Unsteady waves: Difference between revisions

The starting point is the governing equations for stationary normal shocks (repeated here for convenience).

${\displaystyle {\rho }_1{u}_1={\rho }_2{u}_2}$

(Eq. 6.1)

${\displaystyle {\rho }_1{u}_1^2+p_1={\rho }_2{u}_2^2+p_2}$

(Eq. 6.2)

${\displaystyle h_1+\frac{1}{2}{u}_1^2=h_2+\frac{1}{2}{u}_2^2}$

(Eq. 6.3)

Shock moving to the right with the constant speed $W$ into a gas that is standing still. Moving with the shock, we would see a gas velocity ahead of the shock ${\displaystyle u_1=W}$, and the gas behind the shock moves to the right with the velocity ${\displaystyle u_2=W-u_p}$. Now, let's insert ${\displaystyle u_1}$ and ${\displaystyle u_2}$ in the stationary shock relations \ref{eq:stationary:cont} - \ref{eq:stationary:energy}.

${\displaystyle {\rho }_{1}W={\rho }_2(W-u_p)}$

(Eq. 6.4)

${\displaystyle {\rho }_1{W}^2+p_1={\rho }_2(W-u_p{)}^2+p_2}$

(Eq. 6.5)

${\displaystyle h_1+\frac{1}{2}{W}^2=h_2+\frac{1}{2}(W-u_p{)}^2}$

(Eq. 6.6)

Rewriting Eqn. \ref{eq:unsteady:cont}

${\displaystyle (W-u_p)=W\frac{{\rho }_1}{{\rho }_2}}$

(Eq. 6.7)

Inserting Eqn. \ref{eq:unsteady:cont:mod} in Eqn. \ref{eq:unsteady:mom} gives

${\displaystyle p_1+{\rho }_1{W}^2=p_2+{\rho }_2{W}^2{\left(\frac{{\rho }_1}{{\rho }_2}\right)}^2\Rightarrow p_2-p_1={\rho }_1{W}^2(1-\frac{{\rho }_1}{{\rho }_2})}$

(Eq. 6.8)

${\displaystyle W^2=\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_2}{{\rho }_1}\right)}$

(Eq. 6.9)

From the continuity equation \ref{eq:unsteady:cont}, we get

${\displaystyle W=(W-u_p)\left(\frac{{\rho }_2}{{\rho }_1}\right)}$

(Eq. 6.10)

Inserting Eqn. \ref{eq:unsteady:cont:modb} in Eqn. \ref{eq:unsteady:mom:mod} gives

${\displaystyle (W-u_p{)}^2=\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_1}{{\rho }_2}\right)}$

(Eq. 6.11)

Now, let's insert Eqns. \ref{eq:unsteady:mom:mod} and \ref{eq:unsteady:mom:modb} in the energy equation (Eqn. \ref{eq:unsteady:energy}).

${\displaystyle h_1+\frac{1}{2}\left[\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_2}{{\rho }_1}\right)\right]=h_2+\frac{1}{2}\left[\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_1}{{\rho }_2}\right)\right]}$

(Eq. 6.12)

${\displaystyle h=e+\frac{p}{\rho }}$

(Eq. 6.13)

${\displaystyle e_1+\frac{p_1}{{\rho }_1}+\frac{1}{2}\left[\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_2}{{\rho }_1}\right)\right]=e_2+\frac{p_2}{{\rho }_2}+\frac{1}{2}\left[\frac{p_2-p_1}{{\rho }_2-{\rho }_1}\left(\frac{{\rho }_1}{{\rho }_2}\right)\right]}$

(Eq. 6.14)

which can be rewritten as

${\displaystyle e_2-e_1=\frac{p_1+p_2}{2}(\frac{1}{{\rho }_1}-\frac{1}{{\rho }_2})}$

(Eq. 6.15)

Eqn \ref{eq:unsteady:hugonoit} is the same Hugoniot equation as we get for a stationary normal shock. The Hugoniot equation is a relation of thermodynamic properties over a shock. As the shock in the unsteady case is moving with a constant velocity, the frame of reference moving with the shock is an inertial frame and thus the same physical relations apply in the moving shock case as in the stationary shock case. The fact that the Hugoniot relation does not include any velocities or Mach numbers but only thermodynamic properties, the relation will be unchanged for a moving shock.

For a calorically perfect gas we have ${\displaystyle e=C_{v}T}$. Inserted in the Hugoniot relation above this gives

${\displaystyle C_v(T_2-T_1)=\frac{p_1+p_2}{2}({\nu }_1-{\nu }_2)}$

(Eq. 6.16)

where ${\displaystyle \nu =1/\rho }$

Now, using the ideal gas law ${\displaystyle T=p\nu /R}$ and ${\displaystyle C_v/R=1/(\gamma -1)}$ gives

${\displaystyle \left(\frac{1}{\gamma -1}\right)(p_2{\nu }_2-p_1{\nu }_1)=\frac{p_1+p_2}{2}({\nu }_1-{\nu }_2)}$ ${\displaystyle \iff }$ ${\displaystyle p_2(\frac{{\nu }_2}{\gamma -1}-\frac{{\nu }_1-{\nu }_2}{2})=p_1(\frac{{\nu }_1}{\gamma -1}+\frac{{\nu }_1-{\nu }_2}{2})}$

(Eq. 6.17)

