Frame a of a mechanical element.
All mechanical components are always connected together at frames. A frame is a coordinate system in the (mechanical) cut-plane of the connection point. The variables of the cut-plane are defined with respect to the corresponding frame_a and have the following meaning:
Potential variables: S : Rotation matrix describing frame_a with respect to the inertial frame, i.e. if ha is vector h resolved in frame_a and h0 is vector h resolved in the inertial frame, h0 = S*ha. r0: Vector from the origin of the inertial frame to the origin of frame_a, resolved in the inertial frame in [m] !!! (note, that all other vector quantities are resolved in frame_a!!!). v : Absolute (translational) velocity of frame_a, resolved in a, in [m/s]: v = transpose(S)*der(r0) w : Absolute angular velocity of frame_a, resolved in a, in [rad/s] : w = vec(transpose(S)*der(S)); Note, that | 0 -w3 w2 | skew(w) = | w3 0 -w1 | and w=vec(skew(w)) | -w2 w1 0 | a : Absolute translational acceleration of frame_a - gravity acceleration, resolved in a, in [m/s^2]: a = transpose(S)*( der(S*v) - ng*g ) (ng,g are defined in model MultiBody.Parts.InertialSystem). z : Absolute angular acceleration of frame_a, resolved in a, in [rad/s^2]: z = transpose(S)*der(S*w) Flow variables: f : Resultant cut-force acting at the origin of frame_a, resolved in a, in [N]. t : Resultant cut-torque with respect to the origin of frame_a, resolved in a, in [Nm].