Show that in case of heavy damping ( c > c c ) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Question

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Answer 1

Question

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

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Answer 2

Question

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

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Answer 3

Question

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

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Answer 4

Question

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

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Answer 5

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

Answer 6

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

Answer 7

Chapter 19.5, Problem 19.127P

(a)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Answer 8

(a)

Expert Solution

Explanation of Solution

Calculation:

Since (c>cc) which is over damped, the wavelength λ1 and λ2 is less than zero.

The expression for the differential equation of over damping as follows:

x=C1eλ1t+C2eλ2t (1)

Differentiate the above equation with respect to ‘t’.

v=dxdt=C1λ1eλ1t+C2λ2eλ2t (2)

Since the body is released with no initial velocity.

Substitute 0 for t, x0 for x and 0 for v in the equation (1).

x0=C1eλ1(0)+C2eλ2(0)x0=C1e0+C2e0x0=C1(1)+C2(1)x0=C1+C2C1=x0−C2 (3)

Substitute 0 for t, x0 for x and 0 for v in the equation (2).

dxdt=C1λ1eλ1t+C2λ2eλ2t0=C1λ1eλ1(0)+C2λ2eλ2(0)0=C1λ1(1)+C2λ2(1)0=C1λ1+C2λ2

Substitute x0−C2 for C1.

C1λ1+C2λ2=0(x0−C2)λ1+C2λ2=0x0λ1−C2λ1+C2λ2=0x0λ1−C2(λ1−λ2)=0x0λ1=C2(λ1−λ2)C2(λ2−λ1)=−x0λ1C2=−x0λ1(λ2−λ1)

Substitute −x0λ1(λ2−λ1) for C2 in the equation (3).

C1=x0−−x0λ1(λ2−λ1)=x0+x0λ1(λ2−λ1)=x0(λ2−λ1)+x0λ1λ2−λ1=x0λ2−x0λ1+x0λ1λ2−λ1=x0λ2λ2−λ1

Substitute −x0λ1(λ2−λ1) for C2 and x0λ2λ2−λ1 for C1 in equation (1).

x=x0λ2λ2−λ1eλ1t−x0λ1(λ2−λ1)eλ2t=x0λ2−λ1[λ2eλ1t−λ1eλ2t]

Apply boundary condition.

For x=0 when t≠∞.

0=x0λ2−λ1[λ2eλ1t−λ1eλ2t]λ2eλ1t−λ1eλ2t=0λ2eλ1t=λ1eλ2tλ2λ1=eλ2teλ1tλ2λ1=eλ2t−e−λ1tλ2λ1=eλ2t−λ1t (4)

As λ1 and λ2 is less than zero. So, λ1<λ2<0 then 0<λ2λ1<1 and λ2−λ1=0.

Thus the positive answer for the ‘t’ greater than 0 for the equation (4) cannot exist because the exponential (e) is increased to positive power be less than one which is not possible. Hence, the value of x is not becomes zero.

Show the graph of x versus t for the above solution as Figure (1).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 1

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

Answer 13

(b)

To determine

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

Answer 14

(b)

Expert Solution

Explanation of Solution

Calculation:

Since the body is started from O with arbitrary initial velocity.

Substitute 0 for t, 0 for x and v0 for v in the equation (1).

0=C1eλ1(0)+C2eλ2(0)0=C1e0+C2e00=C1(1)+C2(1)0=C1+C2C1=−C2 (5)

Substitute 0 for t, 0 for x, and v0 for v in the equation (2).

v=dxdt=C1λ1eλ1t+C2λ2eλ2tv0=C1λ1eλ1(0)+C2λ2eλ2(0)v0=C1λ1(1)+C2λ2(1)v0=C1λ1+C2λ2

Substitute −C2 for C1.

C1λ1+C2λ2=v0(−C2)λ1+C2λ2=v0−C2λ1+C2λ2=v0−C2(−λ2+λ1)=v0C2(λ2−λ1)=v0C2=v0λ2−λ1

Substitute v0λ2−λ1 for C2 in equation (5).

C1=−v0λ2−λ1

Substitute v0λ2−λ1 for C2 and −v0λ2−λ1 for C1 in equation (1).

x=−v0λ2−λ1eλ1t+v0λ2−λ1eλ2t=v0λ2−λ1[−eλ1t+eλ2t]=v0λ2−λ1[eλ2t−eλ1t]

Apply boundary condition.

For x=0 when t>0.

0=v0λ2−λ1[eλ2t−eλ1t]eλ2t−eλ1t=0eλ2t=eλ1t

For (c>cc), the wavelengths λ1≠λ2, thus no solution can exists for ‘t’ and x is not becomes zero when ‘t’ is greater than zero.

Show the graph of x versus t for the above solution as Figure (2).

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.5, Problem 19.127P , additional homework tip 2

Answer 15

(b)

Expert Solution

Answer 16

(b)

Expert Solution

Answer 17

Expert Solution

Answer 18

Ch. 19.1 - A particle moves in simple harmonic motion....Ch. 19.1 - Prob. 19.2P Ch. 19.1 - Prob. 19.3P Ch. 19.1 - Prob. 19.4P Ch. 19.1 - Prob. 19.5P Ch. 19.1 - Prob. 19.6P Ch. 19.1 - Prob. 19.7P Ch. 19.1 - Prob. 19.8P Ch. 19.1 - Prob. 19.9P Ch. 19.1 - Prob. 19.10P

Show that in case of heavy damping ( c > c c ) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Concept explainers

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Explanation of Solution

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

Explanation of Solution

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Chapter 19 Solutions

Show that in case of heavy damping ( c &gt; c c ) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Concept explainers

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.

Explanation of Solution

Show that in case of heavy damping (c>cc) a body never passes through its position of equilibrium O started from O with an arbitrary initial velocity.

Explanation of Solution

Want to see more full solutions like this?

Chapter 19 Solutions

Show that in case of heavy damping ( c > c c ) a body never passes through its position of equilibrium O if it is released with no initial velocity from an arbitrary position.