Wiki User
∙ 14y agoThe answer depends on what h is supposed to represent.
Wiki User
∙ 6y agoThat depends on the amount of gravity, of course. Weight = mass x gravity. Near the Earth's surface, the value for gravity is approximately 9.8 (meters per square seconds).That depends on the amount of gravity, of course. Weight = mass x gravity. Near the Earth's surface, the value for gravity is approximately 9.8 (meters per square seconds).That depends on the amount of gravity, of course. Weight = mass x gravity. Near the Earth's surface, the value for gravity is approximately 9.8 (meters per square seconds).That depends on the amount of gravity, of course. Weight = mass x gravity. Near the Earth's surface, the value for gravity is approximately 9.8 (meters per square seconds).
9.8 m/s2 ---------------------- Yes this is the average value of acceleration due to gravity near by the surface of the earth. As we go higher and higher level this g value decreases and becomes almost negligible. Same way as we go deeper and deeper the g value decreases and at the centre of the earth its value becomes zero.
In geometry, a plane is a flat two-dimensional "surface" (similar to a sheet of paper, but with no thickness and no finite length or width). A plane is defined by three points, each of which forms a line with the other two points within the plane. In three dimensions, the simplest version of a plane would include all of the points with any x and y value that contain the same value for z.A plane is a flat surface or a 2-dimensional object, stretching to infinity in all directions.
It is 9.81 ms-2, although there are variations across the surface of the earth.
You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.You can set the chart to do that, so each value is shown, or you can have it as a plain line, that just links the value points but does not specifically say what they are.
Earth's surface actually has an overall neutral charge, with positive and negative charges balancing each other out. Lightning, for example, results from the buildup of charge imbalances in the atmosphere, not on the Earth's surface.
At the surface, 38% of its value at the Earth's surface.
At the surface, it is 2.64 times its value at the Earth's surface.
If the Earth were to stop rotating, the value of 'g' (acceleration due to gravity) would remain approximately the same at the Earth's surface. The rotation of the Earth does not significantly affect the gravitational pull experienced on the surface.
The accepted value of the acceleration of gravity near the surface of the Earth is approximately 9.81 m/s^2.
The acceleration of gravity at the 'surface' of Jupiter is 2.639 times its value at the Earth's surface.
The gravitational acceleration, g, decreases with altitude according to the inverse square law. At an altitude equal to the radius of the Earth (about 6371 km), the value of g would reduce to half of its surface value. This is because the gravitational attraction between the Earth and an object weakens as the distance between them increases.
The value of g (acceleration due to gravity) is not constant at all points on Earth's surface because it is influenced by factors such as the planet's rotation, elevation, and density of the underlying materials. These variations cause slight fluctuations in g, leading to different values in different locations.
Earth's gravity is approximately 9.81 m/s^2 at the surface, which is considered the standard for measuring the gravitational force on Earth. This value can vary slightly depending on location and altitude, but the overall range is within a few percentage points of the standard value.
The acceleration of gravity ... and therefor the weight of any object ... on thesurface of Mercury is 37.698% of its value on the surface of Earth. (rounded)
The acceleration of gravity on the surface of Mars, and therefore the weightof any object placed there, is 37.95% of its value on the Earth's surface.
Normally you can use a value of approximately 9.8 meters/second2. Please note that that applies to planet Earth, close to the surface; at a great distance from Earth, or near the surface of other planets, the value for gravity is quite different.