Sears and Zemansky's University Physics, Volume 2Questions, exercises and problems after each chapter |
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Page 856
... connected in parallel , the equivalent resistance of the combination is always smaller than that of either resistor . 27-3 Three resistors having resistances of 1.60 N , 2.40 N , and 4.80 are connected in parallel to a 28.0 - V battery ...
... connected in parallel , the equivalent resistance of the combination is always smaller than that of either resistor . 27-3 Three resistors having resistances of 1.60 N , 2.40 N , and 4.80 are connected in parallel to a 28.0 - V battery ...
Page 860
... connected in series . When a certain potential difference is applied across the combination , the total power dissipated is 27 W. What power would be dissi- pated if the three resistors were connected in parallel across the same ...
... connected in series . When a certain potential difference is applied across the combination , the total power dissipated is 27 W. What power would be dissi- pated if the three resistors were connected in parallel across the same ...
Page 861
... connected between point b and ground ? b ) What is the reading of a voltmeter with resistance 5.00 × 10 ° Q ? c ) What is the reading of a voltmeter with infinite resistance ? a 100 ΚΩ 200 ΚΩ ww b FIGURE 27-47 Problem 27-56 . > 27-57 A ...
... connected between point b and ground ? b ) What is the reading of a voltmeter with resistance 5.00 × 10 ° Q ? c ) What is the reading of a voltmeter with infinite resistance ? a 100 ΚΩ 200 ΚΩ ww b FIGURE 27-47 Problem 27-56 . > 27-57 A ...
Contents
ELECTROMAGNETISM | 669 |
SummaryKey Terms | 694 |
Gausss Law | 704 |
Copyright | |
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Ampere's law amplitude angle angular angular frequency atomic axis battery bulb Calculate capacitance capacitor charge q circuit coil conductor constant Coulomb's law density diagram dielectric diffraction dipole distance electric field electric flux electromagnetic waves electron equal equation Example field lines FIGURE focal length frame frequency Gauss's law Gaussian surface index of refraction induced emf inductor integral intensity interference lens light loop magnetic field magnetic flux magnetic force magnitude and direction material maximum mirror moving negative charge object optical parallel particle path perpendicular phase phasor plane plates point charge polarized positive potential difference potential energy Problem proton R₁ R₂ radiation radius rays reflected resistor result Section shown in Fig shows sinusoidal slits solenoid speed sphere spherical tion torque uniform V₁ vacuum vector velocity voltage wavelength wire x-axis zero