Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Physics-

General

Easy

Question

In the figure shown, A & B are free to move. All the surfaces are smooth. $open parentheses 0 less than theta less than 90 to the power of ring operator end exponent close parentheses$

the acceleration of A will be more than g sin $θ$
the acceleration of A will be less than g sin $θ$
normal force on A due to B will be more than mg cos $θ$
normal force on A due to B will be less than mg cos $θ$

The correct answer is: the acceleration of A will be more than g sin $theta$

Related Questions to study

In the figure shown man is balanced by counter weight of same mass. He starts to climb the rope with an accelerator of $2 m divided by s to the power of 2 end exponent$ w.r.t. rope. The time after which he reaches the pulley will be

In the figure shown man is balanced by counter weight of same mass. He starts to climb the rope with an accelerator of $2 m divided by s to the power of 2 end exponent$ w.r.t. rope. The time after which he reaches the pulley will be

physics-General

In the fig. at the free end of the light string, a force F is appled to keep the suspended mass of 18 kg at rest. Assuming pulley is light then the force exerted by the ceiling on the system is:

In the fig. at the free end of the light string, a force F is appled to keep the suspended mass of 18 kg at rest. Assuming pulley is light then the force exerted by the ceiling on the system is:

physics-General

System is shown in figure. All the surfaces are smooth. Rod is moved by external agent with acceleration 9 m/s² vertically downwards. Force exerted on the rod by the wedge will be:

System is shown in figure. All the surfaces are smooth. Rod is moved by external agent with acceleration 9 m/s² vertically downwards. Force exerted on the rod by the wedge will be:

physics-General

parallel

Find the time in which 2 kg mass will strikes the pulley after being released from rest.

Find the time in which 2 kg mass will strikes the pulley after being released from rest.

physics-General

Two blocks A & B with mass 4 kg and 6 kg respectively are connected by a stretched spring of negligible mass as in figure . When the two blocks are released simultaneously the initial acceleration of B is 1.5 m/s² westward . The acceleration of A is :

Two blocks A & B with mass 4 kg and 6 kg respectively are connected by a stretched spring of negligible mass as in figure . When the two blocks are released simultaneously the initial acceleration of B is 1.5 m/s² westward . The acceleration of A is :

physics-General

Three blocks are connected as shown in the figure, on a horizontal frictionless table and pulled to the right with a force at 60N. if $M subscript 1 end subscript$ = 10kg, $M subscript 2 end subscript$ = 20kg and $M subscript 3 end subscript$ = 30 kg then the value of $T subscript 2 end subscript$ is

Three blocks are connected as shown in the figure, on a horizontal frictionless table and pulled to the right with a force at 60N. if $M subscript 1 end subscript$ = 10kg, $M subscript 2 end subscript$ = 20kg and $M subscript 3 end subscript$ = 30 kg then the value of $T subscript 2 end subscript$ is

physics-General

parallel

Fig shows two pulley arrangements for lifting a mass m. In
a) the mass is lifted by attaching a mass 2m while in
b) the mass is lifted by pulling the other end with a downward force F=2mg, If $f subscript a end subscript$ and $f subscript b end subscript$ are the accelerations of the two masses then

Fig shows two pulley arrangements for lifting a mass m. In
a) the mass is lifted by attaching a mass 2m while in
b) the mass is lifted by pulling the other end with a downward force F=2mg, If $f subscript a end subscript$ and $f subscript b end subscript$ are the accelerations of the two masses then

physics-General

Three equal weights of mass 2kg each are hanging by a string passing over a fixed pulley. The tension in the string (in N) connecting B and C is

Three equal weights of mass 2kg each are hanging by a string passing over a fixed pulley. The tension in the string (in N) connecting B and C is

physics-General

A ball is projected from point A with velocity 10m/sec. perpendicular to the inclined plane as in figure. Range of the ball on the incline is

A ball is projected from point A with velocity 10m/sec. perpendicular to the inclined plane as in figure. Range of the ball on the incline is

physics-General

parallel

The position–time (x–t) graphs for two children A and B returning from their school O to their homes P and Q respectively along straight line path (taken as x axis) are shown in figure below. Choose the correct statement (s):

The position–time (x–t) graphs for two children A and B returning from their school O to their homes P and Q respectively along straight line path (taken as x axis) are shown in figure below. Choose the correct statement (s):

physics-General

The graph shows position as a function of time for two trains running on parallel tracks Which statement is true?

The graph shows position as a function of time for two trains running on parallel tracks Which statement is true?

physics-General

Two blocks are arranged as shown in the figure. The relation between acceleration a₁ and a₂ is :

Two blocks are arranged as shown in the figure. The relation between acceleration a₁ and a₂ is :

physics-General

parallel

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary.(g = $10 m divided by s to the power of 2 end exponent$ )

At a certain moment when the girl was accelerating, the earth frame acceleration of the trolley is found to be 1 m/s² At this moment, the friction force between the girl’s shoes and the trolley’s surface is

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary.(g = $10 m divided by s to the power of 2 end exponent$ )

At a certain moment when the girl was accelerating, the earth frame acceleration of the trolley is found to be 1 m/s² At this moment, the friction force between the girl’s shoes and the trolley’s surface is

physics-General

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary.(g = $10 m divided by s to the power of 2 end exponent$ )

The minimum time in which the girl can stop from 9 m/s relative speed, to zero relative speed, without causing her shoes to slip is

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary.(g = $10 m divided by s to the power of 2 end exponent$ )

The minimum time in which the girl can stop from 9 m/s relative speed, to zero relative speed, without causing her shoes to slip is

physics-General

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary (g $equals 10 m divided by s to the power of 2 end exponent$ )

The total kinetic energy of system (trolley + girl) at the instant the girl acquires her maximum relative speed with respect to trolley, is

In figure shown on the right, the mass of the trolley is 100 kg, and it can move without friction on the horizontal floor. Its length is 12m. The mass of the girl is 50 kg. Friction exists between the shoes of the girl and the trolley’s upper surface, with $mu$ = 1/3. The girl can run with a maximum speed = 9 m/s on the surface of the trolley, with respect to the surface. At t = 0 the girl starts running from rest to the right. The trolley was initially stationary (g $equals 10 m divided by s to the power of 2 end exponent$ )

The total kinetic energy of system (trolley + girl) at the instant the girl acquires her maximum relative speed with respect to trolley, is

physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.