Two cars, A and B, take the same time to go round around two concentric circular tracks of radii `r_(1) and r_(2)`, respectively. If `r_(2)=4r_(1),` the ratio of the angular speed of car A to that of car B is

Two racing cars having masse m_(1) and m_(2) move in concentric circle of radii r_(1) and r_(2) respectively. If their angular speed are same , then ratio of their linear speed is

Two racing cars having masses m_(1) and _(2) move in concentric circles of radi r_(1) and r_(2) respectively . If their angular speeds are same , then the ration of their linear speeds is

Two bodies of masses 8 kg and 4 kg are moving in concentric circular orbits of radii r_(1) and r_(2) respectively . If their time periods are same , the ration of their centripetal accelerations is

Two buses A and B are moving around concentric circular pathe of radii r_(A) and r_(B) If the two buses complete the circular paths in the sme time. The ratio on their linear speeds is

Two cars A and B are going around concentric circular paths of tau_(A) and tau_(B) . If the two cars complete the circular paths in the same time then the ratio of angular speeds of A and B is

Two satellite fo masses m and 4m orbit the earth in circular orbits of radii 4r and r respectively. The ratio of their orbital speed is

Two particles A and B are moving in uniform circular motion in concentric circles of radii r_(A) and r_(B) with speed u_(A) and u_(B) respectively. Their time period of rotation is the same. The ratio of angular speed of a to that of B will be:

Two cars having masses m_1 and m_2 miove in circles of radii r_1 and r_2 respectively. If they complete the circle is equal time the ratio f their angular speedsd omega_1/omega_2 is

Two particles of equal masses are revolving in circular paths of radii r_(1) and r_(2) respectively with the same speed. The ratio of their centripetal force is