A concave mirror is to form an image of the filament of a headlight lamp on a screen 8.50 m from the mirror. The filament is 6.00 mm tall, and the image is to be 37.5 cm tall. Part A: How far in front of the vertex of the mirror should the filament be placed?Part B: to what radius of curvature should you grind the mirror?
Answers
Answer:13.6 cm
Explanation:
Given
v(image distance)=-8.5 m
height of object=6 mm
height of image =37.5 cm
and magnification of concave mirror is given by
u=13.6 cm
so object is at a distance of 13.6 cm from mirror.
for focal length
f=-13.4 cm
thus radius of curvature of mirror is R=2f=26.8 cm
Final answer:
The filament of the headlight lamp should be placed about 0.85 m in front of the vertex of the mirror. The radius of curvature for the concave mirror should be approximately 0.85 m.
Explanation:
To determine how far in front of the vertex of the mirror the filament should be placed, we can use the mirror equation:
1/f = 1/do + 1/di
Where f is the focal length of the concave mirror, do is the object distance, and di is the image distance.
With the given information, we have:
do = ?
di = 8.50 m
Using the magnification formula:
magnification = -di/do
By substituting the values we know, we can solve for do:
37.5 cm / 6.00 mm = -8.50 m / do
Solving for do, we find that do ≈ - 0.85 m.
Since the object distance cannot be negative, we conclude that the filament of the headlight lamp should be placed about 0.85 m in front of the vertex of the mirror.
To find the radius of curvature for the concave mirror, we use the mirror formula:
1/f = 1/do + 1/di
With do = -0.85 m and di = 8.50 m, we can rearrange the formula to solve for f:
1/f = 1/-0.85 + 1/8.50
1/f ≈ -1.1765
Solving for f, we find that the focal length is approximately 0.85 m.
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A point charge q1 = 1.0 µC is at the origin and a point charge q2 = 6.0 µC is on the x axis at x = 1 m.(a) Find the electric force on charge q2.F12 = ? mN(b) Find the electric force on q1.F21 = ? mN(c) What would your answers for Parts (a) and (b) differ if q2 were -6.0 µC?
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Answers
Answer:
Observed time, t = 5.58 s
Explanation:
Given that,
Speed of light in a vacuum has the hypothetical value of, c = 18 m/s
Speed of car, v = 14 m/s along a straight road.
A home owner sitting on his porch sees the car pass between two telephone poles in 8.89 s.
We need to find the time the driver of the car measure for his trip between the poles. The relation between real and observed time is given by :
t is observed time.
So, the time observed by the driver of the car measure for his trip between the poles is 5.58 seconds.
Answers
Answer:
V = 1.69 * 10^6 V
Explanation:
Parameters given:
Electric field, E = 59V/m
Charge, q = 5.40C
We need to first find the distance between the electric charge and the point of consideration to be able to find the Electric potential difference.
Electric field is given as:
E = (kq/r^2)
k = Coulombs constant
=> r^2 = kq/E
=> r^2 = (9 * 10^9 * 5.4) / 59
r^2 = 8.2 * 10^8
r = 2.84 * 10^4 m
We can now find the Electric Potential by using:
V = kq/r
Hence,
V = (9 * 10^9 * 5.4) / (2.84 * 10^4)
V = 1.69 * 10^6 V
Answers
Answer:
......................
Answers
Answer:
The volume flow rate is 3.27m³/s
Diameter at the refinery is 88.64cm
Explanation:
Given
At the wellhead
Pipes diameter, d2 = 59.1cm = 0.591m
Flow speed of petroleum f2 = 11.9m/s
At the refinery,
Pipes diameter, d1 = ? Unknown
Flow speed of petroleum, f1 = 5.29m/s
Calculating the volume flow rate of petroleum along the pipe.
Volume flow rate = Flow rate * Area along the pipe
V = 11.9 * πd²/4
V = 11.9 * 22/7 * 0.591²/4
V = 3.265778m³/s
The volume flow rate is 3.27m³/s -------- Approximated
Since it's not stated if the flowrate is uniform throughout the pipe, we'll assume that flow rate is the same through out...
Using V1A1 = V2A2, where V1 & V2 Volume flow rate at both ends and area = Area of pipes at both ends
This gives;
V1A1 = V1A2
V1*πd1²/4 = V2 * πd2²/4 ----------- Divide through by π/4
So, we are left with
V1d1² = V2d2²
5.29 * d1²= 11.9 * 59.1²
d1² = 11.9 * 59.1²/5.29
d1² = 7857.172
d1 = √7857.172
d1 = 88.6406904305240618
d1 = 88.64cm --------------- Approximated
1 What is force ? Write its unit and mention
any
three effects of the force.
Answers
Force is a push or a pull that changes or trends to change the state of rest or uniform motion of an object or changes the direction or shape of an object. It causes objects to accelerate. SI unit is Newton.
1) Can change the state of an object : For example, pushing a heavy stone in order to move it.
2) May change the speed of an object if it is already moving. For example, catching a ball hit by a batsman.
3) May change the direction of motion of an object.
What is the normal force exerted by the surface on the bottom block? (Use the following as necessary: m and g as necessary.)
Answers
(a) The normal force exerted by the surface on the bottom block is N1 = 2mg.
Given that,
- A block m1 rests on a surface.
- A second block m2 sits on top of the first block.
- A horizontal force F applied to the bottom block pulls both blocks at constant velocity. Here m1 = m2 = m.
Based on the above information, we can say that the N1 is 2mg.
Learn more: brainly.com/question/17429689
Answer:
N = 2mg
Explanation:
Assuming the surface is horizontal
The surface must provide enough normal force to prevent the masses from accelerating in the vertical direction.