0ii sin - , (22)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0219 strong-formula-candidate	transients-oscillation	e = e-3<S2000 cos 0.2 1 + 3500 sin 0.2 «},	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0221 strong-formula-candidate	transients-oscillation	er = 2000 cos 0.2 1 + 3500 sin 0.2 1.	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0228 strong-formula-candidate	transients-oscillation	ii = IQ cos (</> - 7)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0229 strong-formula-candidate	transients-oscillation	ei = e0 sin (0 - 7) l	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0233 strong-formula-candidate	transients-oscillation	e = - €Q sin 7	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0234 strong-formula-candidate	transients-oscillation	i = loe-^cos (0 - 7)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0237 strong-formula-candidate	transients-oscillation	i = c<rui cos (0 - 7) ) n 1 x	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0246 strong-formula-candidate	transients-oscillation	i = ce~ut cos (0 T co - 7) ) ,17,	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0109 strong-formula-candidate	transients-oscillation	transient, starts with the value ij = mi0, and if eQ is the e.m.f.	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0004 strong-formula-candidate	transients-oscillation	where c = - - -r;1 = constant, and the minus sign is chosen, as	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0056 strong-formula-candidate	transients-oscillation	zero of time, Zo = 0, and equations (5) then assume the simpler	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0111 strong-formula-candidate	transients-oscillation	where L0 = inductance, r0 = total resistance of field-exciting cir-	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0180 strong-formula-candidate	transients-oscillation	io = eo2/o, where e0 = voltage between cable conductor and ground.	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0201 strong-formula-candidate	transients-oscillation	This is correct only if g = 0, that is, the conductance, which rep-	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0280 strong-formula-candidate	transients-oscillation	length Z0 = 4 Zi, and therefore the period tQ = cr0/o = 4 o-0/i, that	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0282 strong-formula-candidate	transients-oscillation	the frequencies (2 k - 1)/0, where k = 1, 2, 3 …	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0007 strong-formula-candidate	transients-oscillation	p = e’i. (2)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0009 strong-formula-candidate	transients-oscillation	w = T (5)	source workbench
elementary-lectures-electric-discharges-waves-impulses-eq-candidate-0011 strong-formula-candidate	transients-oscillation	f = Ce. (6)	source workbench