Physics, Principles with Applications |
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Page 19
... maximum height we calculate the position of the ball when its velocity equals zero ( v = 0 at the highest point ) ... maximum height at B , and returns to original height at C. ( See Example 1-6 . ) 2 - v2 – v3 _ 0 − ( 15.0 m / s ) 2 -225 ...
... maximum height we calculate the position of the ball when its velocity equals zero ( v = 0 at the highest point ) ... maximum height at B , and returns to original height at C. ( See Example 1-6 . ) 2 - v2 – v3 _ 0 − ( 15.0 m / s ) 2 -225 ...
Page 277
... maximum velocity vo , ( c ) the velocity v when the mass is 0.050 m from equilibrium , and ( d ) the maximum acceleration of the mass . SOLUTION ( a ) Since the spring stretches 0.150 m when 0.30 kg is hung from it , we find k from ...
... maximum velocity vo , ( c ) the velocity v when the mass is 0.050 m from equilibrium , and ( d ) the maximum acceleration of the mass . SOLUTION ( a ) Since the spring stretches 0.150 m when 0.30 kg is hung from it , we find k from ...
Page 492
... maximum , the charge is a maximum . But what about the current I ? At point a in Figure 19-3b , when the voltage starts increasing , the charge on the plates is zero ; thus charge flows readily toward the plates and the current is large ...
... maximum , the charge is a maximum . But what about the current I ? At point a in Figure 19-3b , when the voltage starts increasing , the charge on the plates is zero ; thus charge flows readily toward the plates and the current is large ...
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acceleration Ampère's law angle angular angular acceleration angular velocity applied Assume atoms average axis battery beam body Calculate called capacitor cell Chapter charge circuit coil components constant decay diagram diffraction direction distance earth electric field electron emitted equal Equation equilibrium example F₁ flow fluid focal length force exerted forces acting frequency friction galvanometer heat horizontal kcal kinetic energy km/h lens light liquid m/s² magnetic field magnitude mass measured mirror molecules momentum motion moving muscle N/m² negative neutrons Newton's Newton's second law nuclear nucleons nucleus object orbit particle perpendicular photon plates positive pressure produced quantum quantum mechanics radiation radius rays reference frame resistance resistor right-hand rule rotating second law SECTION shown in Figure SOLUTION sound speed surface temperature theory torque traveling tube vector velocity vertical vibration voltage wave wavelength weight wire zero