From this result, we can derive a relation for the pressure ratio over the shock as a function of density ratio

${\displaystyle \frac{p_2}{p_1}=\frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{{\nu }_1}{{\nu }_2}}\right)-1}{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)-\left({\displaystyle \frac{{\nu }_1}{{\nu }_2}}\right)}}$

(Eq. 6.18)

${\displaystyle \nu =RT/p}$ and thus

${\displaystyle \frac{{\nu }_1}{{\nu }_2}=\frac{T_1}{T_2}\frac{p_2}{p_1}}$

(Eq. 6.19)

Eqn. \ref{eq:unsteady:density:ratio} in Eqn. \ref{eq:unsteady:hugonoit:c} gives

${\displaystyle \frac{p_2}{p_1}=\frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{T_1}{T_2}}{\displaystyle \frac{p_2}{p_1}}\right)-1}{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)-\left({\displaystyle \frac{T_1}{T_2}}{\displaystyle \frac{p_2}{p_1}}\right)}}$

(Eq. 6.20)

Now, we can get a relation for calculation of the temperature ratio over the moving shock as function of the shock pressure ratio

${\displaystyle \frac{T_2}{T_1}=\frac{p_2}{p_1}\left[\frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}{1+\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)}\right]}$

(Eq. 6.21)

Once again using the ideal gas law

${\displaystyle \frac{{\rho }_2}{{\rho }_1}=\frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}{1+\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)}}$

(Eq. 6.22)

Going back to the momentum equation

${\displaystyle p_2-p_1={\rho }_1{W}^2(1-\frac{{\rho }_1}{{\rho }_2})=\{W=M_s{a}_1\}={\rho }_1{M}_s^2{a}_1^2(1-\frac{{\rho }_1}{{\rho }_2})}$

(Eq. 6.23)

with ${\displaystyle a_1^2=\gamma p_1/{\rho }_1}$, we get

${\displaystyle \frac{p_2}{p_1}=\gamma M_s^2(1-\frac{{\rho }_1}{{\rho }_2})+1}$

(Eq. 6.24)

From the normal shock relations, we have

${\displaystyle \frac{{\rho }_1}{{\rho }_2}=\frac{2+(\gamma -1)M_s^2}{(\gamma +1)M_s^2}}$

(Eq. 6.25)

Eqn. \ref{eq:unsteady:Mach:b} in \ref{eq:unsteady:Mach:a} gives

${\displaystyle \frac{p_2}{p_1}=1+\left(\frac{2\gamma }{\gamma +1}\right)(M_s^2-1)}$

(Eq. 6.26)

or

${\displaystyle M_s=\sqrt{\left(\frac{\gamma +1}{2\gamma }\right)(\frac{p_2}{p_1}-1)+1}}$

(Eq. 6.27)

Eqn. \ref{eq:unsteady:Mach} with ${\displaystyle M_s=W/a_1}$

${\displaystyle W=a_1\sqrt{\left(\frac{\gamma +1}{2\gamma }\right)(\frac{p_2}{p_1}-1)+1}}$

(Eq. 6.28)

Let's try to find a relation for calculation of the induced velocity behind the moving shock. Once again, the starting point is the continuity equation for moving shocks (Eqn. \ref{eq:unsteady:cont}) repeated here for convenience

${\displaystyle {\rho }_{1}W={\rho }_2(W-u_p)}$

(Eq. 6.29)

The induced velocity appears on the right side of the continuity equation

${\displaystyle W({\rho }_1-{\rho }_2)=-{\rho }_2{u}_p}$

(Eq. 6.30)

${\displaystyle u_p=W(1-\frac{{\rho }_1}{{\rho }_2})}$

(Eq. 6.31)

From before we have a relation for $W$ as a function of pressure ratio and one for ${\displaystyle {\rho }_1/{\rho }_2}$, also as a function of pressure ratio.

Eqn. \ref{eq:unsteady:up:a} togheter with Eqns. \ref{eq:unsteady:W} and \ref{eq:unsteady:density:ratio} gives

${\displaystyle u_p=a_1\underset{I}{\underbrace{\sqrt{\left(\frac{\gamma +1}{2\gamma }\right)(\frac{p_2}{p_1}-1)+1}}}\underset{II}{\underbrace{[1-{\displaystyle \frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}{1+\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)}}]}}}$

(Eq. 6.32)

The equation subsets I and II can be rewritten as:

Term I:

${\displaystyle \sqrt{\left(\frac{\gamma +1}{2\gamma }\right)(\frac{p_2}{p_1}-1)+1}=\sqrt{\frac{\gamma +1}{2\gamma }[\left(\frac{p_2}{p_1}\right)+\left(\frac{\gamma -1}{\gamma +1}\right)]}}$

(Eq. 6.33)

Term II:

${\displaystyle [1-\frac{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}{1+\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)}]=\frac{1}{\gamma }(\frac{p_2}{p_1}-1)\frac{\left({\displaystyle \frac{2\gamma }{\gamma +1}}\right)}{\left({\displaystyle \frac{\gamma -1}{\gamma +1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}}$

(Eq. 6.34)

the rewritten terms I and II implemented, Eqn. \ref{eq:unsteady:up:b} becomes

${\displaystyle u_p=\frac{a_1}{\gamma }(\frac{p_2}{p_1}-1)\sqrt{\frac{\left({\displaystyle \frac{2\gamma }{\gamma +1}}\right)}{\left({\displaystyle \frac{\gamma -1}{\gamma +1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}}}$

