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VOOZH | about |
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VOOZH | about |
Concave Lens is a diverging lens that scatters the incident light after refraction. Concave Lens is thinner in the middle and thicker at the edges. The images formed by a concave lens are virtual and erect. Power of the Concave lens is negative and it is widely used in the correction of myopia.In this article, we will learn in detail about the Concave Lens, its properties, image formation, characteristics of the image, formula for calculating power, and magnification along with its application.
Table of Content
Concave Lens, also known as a diverging lens, is a type of lens that is thinner at the center than at the edges. It is characterized by its inward-curved surfaces. Unlike a convex lens, which converges light rays, a concave lens causes parallel rays of light to diverge, or spread out.
A concave lens is a lens that is thinner at the center than at the edges, causing parallel rays of light to diverge as they pass through it.
Following are the some common examples of the concave lens:
A concave lens, like other lenses, consists of several parts and features that contribute to its optical properties. Here are the main parts of a concave lens:
Concave lenses, also known as diverging lenses, come in various shapes and forms depending on their specific applications and designs. The main types of concave lenses include:
- Biconcave Lens is characterized by two curved surfaces, both of which are concave.
- It is symmetrical, with the curves facing each other.
- This lens is thinner at the center than at the edges, and it diverges parallel rays of light.
- Planoconcave lens is a type of lens with one flat (plano) surface and one concave surface.
- The flat side is typically facing away from the center of the lens.
- It is a diverging lens, meaning it causes parallel rays of light to spread out.
- Convexo-concave lens has two different surfaces one as convex surface and other as concave surface.
- The convex side is typically facing outward.
- This lens type can be thought of as a combination of a convex lens and a concave lens, and its optical properties are determined by the radii of curvature of its surfaces.
- "Double Concave Lens" is interchangeable with the biconcave lens.
- It refers to a concave lens with two curved surfaces that are both concave.
- This lens type is frequently used for its diverging properties and is thinner in the middle than at the edges.
Concave lenses, being diverging lenses, possess several distinctive properties. Here are the key properties of concave lenses:
Following are the Sign Conventions for the Concave lens:
Following Table summarizes sign convention of Concave Lens:
Parameter | Sign |
|---|---|
Focal Length(f) | Negative |
Object Distance (u) | Negative (opposite the direction of incident light) |
Image distance (v) | Negative (opposite the direction of the incident light) |
Height (h) | Positive (upward) |
Ray Diagram is a graphical representation used to understand the image formation by lenses. Let's draw a ray diagram for a concave lens:
Object position | Image Position | Image nature | Image size |
|---|---|---|---|
At infinity | At F1 | Virtual and Erect | Highly diminished, point-sized |
Between Infinity and Optical Centre | Between Focus (F1) and Optical center (O) | Virtual and Erect | Diminished |
The lens formula is a mathematical relationship that describes the relationship between the object distance (u), the image distance (v), and the focal length (f) of a lens. The formula is applicable to both convex and concave lenses. For the concave lens , focal length is considered as negative.
The lens formula is given by:
(1/f)= (1/v)-(1/u)
Where:
- f represents focal length of the lens.
- v represents the image distance (distance from the lens to the image formed).
- u represents the object distance (distance from the lens to the object).
The magnification formula relates the height of an image to the height of an object in optics.
For a lens, including a concave lens, the magnification (often denoted as "m") is given by the following formula:
m = himage/hobject
Where:
- m represents the magnification.
- himage represents the height of the image formed by the lens.
- hobject represents the height of the object.
In the context of concave lenses, it's important to note that the magnification for such lenses is generally negative. This negative sign indicates that the image formed is virtual, upright, and on the same side as the object. Since concave lenses diverge light, the virtual image is produced by extending backward the divergent rays that appear to converge.
The magnification formula can also be expressed in terms of object distance (u) and image distance (v) for both convex and concave lenses.
The formula is as follows:
m = v/u
Where:
- m represents the magnification.
- u represents the object distance (distance from the object to the lens).
- v represents the image distance (distance from the image to the lens).
The negative sign in the formula indicates that the image is formed on the same side as the object for a diverging lens, such as a concave lens.
