VECTOR MECH. FOR EGR: STATS & DYNAM (LL
VECTOR MECH. FOR EGR: STATS & DYNAM (LL
12th Edition
ISBN: 9781260663778
Author: BEER
Publisher: MCG
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Chapter 11.4, Problem 11.121P

Airplanes A and B are flying at the same altitude and are tracking the eye of hurricane C. The relative velocity of C with respect to A is vC/A = 350 km/h ⦫ 75°, and the relative velocity of C with respect to B is vC/B = 400 km/h ⦪ 40°. Determine (a) the relative velocity of B with respect to A, (b) the velocity of A if ground-based radar indicates that the hurricane is moving at a speed of 30 km/h due north, (c) the change in position of C with respect to B during a 15-min interval.

Fig. P11.121

Chapter 11.4, Problem 11.121P, Airplanes A and B are flying at the same altitude and are tracking the eye of hurricane C. The

(a)

Expert Solution
Check Mark
To determine

The relative velocity (vB/A) of B with respect to A.

Answer to Problem 11.121P

The relative velocity (vB/A) of B with respect to A is 405km/h_ at an angle of 11.53°_.

Explanation of Solution

Given Information:

The relative velocity (vC/A) of C with respect to A is 350km/h at an angle 75°.

The relative velocity (vC/B) of C with respect to B is 400km/h at an angle 40°.

Calculation:

Show the relative velocity vector diagram of airplanes with respect to hurricane as in Figure (1).

VECTOR MECH. FOR EGR: STATS & DYNAM (LL, Chapter 11.4, Problem 11.121P

Write the relative velocity of hurricane with respect to airplane A:

vC/A=vCvAvC=vC/A+vA (1)

Here, vC is velocity of hurricane, vC/A is relative velocity of hurricane with respect to airplane A, and vA is velocity of airplane A.

Write the relative velocity of hurricane with respect to airplane B:

vC/B=vCvBvC=vC/B+vB (2)

Here, vC is velocity of hurricane, vC/B is relative velocity of hurricane with respect to airplane B and vB is velocity of airplane B.

Equate equations (1) and (2).

vC/A+vA=vC/B+vBvBvA=vC/AvC/B (3)

Write the relative velocity of airplane B with respect to airplane A:

vB/A=vBvA (4)

Here, vB/A is relative velocity of airplane B with respect to airplane A.

Substitute equation (4) in equation (3).

vB/A=vC/AvC/B (5)

Calculate relative velocity B with respective to A by applying law of cosine for Figure (1).

vB/A2=vC/A2+vC/B22vC/AvC/Bcosγ

Here, γ for angle between the direction of the relative velocity of hurricane with respect to airplane A and the relative velocity of hurricane with respect to airplane B.

Substitute 350km/h for vC/A, 400km/h for vC/B, and 65° for γ.

vB/A2=(350)2+(400)22(350)(400)(cos65°)vB/A=164,166.8864vB/A=405.175km/h

Calculate the angle α by applying the law of sines for Figure (1):

sinαvC/B=sinγvB/A

Here, α is angle between the direction of relative velocity of hurricane with respect to airplane A and relative velocity of airplane B with respect to airplane A.

Substitute 400km/h for vC/B, 405.175km/h for vB/A, and 65° for γ.

sinα400=sin65°405.175sinα=sin65°405.175×400α=63.474°

Write the angle subtended by vB/A with the horizontal as:

θ=75°α

Here, angle subtended by vB/A with the horizontal is θ.

Substitute 63.474° for α.

θ=75°63.474°=11.526°11.53°

Therefore, the relative velocity (vB/A) of B with respect to A is 405km/h_ at an angle of 11.53°_.

(b)

Expert Solution
Check Mark
To determine

The velocity (vA) of A if ground based radar indicates that the hurricane is moving at a speed of 30km/h due north.

Answer to Problem 11.121P

The velocity (vA) of A if ground based radar indicates that the hurricane is moving at a speed of 30km/h due north is 379km/h_ at an angle 76.17°_.