(Eq. 6.35)

Since the region behind the moving shock is region 2, the induced flow Mach number is obtained as

${\displaystyle M_p=\frac{u_p}{a_2}=\frac{u_p}{a_1}\frac{a_1}{a_2}=\frac{u_p}{a_1}\sqrt{\frac{\gamma R{T}_1}{\gamma R{T}_2}}=\frac{u_p}{a_1}\sqrt{\frac{T_1}{T_2}}}$

(Eq. 6.36)

With ${\displaystyle up/a_1}$ from Eqn. \ref{eq:unsteady:up} and ${\displaystyle T_1/T_2}$ from Eqn. \ref{eq:unsteady:temperature:ratio}

${\displaystyle M_p=\frac{1}{\gamma }(\frac{p_2}{p_1}-1){\left(\frac{\left({\displaystyle \frac{2\gamma }{\gamma +1}}\right)}{\left({\displaystyle \frac{\gamma -1}{\gamma +1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}\right)}^{1/2}{\left(\frac{1+\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)}{\left({\displaystyle \frac{\gamma +1}{\gamma -1}}\right)\left({\displaystyle \frac{p_2}{p_1}}\right)+{\left({\displaystyle \frac{p_2}{p_1}}\right)}^2}\right)}^{1/2}}$

(Eq. 6.37)

There is a theoretical upper limit for the induced Mach number ${\displaystyle M_p}$

${\displaystyle \underset{p_2/p_1\to \mathrm{\infty }}{\lim }{M}_p\left(\frac{p_2}{p_1}\right)=\sqrt{\frac{2}{\gamma (\gamma -1)}}}$

(Eq. 6.38)

As can be seen, at the upper limit the induced Mach number is a function of ${\displaystyle \gamma }$ and for air (${\displaystyle \gamma =1.4}$) we get

${\displaystyle \underset{p_2/p_1\to \mathrm{\infty }}{\lim }{M}_p\left(\frac{p_2}{p_1}\right)\simeq 1.89}$

(Eq. 6.39)

When the incident shock wave reaches the wall, a shock propagating in the opposite direction is generated with a shock strength such that the velocity of the induced flow behind the incident shock is reduced to zero. The flow can not go through the wall and thus the velocity must be zero in the vicinity of the wall. The properties of the incident shock wave are directly related to the pressure ratio over the shock wave. Therefore, it would be convenient to have a relation between the reflected shock wave and incident shock wave.

The pressure ratio over the incident shock in Fig.~\ref{fig:reflection} can be obtained as

${\displaystyle \frac{p_2}{p_1}=1+\frac{2\gamma }{\gamma +1}(M_s^2-1)}$

(Eq. 6.40)

where ${\displaystyle M_s}$ is the wave Mach number, which is calculated as

${\displaystyle M_s=\frac{W}{a_1}}$

(Eq. 6.41)

In Eqn.~\ref{eq:incident:Mach:def}, ${\displaystyle W}$ is the speed with which the incident shock wave travels into region 1 and ${\displaystyle a_1}$ is the speed of sound in region 1 (see Fig.~\ref{fig:reflection}).

Solving Eqn.~\ref{eq:incident:pr} for ${\displaystyle M_s}$, we get

${\displaystyle M_s=\sqrt{\frac{\gamma +1}{2\gamma }(\frac{p_2}{p_1}-1)+1}}$

(Eq. 6.42)

Anderson derives the relations for calculation of the ratio ${\displaystyle T_2/T_1}$

${\displaystyle \frac{T_2}{T_1}=\frac{p_2}{p_1}\left(\frac{{\displaystyle \frac{\gamma +1}{\gamma -1}}+{\displaystyle \frac{p_2}{p_1}}}{1+{\displaystyle \frac{\gamma +1}{\gamma -1}}{\displaystyle \frac{p_2}{p_1}}}\right)}$

(Eq. 6.43)

From Eqn.~\ref{eq:incident:tr} it is easy to get the corresponding relation for ${\displaystyle {\rho }_2/{\rho }_1}$

${\displaystyle \frac{{\rho }_2}{{\rho }_1}=\frac{1+{\displaystyle \frac{\gamma +1}{\gamma -1}}{\displaystyle \frac{p_2}{p_1}}}{{\displaystyle \frac{\gamma +1}{\gamma -1}}+{\displaystyle \frac{p_2}{p_1}}}}$

(Eq. 6.44)

Anderson also shows how to obtain the induced velocity, ${\displaystyle u_p}$, behind the incident shock wave, {\emph{i.e.}} the velocity in region 2 (see Fig.~\ref{fig:reflection}).

${\displaystyle u_p=W(1-\frac{{\rho }_1}{{\rho }_2})=M_s{a}_1(1-\frac{{\rho }_1}{{\rho }_2})}$

(Eq. 6.45)

The pressure ratio over the reflected shock can be obtained from Eqn.~\ref{eq:incident:pr} by analogy

${\displaystyle \frac{p_5}{p_2}=1+\frac{2\gamma }{\gamma +1}(M_r^2-1)}$

(Eq. 6.46)

where ${\displaystyle M_r}$ is the Mach number of the reflected shock wave defined as

${\displaystyle M_r=\frac{W_r+u_p}{a_2}}$

(Eq. 6.47)

where ${\displaystyle W_r}$ is the speed of the reflected shock wave and ${\displaystyle a_2}$ is the speed of sound in region 2 (see Fig.~\ref{fig:reflection}).

