Radians.
Another AnswerIf you are referring to 'angular displacement' in the context of three-phase transformer connections, then it's defined as the angle by which the secondary line voltages lag the primary line voltages, and is measured in (electrical) degrees.
Momentum = Mass X Velocity Velocity = Displacement/Time Dimension of Mass = M Dimension of Displacement = L Dimension of Time = T Therefore Dimension of Velocity = LT-1 Therefore Dimension of Momentum = MLT-1
Radians.Another AnswerIf you are referring to 'angular displacement' in the context of three-phase transformer connections, then it's defined as the angle by which the secondary line voltages lag the primary line voltages, and is measured in (electrical) degrees.
The dimension of angular velocity is in units of radians per second (rad/s) or revolutions per minute (RPM). It represents the rate of change of angular displacement with respect to time.
The magnitude of displacement can be calculated using the distance formula, which is the square root of the sum of the squares of the changes in position along each dimension. It is essentially the shortest distance between the initial and final positions of an object.
The second equation of motion describes the relationship between an object's final velocity and initial velocity, acceleration, and displacement. It is typically written as v^2 = u^2 + 2as, where v is final velocity, u is initial velocity, a is acceleration, and s is displacement. The dimensions of the second equation of motion are [L/T] for velocity, [L/T] for acceleration, and [L] for displacement.
Momentum = Mass X Velocity Velocity = Displacement/Time Dimension of Mass = M Dimension of Displacement = L Dimension of Time = T Therefore Dimension of Velocity = LT-1 Therefore Dimension of Momentum = MLT-1
It is angular displacement which may be measured in radians, or degrees-minutes-seconds. In 3-D it would be stradians
Weight has same dimension and unit as force. Distance has same dimension and unit as displacement. So weight * distance has same dimension and unit as force * displacement. Force * displacement is work done by the force. Work divided by time to do the work is Power. So weight * distance divided by time also has same dimension and unit as Power although it is not power. S.I. unit of weight * distance divided by time is Newton *meter/second or Nms-1 (in abbr.) It's dimensions are 1, 2, -3 in mass, length and time respectively. Note that given quantity's unit can't be joule/second or watt because weight * distance is not work done, only unit and dimension are same1 . 1. Two physical quantities may have same dimensions and units but that doesn't mean they refer to same quantity.
The Fourth dimension in Space is a real distance dimension r, completing the three vector displacement dimensions. Space is a quaternion with one real dimension and three vector dimensions, s= r + Ix + Jy + Kz, where I,J and K denote the vector dimensions. The real dimension r is related to time by r=ct where c is the speed of light. Einstein and Minkowski proposed in Relativity Theory a defective four dimension Space, where the fourth dimension is a vector Ict . This Space is essentially a two dimensional Space and does not exhibit the non-commuttive features of the quaternion Space.
Radians.Another AnswerIf you are referring to 'angular displacement' in the context of three-phase transformer connections, then it's defined as the angle by which the secondary line voltages lag the primary line voltages, and is measured in (electrical) degrees.
The dimension of angular velocity is in units of radians per second (rad/s) or revolutions per minute (RPM). It represents the rate of change of angular displacement with respect to time.
The magnitude of displacement can be calculated using the distance formula, which is the square root of the sum of the squares of the changes in position along each dimension. It is essentially the shortest distance between the initial and final positions of an object.
That depends on the shape. If it is a uniform configuration with simple sides or walls where accurate dimension are used then calculating the volume is more accurate. If the cavity is of a unusual shape such as the combustion chamber for a cylinder head on an engine, then water displacement is more accurate. With modern software, dimension for such a cavity can be calculated by computer. However, variation to the cavity when machined or cast will never be the same as the computer model. R. Clontz
The second equation of motion describes the relationship between an object's final velocity and initial velocity, acceleration, and displacement. It is typically written as v^2 = u^2 + 2as, where v is final velocity, u is initial velocity, a is acceleration, and s is displacement. The dimensions of the second equation of motion are [L/T] for velocity, [L/T] for acceleration, and [L] for displacement.
Angular displacement is measured in angles, usually degrees or radians. Especially when the unit radian is used, this unit is usually considered to be adimensional, since the radian is defined by the division (ratio) of two lengths: the length of an arc divided by the radius.
The dimension that controls time in falling body and projectile motion problems is vertical displacement, usually denoted as "y". Time affects how far an object falls or how far it travels horizontally in projectile motion. The equations of motion used to solve these problems involve time as a variable to calculate the position or velocity of the object at a given time.
Bore = the (internal) diameter of the cylnder hole in the engine block. Stroke = the distance the piston travels up (or down) the bore during its' cycle. If you multiply the bore dimension by the stroke dimension you will get the volumetric displacement of that cylinder. thus, Vd = (3.1416/4) (dia.) squared x Stroke