The cable of a uniformly loaded suspension bridge hangs in the form of a parabola. The roadway which is horizontal and 100 m long is supported by vertical wires attached to the cable, the longest wire being 30 m and the shortest being 6 m. Find t

The cable of a uniformly loaded suspension bridge hangs in the form of a parabola. The roadway which is horizontal and 100m long is supported by vertical wires attached to the cable, the longest wire being 30m and the shortest being 6m. Find the length of the supporting wire attached to the roadway 18m from the middle.

IF the distribution of weight is uniform, then the rope of the suspended bridge takes the form of parabola.The height of the supporting towers is 20m, the distance between these towers is 150m and the height of the lowest point of the rope from the road is 3m. Find the equation of the parabolic shape of the rope considering the floor of the parabolic shape of the rope considering the floor of the bridge as X-axis and the axis of the parabola as Y-axis. Find the height of that tower which supports the rope and is at a distance of 30 m from the centre of the road.

A wire of length l , mass m and resistance R slides without any friction down the parallel conducting rails of negligible resistance . The rails are connected to each other at the bottom by a resistanceless rail parallel to the wire so that the wire and the rails form a closed rectangualr conducting loop. The plane of the rails makes an angle theta with the horizontal and a uniform vertical magnetic field of the inducetion B exists throughout the rregion. Find the steady state velocity of the wire.

A brilliant student of physics developed a magnetic balance to weight objects. The mass m to be measured is hung from the center the bar. Bar is kept in a uniform magnetic field of 1.5 T directed into the plane of the figure. Battery voltage can be adjusted to vary the current in the circuit. The horizontal bar shown is 60cm long and is made of extremly light weight material. It is connected to the battery via a resistance. There is no tension in the supporting wired. The magnetic force only supports the hanging weight. If V = 150 V , what is the maximum mass m ?

A particle B of mass 5 kg is attached to a frictionless pivot A by a thread of length d = 0.2 m so that B hangs freely. At some instant of time a strong wind begins to apply a constant horizontal force F = 100 N to B, as a result it rotates about A in a vertical plane. Find the speed (in m/s) of B at the instant when the string is horizontal (g = 10 m/s^(2))

A brilliant student of physics developed a magnetic balance to weight objects. The mass m to be measured is hung from the center the bar. Bar is kept in a uniform magnetic field of 1.5 T directed into the plane of the figure. Battery voltage can be adjusted to vary the current in the circuit. The horizontal bar shown is 60cm long and is made of extremly light weight material. It is connected to the battery via a resistance. There is no tension in the supporting wired. The magnetic force only supports the hanging weight. Which point of battery is positive?

A current of 10 A flows around a closed path in a circuit which is int eh horizontal plne as shown in the figure. The circuit consists oif eight alternating arcs of radii r_1=0.08m and r_2 =0.12m . Each subtends the same angle at the centre. a. Find the magnetic field produced by this circuit at the centre. b. An infinitely long straight wire carryin as current of 10 A is passing through the centre of the above circuit vertically with the direction of the current being into the pane of the circuit. what is the force acting on the wire at the centredue to the curren in the circuit? What is the force acting on the arc AC and the straight segment CD due to the current at the centre?