Solving Eqn.~\ref{eq:reflected:pr} for ${\displaystyle M_r}$ gives

${\displaystyle M_r=\sqrt{\frac{\gamma +1}{2\gamma }(\frac{p_5}{p_2}-1)+1}}$

(Eq. 6.48)

The ratios ${\displaystyle T_5/T_2}$ and ${\displaystyle {\rho }_5/{\rho }_2}$ can be obtained from Eqns.~\ref{eq:incident:tr} and \ref{eq:incident:rr} by analogy

${\displaystyle \frac{T_5}{T_2}=\frac{p_5}{p_2}\left(\frac{{\displaystyle \frac{\gamma +1}{\gamma -1}}+{\displaystyle \frac{p_5}{p_2}}}{1+{\displaystyle \frac{\gamma +1}{\gamma -1}}{\displaystyle \frac{p_5}{p_2}}}\right)}$

(Eq. 6.49)

${\displaystyle \frac{{\rho }_5}{{\rho }_2}=\frac{1+{\displaystyle \frac{\gamma +1}{\gamma -1}}{\displaystyle \frac{p_5}{p_2}}}{{\displaystyle \frac{\gamma +1}{\gamma -1}}+{\displaystyle \frac{p_5}{p_2}}}}$

(Eq. 6.50)

The velocity in region 2 which is the same as the induced flow velocity behind the incident shock wave can be obtained as

${\displaystyle u_p=W_r(\frac{{\rho }_5}{{\rho }_2}-1)=M_r{a}_2(1-\frac{{\rho }_2}{{\rho }_5})}$

(Eq. 6.51)

With the relations for the incident shock wave and reflected shock wave defined, we now have the tools to derive a relation between the incident and reflected shock waves. The induced flow velocity $u_p$ calculated using the relation obtained for the incident shock wave must of course be the same as when calculated using reflected wave properties, {\emph{i.e.}} the result of Eqn.~\ref{eq:incident:up} is identical to that of Eqn.~\ref{eq:reflected:up}

${\displaystyle M_r{a}_2(1-\frac{{\rho }_2}{{\rho }_5})=M_s{a}_1(1-\frac{{\rho }_1}{{\rho }_2})}$

(Eq. 6.52)

rewriting gives

${\displaystyle M_r(1-\frac{{\rho }_2}{{\rho }_5})=M_s(1-\frac{{\rho }_1}{{\rho }_2})\frac{a_1}{a_2}}$

(Eq. 6.53)

Assuming calorically perfect gas gives ${\displaystyle a=\sqrt{\gamma RT}}$ and thus

${\displaystyle M_r(1-\frac{{\rho }_2}{{\rho }_5})=M_s(1-\frac{{\rho }_1}{{\rho }_2})\sqrt{\frac{T_1}{T_2}}}$

(Eq. 6.54)

Let's first look at the term on the left hand side of Eqn.~\ref{eq:relation:c}

${\displaystyle M_r(1-\frac{{\rho }_2}{{\rho }_5})}$

(Eq. 6.55)

Using the ${\displaystyle {\rho }_5/{\rho }_2}$ and ${\displaystyle p_2/p_5}$ from Eqns.~\ref{eq:reflected:rr} and~\ref{eq:reflected:pr} and simplifying gives

${\displaystyle M_r(1-\frac{{\rho }_2}{{\rho }_5})=\left(\frac{2}{\gamma +1}\right)\left(\frac{M_r^2-1}{M_r}\right)}$

(Eq. 6.56)

Using the same approach on the corresponding term for the incident shock wave on the right hand side of Eqn.~\ref{eq:relation:c} gives

${\displaystyle M_s(1-\frac{{\rho }_1}{{\rho }_2})=\left(\frac{2}{\gamma +1}\right)\left(\frac{M_s^2-1}{M_s}\right)}$

(Eq. 6.57)

Now, inserting~\ref{eq:relation:d} and~\ref{eq:relation:e} in Eqn.~\ref{eq:relation:c} gives

${\displaystyle \left(\frac{2}{\gamma +1}\right)\left(\frac{M_r^2-1}{M_r}\right)=\left(\frac{2}{\gamma +1}\right)\left(\frac{M_s^2-1}{M_s}\right)\sqrt{\frac{T_1}{T_2}}}$

(Eq. 6.58)

Simplifying and inverting gives

${\displaystyle \left(\frac{M_r}{M_r^2-1}\right)=\left(\frac{M_s}{M_s^2-1}\right)\sqrt{\frac{T_2}{T_1}}}$

(Eq. 6.59)

The rightmost term in Eqn.~\ref{eq:relation:g} (${\displaystyle \sqrt{T_2/T_1}}$) needs to be rewritten. Inserting~\ref{eq:incident:pr} in~\ref{eq:incident:tr} and expanding all terms gives

${\displaystyle \frac{T_2}{T_1}=\frac{2(\gamma +1)+(\gamma +1)(\gamma -1)M_s^2+4\gamma (M_s^2-1)+2\gamma (\gamma -1)M_s^2(M_s^2-1)}{(\gamma +1{)}^2{M}_s^2}=}$

