Show that ∂ 2 u ∂ t 2 − c 2 ∂ 2 u ∂ x 2 = − 4 c 2 ∂ ∂ ζ ∂ u ∂ η .

Question

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Answer 1

Question

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

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The force of the quadriceps (Fq) and force of the patellar tendon (Fp) is identical (i.e., 1000 N each). In the figure below angle in blue is Θ and the in green is half Θ (i.e., Θ/2). A) Calculate the patellar reaction force (i.e., R resultant vector is the sum of the horizontal component of the quadriceps and patellar tendon force) at the following joint angles: you need to provide a diagram showing the vector and its components for each part. a1) Θ = 160 degrees, a2) Θ = 90 degrees. NOTE: USE ONLY TRIGNOMETRIC FUNCTIONS (SIN/TAN/COS, NO LAW OF COSINES, NO COMPLICATED ALGEBRAIC EQUATIONS OR ANYTHING ELSE, ETC. Question A has 2 parts!

The force of the quadriceps (Fq) and force of the patellar tendon (Fp) is identical (i.e., 1000 N each). In the figure below angle in blue is Θ and the in green is half Θ (i.e., Θ/2). A) Calculate the patellar reaction force (i.e., R resultant vector is the sum of the horizontal component of the quadriceps and patellar tendon force) at the following joint angles: you need to provide a diagram showing the vector and its components for each part. a1) Θ = 160 degrees, a2) Θ = 90 degrees. NOTE: USE DO NOT USE LAW OF COSINES, NO COMPLICATED ALGEBRAIC EQUATIONS OR ANYTHING ELSE, ETC. Question A has 2 parts!

Answer 2

Question

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

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Answer 3

Question

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

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Answer 4

Question

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

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Answer 5

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Answer 6

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)

Subtract equation (XII) from (VI), and solve.

∂2u∂x2−1c2∂2u∂t2=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η−[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]=4∂2u∂η∂ζc2∂2u∂x2−∂2u∂t2=4c2∂2u∂η∂ζ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ(∂u∂η) (XIII)

Conclusion:

Therefore, ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Answer 7

Chapter 16, Problem 16.4P

To determine

Show that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Answer 8

Expert Solution & Answer

Answer to Problem 16.4P

Showed that ∂2u∂t2−c2∂2u∂x2=−4c2∂∂ζ∂u∂η.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given that two equations ζ=x−ct and η=x+ct.

Differentiate the equation ζ=x−ct with respect to x.

∂ζ∂x=∂∂x(x−ct)=1 (I)

Differentiate the equation η=x+ct with respect to x.

∂ζ∂x=∂∂x(x+ct)=1 (II)

The variable u is a function of ζ and η. Then it can be written as u=u(ζ,η).

Take the differential of u=u(ζ,η) with respect to x.

∂u∂x=∂∂x[u(ζ,η)]=∂u∂ζ∂ζ∂x+∂u∂η∂η∂x (III)

Use equation (I) and (II) in (III).

∂u∂x=∂u∂ζ+∂u∂η (IV)

Differentiate equation (IV) with respect to x.

∂2u∂x=∂∂x(∂u∂ζ+∂u∂η)=∂∂x(∂u∂ζ)+∂∂x(∂u∂η)=∂∂ζ(∂u∂ζ)∂ζ∂x+∂∂η(∂u∂ζ)∂η∂x+∂∂ζ(∂u∂η)∂ζ∂x+∂∂η(∂u∂η)∂η∂x (V)

Use equation (I) and (II) in (V).

∂2u∂x=∂∂ζ(∂u∂ζ)+∂∂η(∂u∂ζ)+∂∂ζ(∂u∂η)+∂∂η(∂u∂η)=∂2u∂ζ+∂2u∂η∂ζ+∂2u∂η+∂2u∂ζ∂η=∂2u∂ζ+2∂2u∂η∂ζ+∂2u∂η (VI)

Differentiate the equation ζ=x−ct with respect to t.

∂ζ∂t=∂∂t(x−ct)=−c (VII)

Differentiate the equation η=x+ct with respect to t.

∂ζ∂t=∂∂t(x+ct)=c (VIII)

Take the differential of u=u(ζ,η) with respect to t.

∂u∂t=∂∂t[u(ζ,η)]=∂u∂ζ∂ζ∂t+∂u∂η∂η∂t (IX)

Use equation (VII) and (VIII) in (IX).

∂u∂t=∂u∂ζ(−c)+∂u∂η(c)=c[−∂u∂ζ+∂u∂η] (X)

Differentiate equation (X) with respect to t.

∂2u∂t=∂∂tc(−∂u∂ζ+∂u∂η)=c[∂∂t(−∂u∂ζ)+∂∂t(∂u∂η)]=c[∂∂ζ(−∂u∂ζ)∂ζ∂t+∂∂η(−∂u∂ζ)∂η∂t+∂∂ζ(∂u∂η)∂ζ∂t+∂∂η(∂u∂η)∂η∂t] (XI)

Use equation (VII) and (VIII) in (XI).

∂2u∂t2=c[∂∂ζ(−∂u∂ζ)(−c)+∂∂η(−∂u∂ζ)c+∂∂ζ(∂u∂η)(−c)+∂∂η(∂u∂η)c]=c2[∂2u∂ζ−∂2u∂η∂ζ+∂2u∂η−∂2u∂ζ∂η]=c2[∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η]1c2∂2u∂t2=∂2u∂ζ−2∂2u∂η∂ζ+∂2u∂η (XII)