Rigid Bar $AB$ rotates about the fixed pin A with a constant angular velocity $.$ Slider C is moving in the vertical direction along a frictionless slot. Rigid Bars $AB$ and $BC$ are connected at $B$ by a hinge. Assume all hinges are frictionless.

How many degrees of freedom does this system have?

Determine constant angular velocity $($in rad$/$s$)$ when speed of point B is $2\frac{m}{s}.$ Use $L=1\mathrm{.}5.$

Determine magnitude of acceleration $($in $\frac{m}{s^2})$ at point $B$ when $=2ra\frac{d}{s}$ and a constant. Use $L=1\mathrm{.}5$

What two equations can describe the motion of the system? These equations can be determined by observing the geometrical constraints between points $A,B$ and C $.$ Hint: Use absolute motion analysis

Using Absolute Motion Analysis, determine speed of Slider $C$ in $\frac{m}{s}$ when $=60$ and $=2ra\frac{d}{s}$ Use $L=1\mathrm{.}5$

Rigid Bar $AB$ rotates about the fixed pin A with a constant angular velocity $.$ Slider C is moving in the vertical direction along a frictionless slot. Rigid Bars $AB$ and $BC$ are connected at $B$ by a hinge. Assume all hinges are frictionless.

How many degrees of freedom does this system have?

Determine constant angular velocity $($in rad$/$s$)$ when speed of point B is $2\frac{m}{s}.$ Use $L=1\mathrm{.}5.$

Determine magnitude of acceleration $($in $\frac{m}{s^2})$ at point $B$ when $=2ra\frac{d}{s}$ and a constant. Use $L=1\mathrm{.}5$

What two equations can describe the motion of the system? These equations can be determined by observing the geometrical constraints between points A$,$ B and C$.$ Hint: Use absolute motion analysis

Using Absolute Motion Analysis, determine speed of Slider $C$ in $\frac{m}{s}$ when $=60$ and $=2ra\frac{d}{s}$ Use $L=1\mathrm{.}5$