${\displaystyle =\frac{2(\gamma +1)+(\gamma +1)(\gamma -1)M_s^2+4\gamma (M_s^2-1)}{(\gamma +1{)}^2{M}_s^2}+\frac{2(\gamma -1)}{(\gamma +1{)}^2}(M_s^2-1)\gamma =}$

${\displaystyle =\frac{2(\gamma +1)+(\gamma +1)(\gamma -1)M_s^2+4\gamma (M_s^2-1)-(2(\gamma -1)(M_s^2-1))}{(\gamma +1{)}^2{M}_s^2}}$

${\displaystyle \frac{2(\gamma -1)}{(\gamma +1{)}^2}(M_s^2-1)(\gamma +\frac{1}{M_s^2})}$

(Eq. 6.60)

Finally we end up with the following relation

${\displaystyle \frac{T_2}{T_1}=1+\frac{2(\gamma -1)}{(\gamma +1{)}^2}(M_s^2-1)(\gamma +\frac{1}{M_s^2})}$

(Eq. 6.61)

The temperature ratio over the incident shock wave is now totally defined by the incident Mach number ${\displaystyle M_s}$ and the ratio of specific heats ${\displaystyle \gamma }$. With~\ref{eq:relation:tr} in~\ref{eq:relation:g} we get the sought relation between the reflected and incident Mach numbers.

${\displaystyle \left(\frac{M_r}{M_r^2-1}\right)=\left(\frac{M_s}{M_s^2-1}\right)\sqrt{1+\frac{2(\gamma -1)}{(\gamma +1{)}^2}(M_s^2-1)(\gamma +\frac{1}{M_s^2})}}$

(Eq. 6.62)

It should be noted that Eqn.~\ref{eq:relation:final} is valid for calorically perfect gases only.

In the following we are going to derive the linear acoustic wave equation starting from the continuity and momentum equations on non-conservation differential form. The equations are repeated here for convenience.

${\displaystyle \frac{D\rho }{Dt}+\rho (\mathrm{\nabla }\cdot 𝐯)=0}$

(Eq. 6.63)

${\displaystyle \rho \frac{D𝐯}{Dt}+\mathrm{\nabla }p=0}$

(Eq. 6.64)

Remember that ${\displaystyle D/Dt}$ denotes the substantial derivative operator defined as follows

${\displaystyle \frac{D}{Dt}=\frac{\partial }{\partial t}+𝐯\cdot \mathrm{\nabla }}$

(Eq. 6.65)

where ${\displaystyle \partial /\partial t}$ is the local temporal derivative and ${\displaystyle 𝐯\cdot \mathrm{\nabla }}$ is the convective derivative.

We are going to analyze acoustic waves in one dimension, which means that the equations above reduces to

${\displaystyle \frac{\partial \rho }{\partial t}+u\frac{\partial \rho }{\partial x}+\rho \frac{\partial u}{\partial x}=0}$

(Eq. 6.66)

${\displaystyle \rho \frac{\partial u}{\partial t}+\rho u\frac{\partial u}{\partial x}+\frac{\partial p}{\partial x}=0}$

(Eq. 6.67)

Pressure is a thermodynamic property and thus it can be expressed as a function of two other thermodynamic properties. Let's express pressure as a function of density (${\displaystyle \rho }$) and entropy (${\displaystyle s}$).

${\displaystyle p=p(\rho ,s)\Rightarrow dp={\left(\frac{\partial p}{\partial \rho }\right)}_{s}d\rho +{\left(\frac{\partial p}{\partial s}\right)}_{\rho }ds}$

(Eq. 6.68)

Since weak acoustic waves are considered, entropy will be constant and thus ${\displaystyle ds=0}$, which means that

${\displaystyle dp={\left(\frac{\partial p}{\partial \rho }\right)}_{s}d\rho =a^{2}d\rho }$

(Eq. 6.69)

${\displaystyle \rho \frac{\partial u}{\partial t}+\rho u\frac{\partial u}{\partial x}+a^2\frac{\partial \rho }{\partial x}=0}$

(Eq. 6.70)

The acoustic perturbations can be described as small deviations around a reference state

${\displaystyle \begin{array}{cc}& \rho ={\rho }_{\mathrm{\infty }}+\Delta \rho \\ & p=p_{\mathrm{\infty }}+\Delta p\\ & T=T_{\mathrm{\infty }}+\Delta T\\ & u=u_{\mathrm{\infty }}+\Delta u=\{u_{\mathrm{\infty }}=0\}=\Delta u\\ \end{array}}$

Inserted in Eqns.~\ref{eq:unstady:acoustic:wave:cont} and \ref{eq:unstady:acoustic:wave:mom:b} and using the fact that derivatives of the constant reference state flow quantities are zero, we get

${\displaystyle \frac{\partial }{\partial t}(\Delta \rho )+\Delta u\frac{\partial }{\partial x}(\Delta \rho )+({\rho }_{\mathrm{\infty }}+\Delta \rho )\frac{\partial }{\partial x}(\Delta u)=0}$

(Eq. 6.71)

${\displaystyle ({\rho }_{\mathrm{\infty }}+\Delta \rho )\frac{\partial }{\partial t}(\Delta u)+({\rho }_{\mathrm{\infty }}+\Delta \rho )\Delta u\frac{\partial }{\partial x}(\Delta u)+a^2\frac{\partial }{\partial x}(\Delta \rho )=0}$

