Three particles `A,B` and `C` move in a circle in anticlockwise direction with speeds `1min^(-1),2.5ms^(-1)` and `2ms^(-1)` respectively. The initial positions of `A,B` and `C` meet for the first time is

Three particles A,B and C move in a circle in anticlockwise direction with speeds 1min^(-1),2.5ms^(-1) and 2ms^(-1) respectively. The initial positions of A,B and C shown in figure . the ratio of distance travelled by A ,B and C by the instant they meet for the first time is

Three particles A,B and C move in a circle in anticlockwise direction with speeds 1min^(-1),2.5ms^(-1) and 2ms^(-1) respectively. The initial positions of A , B and C are shown in fig. The ratio of distance travelled by B and C by the instant A,B and C meet for the first time is

Three particles A, B and C move in a circle of radius r=(1)/(pi) m, in anti-clockwise direaction with speed 1ms^(-1), 2.5ms^(-1) and 2ms^(-1) respectively. The initial position of A, B and C are as shown in figure. The ratio of distance travelled by B and C by the instant A, B and C meet for the first time is

Three particles A, B and C move in a circle of radius r=(1)/(pi) m, in anti-clockwise direaction with speed 1ms^(-1), 2.5ms^(-1) and 2ms^(-1) respectively. The initial position of A, B and C are as shown in figure. The ratio of distance travelled by B and C by the instant A, B and C meet for the first time is

Buses A and B are moving in the same direction with speed 20 ms^(-1) and 15 ms^(-1) respectively. Find the relative velcoity of A w.r.t. B and relative velocity of B w.r.t. A.

Buses A and B are moving in the same direction with speed 20 ms^(-1) and 15 ms^(-1) respectively. Find the relative velcoity of A w.r.t. B and relative velocity of B w.r.t. A.

Buses A and B are moving in the same direction with speed 20 ms^(-1) and 15 ms^(-1) respectively. Find the relative velcoity of A w.r.t. B and relative velocity of B w.r.t. A.

Three particles of masses 1 kg, 2 kg and 3 kg are situated at the corners of an equilateral triangle move at speed 6ms^(-1), 3ms^(-1) and 2ms^(-1) respectively. Each particle maintains a direction towards the particles at the next corners symmetrically. Find velocity of CM of the system at this instant

Three particles of masses 1 kg, 2 kg and 3 kg are situated at the corners of an equilateral triangle move at speed 6ms^(-1), 3ms^(-1) and 2ms^(-1) respectively. Each particle maintains a direction towards the particles at the next corners symmetrically. Find velocity of CM of the system at this instant

Three particles of masses 1 kg, 2 kg and 3 kg are situated at the corners of an equilateral triangle move at speed 6ms^(-1), 3ms^(-1) and 2ms^(-1) respectively. Each particle maintains a direction towards the particles at the next corners symmetrically. Find velocity of CM of the system at this instant