Archives: Solution Manual

446 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. where v is the speed of the weight so that […]

436 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. Computation. Substituting Eq. (3) into Eq. (1), and Eq. (4) […]

426 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. To determine the locomotive’s stopping distance, we recall that RxDPxd […]

416 Solutions Manual Problem 3.10 A hammer hits a mass m on the end of a metal bar. In Chapter 5, we will see that this imparts an instantaneous initial velocity v0 at xD0 to the mass. Treating the bar […]

406 Solutions Manual Chapter 3 Solutions Problem 3.1 Two curling stones A and B , with masses m and 4m , respectively, and initially at rest on the start line, are pushed by two identical forces Fover the distance d. […]

400 Solutions Manual Problem 2.305 Block B is released from rest at the position shown, and it has a constant acceleration downward a0D5:7 m=s2 . Determine the velocity and acceleration of block A at the instant that B touches the […]

390 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. where we have used the data vmax D2m=s and R0D3cm […]

380 Solutions Manual Problem 2.291 A skater is spinning with her arms completely stretched out and with an angular velocity !D60 rpm . Letting rbD0:55 ft , and `D2:2 ft and neglecting the change in ! as the skater lowers […]

370 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. Recall that we have vsD800 m=s , vaD2 3vs , […]

360 Solutions Manual Problem 2.278 An airplane is being tracked by a radar station at A . At the instant tD0 , the following data is recorded: rD15 km , D80ı , ✓D15ı , PrD350 km=h , P D0:002 rad=s […]

350 Solutions Manual Problem 2.271 A golfer chips the ball on a flat, level part of a golf course as shown. Letting ˛D23ı , ˇD41ı , and the initial speed be v0D6m=s , determine the x and y coordinates of […]

Problem 2.261 Referring to the problem of a robot arm catching an egg (Prob. 2.260), the strategy is that the arm and the egg must have the same velocity and the same position at the same time for the arm […]

330 Solutions Manual Problem 2.252 A crate A is being pulled up an inclined ramp by a winch. The rate of winding of the cord is controlled so as to hoist the crate up the incline with a constant speed […]

320 Solutions Manual Problem 2.242 The gun tackle shown is operated with the help of a horse. If the horse moves to the right at a constant speed of 7ft=s , determine the velocity and acceleration of B when the […]

310 Solutions Manual Problem 2.233 At the instant shown, EvBD5O{m=s . If ✓D25ı , determine the speed of A relative to B in order for A to travel only in the vertical direction while sliding over B. Solution Using the […]

300 Solutions Manual Problem 2.226 During practice, a player P punts a ball B with a speed v0D25 ft=s , at an angle ✓D60ı , and at a height h from the ground. Then the player sprints along a straight […]

290 Solutions Manual Problem 2.218 Reference frame A is translating relative to reference frame B with velocity EvA=B and acceleration EaA=B . A particle C appears to be stationary relative to frame A . What can you say about the […]

280 Solutions Manual Problem 2.211 The collar is mounted on the horizontal arm shown, which is originally rotating with the angular velocity !0 . Assume that after the cord is cut, the collar slides along the arm in such a […]

270 Solutions Manual P of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. where we have used the following numerical data: RrD187;500 […]

260 Solutions Manual Problem 2.196 A micro spiral pump consists of a spiral channel attached to a stationary plate. This plate has two ports, one for fluid inlet and another for outlet, the outlet being farther from the center of […]

250 Solutions Manual Problem 2.186 At a given instant, the merry-go-round is rotating with an angular velocity !D18 rpm . When the child is 0:45 m away from the spin axis, determine the second derivative with respect to time of […]

240 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. From the problem figure, we have that ds Dqdx2Cdy2:(5) Since […]

230 Solutions Manual Problem 2.168 A water jet is ejected from the nozzle of a fountain with a speed v0D12 m=s . Letting ˇD33ı , determine the rate of change of the speed of the water particles as soon as […]

220 Solutions Manual Problem 2.160 Particles A and B are moving in the plane with the same constant speed v , and their paths are tangent at P . Do these particles have zero acceleration at P ? If not, […]

210 Solutions Manual Problem 2.151 The position of the piston C , as a function of the crank angle  and the lengths of the crank AB and connecting rod BC , is given by yCDRcos C Lp1.R sin =L/2 […]

200 Solutions Manual Problem 2.141 A particle P is moving along the curve C , whose equation is given by y2x2.x 1/.2x 3/ D4x2Cy22x2; at a constant speed vc . For any position on the curve C for which the […]

190 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. CR ✓r.sin ✓O{Ccos ✓O|/P ✓2r.cos ✓O{Csin ✓O| /: (7) Collecting […]

180 Solutions Manual Problem 2.124 Consider the four points whose positions are given by the vectors ErAD 2O{C0O km , ErBD2O{C1O km , ErCD2O{C2O km , and ErDD2O{C3O km . Knowing that the magnitude of these vectors is constant and […]

