When an object is at a distance of twice the focal length from a concave lens, the image produced is virtual and smaller than th
2 answers:
Answer:
The image produced is virtual and smaller than the object.
Explanation:
For concave lens we know that
here we have
Magnification will be given as
so image will be virtual and formed behind the lens
Now the object position is shifted to new position at distance of focal length
now again we will have
here we have
Magnification will be given as
So again we will have virtual image with magnification 1/2
so here size of image is less than object size by factor of 1/2 and it is virtual
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First, let's find the speed 
of the two blocks m1 and m2 sticked together after the collision.
We can use the conservation of momentum to solve this part. Initially, block 2 is stationary, so only block 1 has momentum different from zero, and it is:
After the collision, the two blocks stick together and so now they have mass
and they are moving with speed :
For conservation of momentum
So we can write
From which we find
The two blocks enter the rough path with this velocity, then they are decelerated because of the frictional force
. The work done by the frictional force to stop the two blocks is
where d is the distance covered by the two blocks before stopping.
The initial kinetic energy of the two blocks together, just before entering the rough path, is
When the two blocks stop, all this kinetic energy is lost, because their velocity becomes zero; for the work-energy theorem, the loss in kinetic energy must be equal to the work done by the frictional force:
From which we can find the value of the coefficient of kinetic friction:
We can use the conservation of momentum to solve this part. Initially, block 2 is stationary, so only block 1 has momentum different from zero, and it is:
After the collision, the two blocks stick together and so now they have mass
For conservation of momentum
So we can write
From which we find
The two blocks enter the rough path with this velocity, then they are decelerated because of the frictional force
where d is the distance covered by the two blocks before stopping.
The initial kinetic energy of the two blocks together, just before entering the rough path, is
When the two blocks stop, all this kinetic energy is lost, because their velocity becomes zero; for the work-energy theorem, the loss in kinetic energy must be equal to the work done by the frictional force:
From which we can find the value of the coefficient of kinetic friction:
Answer:
a)μΩ
b)
c)Ω
here * stand for multiplication
Explanation:
length of cylinder = 1.5 m
radius of cylinder = 1.1 cm
resistivity depends on the distance x from the left
............(i)
using equation
let dR is the resistance of thickness dx
where p(x) is resistivity l is length
a is area
.........................(2)
after integration
...............(3)
it is given Ωm
=
Ωm
(here * stand for multiplication )
on solving we get
Ωm
put each value of a and b and r value in equation 3rd we get
Ω
μΩ
FOR (b)
for mid point x = L/2
E = p(x)L
for x = L/2
for given current I = 1.75 A
so electric field
by substitute the values
we get;
(here * stand for multiplication )
c ).
75 cm means length will be half
that is x = L/2
integrate the second equation with upper limit L/2
Let resistance is
so after integration we get
substitute the value of a , b and L we get
Ω
for second half resistance
Ω
(here * stand for multiplication )
Answer:
Explanation:
Given that
J(r) = Br
We know that area of small element
dA = 2 π dr
I = J A
dI = J dA
Now by putting the values
dI = B r . 2 π dr
dI= 2π Br² dr
Now by integrating above equation
Given that
B= 2.35 x 10⁵ A/m³
r₁ = 2 mm
r₂ = 2+ 0.0115 mm
r₂ = 2.0115 mm
By putting the values
Answer:
a.
b.
Explanation:
The inertia can be find using
a.
now to find the torsion constant can use knowing the period of the balance
b.
T=0.5 s
Solve to K'