(Eq. 6.72)

In the same way as pressure, being a thermodynamic variable, can be expressed as a function of two other thermodynamic variables, so can the speed of sound. Once again we will select density and entropy as the two thermodynamic variables

${\displaystyle a^2=a^2(\rho ,s)}$

(Eq. 6.73)

and since entropy is constant

${\displaystyle a^2=a^2(\rho )}$

(Eq. 6.74)

Taylor expansion of ${\displaystyle a^2}$ around the reference state ${\displaystyle a_{\mathrm{\infty }}}$ with ${\displaystyle \Delta \rho =\rho -{\rho }_{\mathrm{\infty }}}$ gives

${\displaystyle a^2=a_{\mathrm{\infty }}^2+{(\frac{\partial }{\partial \rho }(a^2))}_{\mathrm{\infty }}\Delta \rho +{(\frac{{\partial }^2}{\partial {\rho }^2}(a^2))}_{\mathrm{\infty }}(\Delta \rho {)}^2+\cdots }$

(Eq. 6.75)

Inserted in Eqn.~\ref{eq:unstady:acoustic:wave:mom:pert}, we get

${\displaystyle ({\rho }_{\mathrm{\infty }}+\Delta \rho )\frac{\partial }{\partial t}(\Delta u)+({\rho }_{\mathrm{\infty }}+\Delta \rho )\Delta u\frac{\partial }{\partial x}(\Delta u)+[a_{\mathrm{\infty }}^2+{(\frac{\partial }{\partial \rho }(a^2))}_{\mathrm{\infty }}\Delta \rho +\cdots ]\frac{\partial }{\partial x}(\Delta \rho )=0}$

(Eq. 6.76)

The perturbations ${\displaystyle \Delta u}$ and ${\displaystyle \Delta \rho }$ are small, which implies that ${\displaystyle \Delta u\ll a_{\mathrm{\infty }}}$ and ${\displaystyle \Delta \rho \ll {\rho }_{\mathrm{\infty }}}$. This means that products of perturbations can be canceled and so can higher-order terms in the Taylor expansion of ${\displaystyle a^2}$. This means that the continuity and momentum equations reduces to

${\displaystyle \frac{\partial }{\partial t}(\Delta \rho )+{\rho }_{\mathrm{\infty }}\frac{\partial }{\partial x}(\Delta u)=0}$

(Eq. 6.77)

${\displaystyle {\rho }_{\mathrm{\infty }}\frac{\partial }{\partial t}(\Delta u)+a_{\mathrm{\infty }}^2\frac{\partial }{\partial x}(\Delta \rho )=0}$

(Eq. 6.78)

Before making the assumption that the perturbations are small compared to the corresponding reference state flow quantities and thus justifying the cancelation of products of perturbations from the equations, the flow equations were still the exact fully non-linear equations. Eqns.~\ref{eq:unstady:acoustic:wave:cont:linear}. and \ref{eq:unstady:acoustic:wave:mom:linear}, however, are approximations as several terms has been removed. The equations are linear and are good approximations as long as the perturbations are small. The smaller the perturbations, the better the approximation are the linear equations. Eqns.~\ref{eq:unstady:acoustic:wave:cont:linear} and \ref{eq:unstady:acoustic:wave:mom:linear} describes the motion induced in a gas by the passage of a sound wave. By combining the temporal derivative of Eqn.~\ref{eq:unstady:acoustic:wave:cont:linear} with the divergence of Eqn.~\ref{eq:unstady:acoustic:wave:mom:linear}, it is possible to obtain a wave equation describing the propagation of acoustic waves in a quiescent surrounding.

The temporal derivative of the continuity equation:

${\displaystyle \frac{{\partial }^2}{\partial t^2}(\Delta \rho )+{\rho }_{\mathrm{\infty }}\frac{{\partial }^2}{\partial x\partial t}(\Delta u)=0}$

(Eq. 6.79)

The divergence of the momentum equation:

${\displaystyle {\rho }_{\mathrm{\infty }}\frac{{\partial }^2}{\partial x\partial t}(\Delta u)+a_{\mathrm{\infty }}^2\frac{{\partial }^2}{\partial x^2}(\Delta \rho )=0}$

(Eq. 6.80)

The second term in the first equation is the same as the first term in the second equation. Substituting the term, the two equations reduces to one single equation

${\displaystyle \frac{{\partial }^2}{\partial t^2}(\Delta \rho )=a_{\mathrm{\infty }}^2\frac{{\partial }^2}{\partial x^2}(\Delta \rho )}$

(Eq. 6.81)

which is a one-dimensional form of the classic wave equation with the general solution

${\displaystyle \Delta \rho =F(x-a_{\mathrm{\infty }}t)+G(x+a_{\mathrm{\infty }}t)}$

(Eq. 6.82)

${\displaystyle F}$ and ${\displaystyle G}$ are arbitrary functions. The function ${\displaystyle F}$ describes the shape of a wave traveling in the positive ${\displaystyle x}$-direction at the speed of sound of the ambient gas and the function ${\displaystyle G}$ describes the shape of a wave traveling in the negative ${\displaystyle x}$-direction at the same speed. In Eqn.~\ref{eq:wave} ${\displaystyle \Delta \rho }$ appears with second derivatives in space and time. Let's differentiate the proposed solution (Eqn.~\ref{eq:wave:solution}) two times in time and space, respectively, and check that it is actually a valid solution to Eqn.~\ref{eq:wave}.