Power of Concave Lens is the ability of concave lens to diverge the incident rays. The formula for Power of concave lens is given by
P = 1/(-f)
where,
- P is Power
- F is focal length of the lens in m
Since, focal length of concave lens is negative therefore minus sign is placed before 'f' in the formula. This implies that Power of Concave Lens is negative
Below is the difference between the Concave and Convex lens:
Feature | Concave Lens | Convex Lens |
|---|---|---|
Shape | Thinner at the center, curved inward | Thicker at the center, curved outward |
Nature of Lens | Diverging lens | Converging lens |
Principal Focus | Virtual, on the same side as the incident light | Real, on the opposite side from the incident light |
Focal Length | Negative | Positive |
Effect on Parallel Rays | Rays diverge after passing through | Rays converge after passing through |
Image Formation | Virtual, upright, and diminished | May be Real or virtual, inverted or upright, and magnified or diminished |
Common Applications | Corrective eyeglasses for myopia, projectors, optical instruments with diverging needs | Corrective eyeglasses for hyperopia, cameras, magnifying glasses, optical instruments requiring convergence |
Learn, Difference Between Concave and Convex Lens
Concave lenses, also known as diverging lenses, have various applications in optics and technology. Their ability to diverge parallel rays of light is utilized in different contexts. Here are some common applications of concave lenses:
Also, Check
Example 1: An object is placed 20 cm in front of a concave lens with a focal length of -15 cm. Determine the image distance and describe the characteristics of the image formed.
Solution:
Given
- Object distance (u) = -20 cm (negative since the object is in front of the lens)
- Focal length (f) = -15 cm (negative for a concave lens)
Using the lens formula:
(1/f)= (1/v)-(1/u)
Substitute the known values:
(1/-15) = (1/v) - (1/-20)
Solve for v:
1/v = (1/-15) - (1/20)
1/v = -(7/60)
v = -8.57 cm
The image distance (v) is 8.57 cm. The negative sign indicates that the image is formed on the same side as the incident light. The image which we get will be virtual, upright, and diminished.
Example 2: A concave lens has a focal length (f) of -10 cm. An object is placed 20 cm in front of the lens. Determine the image distance (v).
Solution:
Given:
u = -20 cm
f = -15 cm
Using the lens formula:
(1/f) = (1/v)-(1/u)
Substitute the known values:
(1/-10) = (1/v)-(1/-20)
Solve for v:
1/v = (1/-10)-(1/-20)
1/v = -(2/20)
v = -10 cm
So, the image distance (v) is -10 cm.
Example 3: A concave lens with a focal length (f) of -12 cm is used to form an image. An object is placed 24 cm in front of the lens. Determine the image distance (v). Calculate the height of the image formed if the object has a height of 6 cm.
Solution:
1. Calculation of Image Distance (v):
u = -24 cm
f = -12 cm
Using the lens formula:
(1/f)= (1/v)-(1/u)
Substitute the known values:
(1/-12)= (1/v) -(1/-24)
Solve for v:
1/v = (1/-12)-(1/24)
1/v = -(3/24)
v = -8 cm
So, the image distance (v) is -8 cm.
2. Calculation of Image Height:
Given:
hobject = 6 cm
The magnification (m) is given by the formula:
m = v/u
Substitute the values:
m = (−8/−12)
The image height (himage) is related to the object height by the magnification:
himage = m × hobject
Substitute the values:
himage = (8/12) × 6 = 4 cm
So, the height of the image is 4 cm.
Example 4: Suppose you have a concave lens with an object placed 20 cm in front of it, and the image is formed at 10 cm. Find the focal length.
Solution:
Given:
u = -20 cm
v = -10 cm
Using the lens formula:
(1/f) = (1/v)-(1/u)
Substitute the known values:
(1/f) = (1/-10)-(1/-20)
Solve for f:
f = 1/((1/-10)-(1/-20)
f = 1/(-2/20)
f = 20/-2 cm
f = -10
So, the focal length is 10 cm.
Concave Lens - Practice Questions
Q1. A concave lens forms a virtual image when an object is placed 15 cm in front of it. If the image distance is -30 cm, find the focal length.
Q2. For a concave lens, an object is placed 25 cm in front of it, and the resulting image is formed at -50 cm. Determine the focal length.
Q3. A concave lens is used to form an image. If the object distance is -18 cm and the image distance is -9 cm, calculate the focal length.
Q4. Suppose a concave lens forms a virtual image when the object is placed 12 cm in front of it, and the image distance is -24 cm. Determine the focal length.
Q5. For a concave lens, the object distance is -30 cm, and the image is formed at -15 cm. Find the focal length.
