One cylinder would have a displacement of 21.2 cubic inches. By multiplying this displacement by the number of cylinders, in this case 6, the total displacement would be approximately 127 cubic inches. Area of circle pi x radius squared x length of stroke = one cylinder's displacement. be sure to use same units for area as well as stroke.
The technical answer is that displacement is the vector sum of the distances. An example to illustrate the difference in less technical terms, distance travelled in one direction added to the same distance in the opposite direction will result in the total distance being twice the distance of each leg but the total displacement is 0.
the object's displacement.
No. Distance is never negative, and total distance travelled doesn't decrease during a trip. The distance from A to B is the same as the distance from B to A. Displacement, on the other hand, can be negative, and can decrease during a trip. The displacement from A to B is the same magnitude, but opposite sign, as the displacement from B to A. An example would be if you went from your home to a friend's house 1 mile to the east. After you reach your friend's house, you have travelled a distance of 1 mile and your displacement from your starting position is 1 mile. When you come back home from your friends house, you travel a distance of 1 more mile. Your total distance travelled is now 2 miles, but your displacement from your starting location is zero (because you are back where you started.)
It is a total journey of 11 kilometres, resulting in a displacement of 5 km west.
If an object moves from one point to another and then returns to its original position, it will have a total displacement of zero. This is because displacement is a vector quantity that represents the change in position of an object from its starting point to its end point. When the object returns to its starting point, the displacements cancel each other out, resulting in a total displacement of zero.
The total displacement of the dog from the starting point can be calculated by finding the net displacement, which is the difference between the distances moved in each direction. In this case, the net displacement would be 6m north - 4m south, resulting in a total displacement of 2m north.
I have traveled 100 kilometers in total.
No, your total displacement (the straight line distance from start to finish, regardless of path taken) cannot be greater than your total distance (the sum of all the length of the path taken). Displacement can be shorter or equal to distance, but not greater.
The average velocity would be the total displacement over the total time interval. To calculate this, divide the total displacement by the total time to get the average velocity.
The total displacement in one oscillation is the maximum distance the object moves away from its equilibrium position in either direction before returning back to the equilibrium position. This total displacement is equal to twice the amplitude of the oscillation.
The total displacement is 8 km.
formula for displacement: A=(pi)r^2 A is Area Pi is 3.14 and R is the radius of the cylinder, this is the piston in Square inches. then multiply that by the distance the piston travels, that is the displacement of one cylinder to find total engine displacement multiply that by how many pistons are in the engine to get total engine displacement
To determine total displacement, you would need to calculate the vector sum of all individual displacement vectors. This can be achieved by adding together all the individual displacements in both the x and y directions. The total displacement will give the net change in position from the starting point to the final point.
If an object moves in a closed loop, returning to its initial position, its total displacement will be zero. For example, if you walk around a circular track and end up back at your starting point, your total displacement is zero.
The total displacement is 2km north, as the southward and northward displacements cancel each other out.
Average velocity is the total displacement divided by the time interval during which the displacement occurred. It indicates the overall change in position over time and is a vector quantity that includes both magnitude and direction.