${\displaystyle \frac{\partial }{\partial t}(\Delta \rho )=\frac{\partial F}{\partial (x-a_{\mathrm{\infty }}t)}\frac{\partial (x-a_{\mathrm{\infty }}t)}{\partial t}+\frac{\partial G}{\partial (x+a_{\mathrm{\infty }}t)}\frac{\partial (x+a_{\mathrm{\infty }}t)}{\partial t}}$

(Eq. 6.83)

${\displaystyle \frac{\partial }{\partial t}(\Delta \rho )=-a_{\mathrm{\infty }}{F}^{\prime }+a_{\mathrm{\infty }}{G}^{\prime }}$

(Eq. 6.84)

${\displaystyle \frac{{\partial }^2}{\partial t^2}(\Delta \rho )=-a_{\mathrm{\infty }}\frac{\partial F^{\prime }}{\partial (x-a_{\mathrm{\infty }}t)}\frac{\partial (x-a_{\mathrm{\infty }}t)}{\partial t}+a_{\mathrm{\infty }}\frac{\partial G^{\prime }}{\partial (x+a_{\mathrm{\infty }}t)}\frac{\partial (x+a_{\mathrm{\infty }}t)}{\partial t}}$

(Eq. 6.85)

${\displaystyle \frac{{\partial }^2}{\partial t^2}(\Delta \rho )=a_{\mathrm{\infty }}^2{F}^{″}+a_{\mathrm{\infty }}^2{G}^{″}}$

(Eq. 6.86)

${\displaystyle \frac{\partial }{\partial x}(\Delta \rho )=\frac{\partial F}{\partial (x-a_{\mathrm{\infty }}t)}\frac{\partial (x-a_{\mathrm{\infty }}t)}{\partial x}+\frac{\partial G}{\partial (x+a_{\mathrm{\infty }}t)}\frac{\partial (x+a_{\mathrm{\infty }}t)}{\partial x}}$

(Eq. 6.87)

${\displaystyle \frac{\partial }{\partial x}(\Delta \rho )=F^{\prime }+G^{\prime }}$

(Eq. 6.88)

${\displaystyle \frac{{\partial }^2}{\partial x^2}(\Delta \rho )=\frac{\partial F^{\prime }}{\partial (x-a_{\mathrm{\infty }}t)}\frac{\partial (x-a_{\mathrm{\infty }}t)}{\partial x}+\frac{\partial G^{\prime }}{\partial (x+a_{\mathrm{\infty }}t)}\frac{\partial (x+a_{\mathrm{\infty }}t)}{\partial x}}$

(Eq. 6.89)

${\displaystyle \frac{{\partial }^2}{\partial x^2}(\Delta \rho )=F^{″}+G^{″}}$

(Eq. 6.90)

Eqns. \ref{eq:wave:ddt} and \ref{eq:wave:ddx} inserted Eqn. \ref{eq:wave} gives

${\displaystyle a_{\mathrm{\infty }}^2{F}^{″}+a_{\mathrm{\infty }}^2{G}^{″}=a_{\mathrm{\infty }}^2(F^{″}+G^{″})}$

(Eq. 6.91)

which shows that Eqn. \ref{eq:wave:solution} is a valid solution to the wave equation.

${\displaystyle F}$ and ${\displaystyle G}$ are arbitrary functions and thus ${\displaystyle G=0}$ is a valid solution, which gives

${\displaystyle \Delta \rho (x,t)=F(x-a_{\mathrm{\infty }}t)}$

(Eq. 6.92)

If ${\displaystyle \Delta \rho }$ is constant, i.e. a wave with constant amplitude, we see from Eqn.~\ref{eq:wave:solution:F} that ${\displaystyle (x-a_{\mathrm{\infty }}t)}$ is constant and thus

${\displaystyle x=a_{\mathrm{\infty }}t+c\Rightarrow \frac{dx}{dt}=a_{\mathrm{\infty }}}$

(Eq. 6.93)

From Eqn.~\ref{eq:wave:solution:F}, we get

${\displaystyle \frac{\partial }{\partial t}(\Delta \rho )=-a_{\mathrm{\infty }}{F}^{\prime }}$

(Eq. 6.94)

${\displaystyle \frac{\partial }{\partial x}(\Delta \rho )=F^{\prime }}$

(Eq. 6.95)

and thus

${\displaystyle \frac{\partial }{\partial x}(\Delta \rho )=-\frac{1}{a_{\mathrm{\infty }}}\frac{\partial }{\partial t}(\Delta \rho )}$

(Eq. 6.96)

which gives a relation between the temporal derivative of ${\displaystyle \Delta \rho }$ and the spatial derivative of ${\displaystyle \Delta \rho }$. With Eqn.~\ref{eq:wave:solution:F:b}, the linearized momentum equation Eqn.~\ref{eq:unstady:acoustic:wave:mom:linear} can be rewritten as follows

${\displaystyle \frac{\partial }{\partial t}(\Delta u)=-\frac{a_{\mathrm{\infty }}^2}{{\rho }_{\mathrm{\infty }}}\frac{\partial }{\partial x}(\Delta \rho )=\{\frac{\partial }{\partial x}(\Delta \rho )=-\frac{1}{a_{\mathrm{\infty }}}\frac{\partial }{\partial t}(\Delta \rho )\}=\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\frac{\partial }{\partial t}(\Delta \rho )\Rightarrow }$

