▼Part ATwo blocks, each of mass m = 7.60 kg, are connected by a massless rope and start sliding down a slope of incline 0= 40.0° at t = 0.000 s. The slope's top portion is arough surface whose coefficient of kinetic friction is μ = 0.350. At a distance d = 1.40 m from block A's initial position the slope becomes frictionless. (Figure 1)What isthe velocity of the blocks when block A reaches this frictional transition point? Assume that the blocks' width is negligible.Express your answer numerically in meters per second to four significant figures.► View Available Hint(s)V=||| ΑΣΦSubmitPart B Complete previous part(s)Part C Complete previous part(s)HProvide FeedbackrOvec?m/sCReviewU ENG ☎4xNext >7:49 PM7/12/2022 Principle of Linear Impulse and Momentum for a System ofsystem, yieldsΣmi(vi), + Σ/ F, dt = Emi(vi)2where m, is the ith particle's mass, v, is the ith particle's velocity,and F; is the external force that acts on the ith particle. Thisrelationship states that the sum of the initial linear momenta, at timet₁, and the impulses of all the external forces acting between times t₁and t2 is equal to the sum of the linear momenta of the system, at timeto. If the system has a mass center, G, the expression becomesm(ve)₁ + Σ ſt² F; dt = m(vc)2This expression allows the principle of linear impulse and momentumto be applied to a system of particles that is represente as a singleparticle.Figureyxd-1 of 1ParPartProvi

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▼ Part A Two blocks, each of mass m = 7.60 kg, are connected by a massless rope and start sliding down a slope of incline 0= 40.0° at t=0.000 s. The slope's top portion is a rough surface whose coefficient of kinetic friction is x=0.350. At a distance d = 1.40 m from block A's initial position the slope becomes frictionless. (Figure 1)What is the velocity of the blocks when block A reaches this frictional transition point? Assume that the blocks' width is negligible. Express your answer numerically in meters per second to four significant figures. ► View Available Hint(s) V= 195 ΑΣΦ Submit vec 3 ? m/s

▼ Part A Two blocks, each of mass m = 7.60 kg, are connected by a massless rope and start sliding down a slope of incline 0= 40.0° at t=0.000 s. The slope's top portion is a rough surface whose coefficient of kinetic friction is x=0.350. At a distance d = 1.40 m from block A's initial position the slope becomes frictionless. (Figure 1)What is the velocity of the blocks when block A reaches this frictional transition point? Assume that the blocks' width is negligible. Express your answer numerically in meters per second to four significant figures. ► View Available Hint(s) V= 195 ΑΣΦ Submit vec 3 ? m/s

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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