Explanation of Solution

Given Information:

The relative velocity (vC/A) of C with respect to A is 350km/h at an angle 75°.

The relative velocity (vC/B) of C with respect to B is 400km/h at an angle 40°.

Calculation:

Rewrite Equation (1):

vA=vCvC/A (6)

Write vector vC/A in terms of components by resolving the vector into horizontal and vertical component.

vC/A=vC/Acos75ivC/Asin75j (7)

Choose direction of vC in the direction of unit vector of j since it moves in the direction of due north. Rewrite Equation (6) using Equation (7) as:

vA=vCj[vC/Acos75ivC/Asin75j] (8)

Substitute 30km/h for vC and 350km/h for vC/A in Equation (11) to find vC.

vA=30j[350cos75i350sin75j]=30j+90.587i+338.07j=(90.587km/h)i+(368.07km/h)j

Calculate the resultant velocity (vA) of airplane A with respect to ground as:

vA=(vA)x2+(vA)y2

Here, (vA)x is  x-component of vA and (vA)y is y-component of vA.

Substitute 90.587km/h for (vA)x and 368.07km/h for (vA)y.

vA=(90.587)2+(368.07)2=143,681.5295=379.0535379km/h

Calculate the angle (θA) of resultant velocity of airplane A with horizontal with respect to ground using the relation:

θA=tan1((vA)y(vA)x)

Substitute 90.587km/h for (vA)x and 368.07km/h for (vA)y.

θA=tan1(368.0790.587)=tan1(4.0632)=76.17°

Therefore, the velocity (vA) of A if ground based radar indicates that the hurricane is moving at a speed of 30km/h due north is 379km/h_ at an angle 76.17°_.

(c)

Expert Solution
Check Mark
To determine

The change in position (ΔrC/B) C with respect to B during a 15 min interval.

Answer to Problem 11.121P

The change in position (ΔrC/B) C with respect to B during a 15 min interval is 100km_ at an angle 40°_.

Explanation of Solution

Given Information:

The relative velocity (vC/A) of C with respect to A is 350km/h at an angle 75°.

The relative velocity (vC/B) of C with respect to B is 400km/h at an angle 40°.

Calculation:

Write the position of airplane B as:

vB=rB(r0)BtrB=vBt+(r0)B (8)

Here, rB is final position of airplane B, (r0)B is initial position of airplane B , vB is velocity of airplane B and t is time.

Write the position of hurricane as:

vC=rC(r0)CtrC=vCt+(r0)C (9)

Here, (r0)C is final position of hurricane is rC, initial position of hurricane and vC is velocity of hurricane.

Write the position of hurricane with respect to airplane B as:

rC/B=rCrB (10)

Here, rC/B is position of hurricane with respect to airplane B.

Use Equations (8) and (9) to rewrite Equation (10)

rC/B=vCt+(r0)CvBt(r0)B=(vCvB)t+[(r0)C(r0)B]=vC/Bt+[(r0)C(r0)B] (11)

Write the change in position of hurricane with respect to B as:

ΔrC/B=(rC/B)t2(rC/B)t1 (12)

Here, ΔrC/B is change in position of hurricane with respect to B, (rC/B)t2 position of hurricane with respect to B at an instant of time t2 and (rC/B)t1 is position of hurricane with respect to B at an instant of time t1.

Rewrite Equation (11) using Equation (12) as:

ΔrC/B=(rC/B)t2(rC/B)t1=vC/Bt2+[(r0)C(r0)B]vC/Bt1[(r0)C(r0)B]=vC/B(t2t1)=vC/B(Δt) (13)

Calculate the change in position (ΔrC/B) C with respect to B during a 15 min interval:

Substitute 400km/h for vC/B and 15 min for Δt in Equation (13)

ΔrC/B=400km/h(15min)(1h60min)=400(14)km=100km

Therefore, the change in position (ΔrC/B) C with respect to B during a 15 min interval is 100km_ at an angle 40°_.

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Chapter 11 Solutions

VECTOR MECH. FOR EGR: STATS & DYNAM (LL

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