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∙ 12y agoTo find the horizontal distance of an object dropped by a plane, you can use the formula: distance = velocity x time. First, calculate the time it takes for the object to fall using the formula: time = √(2 x height / g), where g is the acceleration due to gravity (9.81 m/s^2). Then, multiply the time by the horizontal velocity of the plane to find the horizontal distance the object travels.
The bomb will fall vertically downward relative to the plane as both the bomb and the plane are in motion. The horizontal distance between the bomb and the plane will increase as the bomb falls due to the plane's forward velocity.
In a plane mirror, the image distance (di) is equal to the object distance (do). The image formed is virtual, upright, and the same size as the object, and it appears behind the mirror at the same distance as the object in front of the mirror.
When an object is dropped from a plane, it doesn't fall straight down due to the forward motion of the plane. The object inherits this forward velocity, resulting in a curved path known as projectile motion due to the influence of gravity and air resistance. This causes the object to fall at an angle rather than directly below the plane.
The distance between the image and the plane mirror is the same as the distance between the object and the mirror. Therefore, if the object is 15m away from the mirror, the image will also be 15m behind the mirror.
A parabolic path due to the combination of the object's forward motion from the plane and the downward force of gravity. This combination of forces causes the object to follow a curved path as it falls through the air.
If an object is rolling along a plane horizontal surface with no other forces acting on it, then rolled distance is directly proportional to the time taken.If an object is rolling along a plane horizontal surface with no other forces acting on it, then rolled distance is directly proportional to the time taken.If an object is rolling along a plane horizontal surface with no other forces acting on it, then rolled distance is directly proportional to the time taken.If an object is rolling along a plane horizontal surface with no other forces acting on it, then rolled distance is directly proportional to the time taken.
The bomb will fall vertically downward relative to the plane as both the bomb and the plane are in motion. The horizontal distance between the bomb and the plane will increase as the bomb falls due to the plane's forward velocity.
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In a plane mirror, the image distance (di) is equal to the object distance (do). The image formed is virtual, upright, and the same size as the object, and it appears behind the mirror at the same distance as the object in front of the mirror.
When an object is dropped from a plane, it doesn't fall straight down due to the forward motion of the plane. The object inherits this forward velocity, resulting in a curved path known as projectile motion due to the influence of gravity and air resistance. This causes the object to fall at an angle rather than directly below the plane.
The distance of the object from the mirror line should equal the distance of the image from the mirror line.
The distance between the image and the plane mirror is the same as the distance between the object and the mirror. Therefore, if the object is 15m away from the mirror, the image will also be 15m behind the mirror.
A parabolic path due to the combination of the object's forward motion from the plane and the downward force of gravity. This combination of forces causes the object to follow a curved path as it falls through the air.
The image formed by a plane mirror is a virtual, upright, and laterally inverted replica of the object. The distance between the object and its image in a plane mirror is twice the distance of the object from the mirror. The size of the image is equal to the size of the object.
The height of collimation is the height of the line of sight. It is the vertical distance of the horizontal plane through a telescope.
The graph is called a corrdinate plane. The horizontal is called the x-axis. The verticle is the y-axis.
single plane method:- let A and B be the two chosen instument station Q be the elevate object whose elevation is required A Band Q lies in the same vertical plane double plane method:- let A and B be the not in the same verticale plane as that of elevayed object Q they are in two vertical planes