170 Solutions Manual Problem 2.116 With reference to Probs. 2.113 and 2.115, assume that an experiment is conducted so that the measured value of xI is 10% smaller than what is predicted in the absence of viscous drag. Find the […]

160 Solutions Manual Problem 2.110 The jaguar A leaps from O at speed v0 and angle ˇ relative to the incline to intercept the panther B at C . The distance along the incline from O to C is R […]

150 Solutions Manual Problem 2.102 Suppose that you can throw a projectile at a large enough v0 so that it can hit a target a distance R downrange. Given that you know v0 and R , determine the general expressions […]

140 Solutions Manual Problem 2.92 An airplane flying horizontally at elevation hD60 m and at a constant speed v0D120 km=h drops a package P when passing over point O . Determine the time it takes for the package to hit […]

130 Solutions Manual Problem 2.85 The spool of paper used in a printing process is unrolled with velocity vp and acceleration ap . The thickness of the paper is h, and the outer radius of the spool at any instant […]

120 Solutions Manual Problem 2.78 As we will see in Chapter 3, the acceleration of a particle of mass m suspended by a linear spring with spring constant k and unstretched length L0 (when the spring length is equal to […]

110 Solutions Manual Problem 2.70 Heavy rains cause a particular stretch of road to have a coefficient of friction that changes as a function of location. Specifically, mea- surements indicate that the friction coefficient has a 3% decrease per meter. […]

100 Solutions Manual Problem 2.60 Referring to Example 2.8 on p. 56, and defining terminal velocity as the velocity at which a falling object stops accelerating, determine the skydiver’s terminal velocity without performing any integrations. Solution of McGraw-Hill, and must […]

90 Solutions Manual Problem 2.50 Approximately 1 h 15 min into the movie King Kong (the one directed by Peter Jackson), there is a scene in which Kong is holding Ann Darrow (played by the actress Naomi Watts) in his […]

80 Solutions Manual Problem 2.40 The following four problems refer to a car traveling between two stop signs, in which the car’s velocity is assumed to be given by v.t/ DŒ9 9cos.2t=5/çm=s for 0t5⇡s. Determine the time at which the […]

70 Solutions Manual of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. where, in obtaining the last of Eqs. (6), we have […]

60 Solutions Manual Problem 2.27 Find the x and y components of the acceleration in Example 2.3 (except for the plots) by differentiating the first of Eqs. (3) and the last of Eqs. (1) with respect to time and then […]

50 Solutions Manual where, referring to the problem statement, x.t/ Dx0⇥sin.2⇡!t/ 3sin.⇡!t /⇤:(5) of McGraw-Hill, and must be surrendered upon request of McGraw-Hill. Any duplication or distribution, either in print or electronic form, without the permission of McGraw-Hill, is prohibited. […]

40 Solutions Manual Problem 2.11 The position of a car as a function of time t, with t>0and expressed in seconds, is Er.t/ DŒ.5:98t2C0:139t30:0149t4/O{C.0:523t2C0:0122t 30:00131t4/O|çft: Determine the velocity, speed, and acceleration of the car for tD15 s. of McGraw-Hill, and […]

Chapter 2 Solutions Problem 2.1 If Evavg is the average velocity of a point P over a given time interval, is jEvavgj , the magnitude of the average velocity, equal to the average speed of Pover the time interval in […]

2210 Solutions Manual Substituting Eqs. (??) and (??) into Eq. (??), we obtain vAO{DP ˇpd2Ch2O{Cd.` R/ pd2Ch2P ˇh!ACR!dO|h.` R/ pd2Ch2P ˇCd! AO k: Equating components and solving the resulting three scalar equations for vA,!A, and P ˇ, we obtain vADdR!d […]

Dynamics 2e 2199 Problem 10.65 The shaft AB rotates with angular speed !0.t/ about the vertical axis. The uniform thin disk CD of radius R is rigidly attached to the end of the hori- zontal arm OG , which is […]

Dynamics 2e 2189 Problem 10.58 The uniform sphere of mass m and radius R can spin freely relative to the shaft AB , whose mass is negligible. The shaft AB precesses about the vertical axis with constant angular speed !0 […]

Dynamics 2e 2179 Problem 10.54 The L-shaped bar OCD is pin-connected at O to the vertical bar AB . The segments OC and CD are uniform, and each has mass m and length L . The bar AB rotates about […]

Dynamics 2e 2169 Problem 10.49 The thin uniform disk of radius R and mass m is mounted on the horizontal shaft, such that the mass center of the disk is on the axis of rotation. Due to an error in […]

Dynamics 2e 2159 we are viewing the bar AB in the plane of the angle ˇ , the spring force Fs has a component .Fs/k in that plane and a component .Fs/? perpendicular to that plane. Fortunately, the work of […]

Dynamics 2e 2149 Problem 10.41 The uniform bar AB of length L and mass m is attached to the T-bar support by a frictionless pin at A . The mass of the T-bar is negligible, and it rotates freely in […]