Obtain the Lagrangian equations of the PR(prismatic+rotarary) manipulator in the figure. write in standard form.(by using formulas in photo- find kinetic and potential energy for finding lagrange equations)(do not copy the answer from another answered question) The kinetic energy of the first link can be expressed aswhere v2 and w2 are the linear velocity of the link center ofmass and angular velocity of the link, respectively. We haveS10.7) (10.7) - M(q)4 + C(q, à + g(q).where C(a.4 eR° is a vector of velocity product terms witlthe lo X no matrix C(q. 4) linear in 4. gegravitational forces, and Mq) is an no X no symmetric, positivdefinite mass or inertia matrix.A matrix M is symmetric if My =Mj, where My is the entry in the th row and th column of M. Fmatrix Mis positive definite if v Mv > 0 holds for any nonzercvector v, This is true if the determinant and trace sum ofdiagonal elements) of M are positive.1K1(q, 4) =E Ris a vector c+a = 4yieldingwhere v1 and w1 are the linear velocity of the link center ofmass and angular velocity of the link, respectively. We have Ka(q. 4) = =m2(4; + (q>¢1>*) + h4i.(the%3DEquations (10.5) and (10.6) for the RP manipulator can bewritten in the standard form of equation (10.7), wherevi = 41The potential energy of the second link isMg) -"V2(q) = m2a,42 sin q1.[4,(mn+) con n.yielding the expressionThe Lagrangian for the system is L = K1 + K2 – V1 - V2:The standard form (10,7) is compact, but the term C(q. 9masks the fact that these velocity product terms can be derivefrom the inertia matrix Mg). If we consider the individualcomponents of this vector, C(q. 4 = (c(q. )..... Cnglq. 4).we find thatL-( +4+mr+ m)vi + m;) - a, sin q,(mr + g)K1(q, 4) =+Applying Lagrange's equations, we get(10.8)The potential energy of the first link is(10.5)(10.5)+ag(mirn + q2) cos qVi(q) = m1agr1 sin 1.(10.6) (10.6) uz = mzä2 – m2qrq¡ +a,m2 sinq1.The kinetic energy of the second link can be expressed as(wr-(10.8) a(q. 4)==K2(q, 4) =j-lwhere(10.9) (10.9) le) =(2M(g) , aMalq) _ aMy(q) \ Yom, ,I,m, ,I,a1

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Question

Obtain the Lagrangian equations of the PR(prismatic+rotarary) manipulator in the figure. write in standard form.(by using formulas in photo- find kinetic and potential energy for finding lagrange equations)

(do not copy the answer from another answered question)

The kinetic energy of the first link can be expressed as
where v2 and w2 are the linear velocity of the link center of
mass and angular velocity of the link, respectively. We have
S10.7) (10.7) - M(q)4 + C(q, à + g(q).
where C(a.4 eR° is a vector of velocity product terms witl
the lo X no matrix C(q. 4) linear in 4. ge
gravitational forces, and Mq) is an no X no symmetric, positiv
definite mass or inertia matrix.A matrix M is symmetric if My =
Mj, where My is the entry in the th row and th column of M. F
matrix Mis positive definite if v Mv > 0 holds for any nonzerc
vector v, This is true if the determinant and trace sum of
diagonal elements) of M are positive.
1
K1(q, 4) =
E Ris a vector c
+
a = 4
yielding
where v1 and w1 are the linear velocity of the link center of
mass and angular velocity of the link, respectively. We have Ka(q. 4) = =m2(4; + (q>¢1>*) + h4i.
(the
%3D
Equations (10.5) and (10.6) for the RP manipulator can be
written in the standard form of equation (10.7), where
vi = 41
The potential energy of the second link is
Mg) -"
V2(q) = m2a,42 sin q1.
[4,(mn+) con n.
yielding the expression
The Lagrangian for the system is L = K1 + K2 – V1 - V2:
The standard form (10,7) is compact, but the term C(q. 9
masks the fact that these velocity product terms can be derive
from the inertia matrix Mg). If we consider the individual
components of this vector, C(q. 4 = (c(q. )..... Cnglq. 4).
we find that
L-( +4+mr+ m)vi + m;) - a, sin q,(mr + g)
K1(q, 4) =
+
Applying Lagrange's equations, we get
(10.8)
The potential energy of the first link is
(10.5)
(10.5)
+ag(mirn + q2) cos q
Vi(q) = m1agr1 sin 1.
(10.6) (10.6) uz = mzä2 – m2qrq¡ +a,m2 sinq1.
The kinetic energy of the second link can be expressed as
(wr-
(10.8) a(q. 4)==
K2(q, 4) =
j-l
where
(10.9) (10.9) le) =(2M(g) , aMalq) _ aMy(q) \

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