(Eq. 6.97)

${\displaystyle \frac{\partial }{\partial t}(\Delta u-\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho )=0\Rightarrow \Delta u-\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho =const}$

(Eq. 6.98)

In an undisturbed gas ${\displaystyle \Delta u=\Delta \rho =0}$ and thus

${\displaystyle \Delta u-\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho =0}$

(Eq. 6.99)

or

${\displaystyle \Delta u=\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho }$

(Eq. 6.100)

If instead ${\displaystyle F}$ is set to zero and ${\displaystyle G}$ is non-zero, we get

${\displaystyle \Delta u=-\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho }$

(Eq. 6.101)

${\displaystyle {\left(\frac{\partial p}{\partial \rho }\right)}_s=a^2\Rightarrow \Delta p=a_{\mathrm{\infty }}^2\Delta \rho }$

(Eq. 6.102)

Acoustic wave traveling in the positive ${\displaystyle x}$-direction:

${\displaystyle \Delta u=\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho =\frac{1}{a_{\mathrm{\infty }}{\rho }_{\mathrm{\infty }}}\Delta p}$

(Eq. 6.103)

Acoustic wave traveling in the negative ${\displaystyle x}$-direction:

${\displaystyle \Delta u=-\frac{a_{\mathrm{\infty }}}{{\rho }_{\mathrm{\infty }}}\Delta \rho =-\frac{1}{a_{\mathrm{\infty }}{\rho }_{\mathrm{\infty }}}\Delta p}$

(Eq. 6.104)

Starting point: the governing flow equations on partial differential form

Continuity equation:

${\displaystyle \frac{\partial \rho }{\partial t}+u\frac{\partial \rho }{\partial x}+\rho \frac{\partial u}{\partial x}=0}$

(Eq. 6.105)

Momentum equation:

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}+\frac{1}{\rho }\frac{\partial p}{\partial x}=0}$

(Eq. 6.106)

Any thermodynamic property can be expressed as a function of two other thermodynamic properties. This means that we can get density as a function of pressure and entropy: ${\displaystyle \rho =\rho (p,s)}$ and therefore

${\displaystyle d\rho ={\left(\frac{\partial \rho }{\partial p}\right)}_{s}dp+{\left(\frac{\partial \rho }{\partial s}\right)}_{p}ds}$

(Eq. 6.107)

Assuming isentropic flow ${\displaystyle ds=0}$ gives

${\displaystyle d\rho ={\left(\frac{\partial \rho }{\partial p}\right)}_{s}dp}$

(Eq. 6.108)

${\displaystyle \begin{array}{cc}& \frac{\partial \rho }{\partial t}={\left(\frac{\partial \rho }{\partial p}\right)}_s\frac{\partial p}{\partial t}=\frac{1}{a^2}\frac{\partial p}{\partial t}\\ & \\ & \frac{\partial \rho }{\partial x}={\left(\frac{\partial \rho }{\partial p}\right)}_s\frac{\partial p}{\partial x}=\frac{1}{a^2}\frac{\partial p}{\partial x}\end{array}}$

(Eq. 6.109)

Now, insert \ref{eq:rhotop} in \ref{eq:pde:cont} gives

${\displaystyle \frac{\partial p}{\partial t}+u\frac{\partial p}{\partial x}+\rho a^2\frac{\partial u}{\partial x}=0}$

(Eq. 6.110)

Dividing \ref{eq:pde:cont:b} by ${\displaystyle \rho a}$ gives

${\displaystyle \frac{1}{\rho a}(\frac{\partial p}{\partial t}+u\frac{\partial p}{\partial x})+a\frac{\partial u}{\partial x}=0}$

(Eq. 6.111)

A slightly modified form of the momentum equation is obtained by multiplying and dividing the last term by ${\displaystyle a}$

${\displaystyle \frac{\partial u}{\partial t}+u\frac{\partial u}{\partial x}+\frac{1}{\rho a}\left(a\frac{\partial p}{\partial x}\right)=0}$

(Eq. 6.112)

If the continuity equation on the form \ref{eq:pde:cont:c} is added to the momentum equation on the form \ref{eq:pde:mom:c}, we get

${\displaystyle [\frac{\partial u}{\partial t}+(u+a)\frac{\partial u}{\partial x}]+\frac{1}{\rho a}[\frac{\partial p}{\partial t}+(u+a)\frac{\partial p}{\partial x}]=0}$

(Eq. 6.113)

If, instead, the continuity equation on the form \ref{eq:pde:cont:c} is subtracted from the momentum equation on the form \ref{eq:pde:mom:c}, we get

${\displaystyle [\frac{\partial u}{\partial t}+(u-a)\frac{\partial u}{\partial x}]+\frac{1}{\rho a}[\frac{\partial p}{\partial t}+(u-a)\frac{\partial p}{\partial x}]=0}$

(Eq. 6.114)

Since ${\displaystyle u=u(x,t)}$, we have from the definition of a differential

${\displaystyle du=\frac{\partial u}{\partial t}dt+\frac{\partial u}{\partial x}dx=\frac{\partial u}{\partial t}dt+\frac{\partial u}{\partial x}\frac{dx}{dt}dt}$

(Eq. 6.115)

Now, let ${\displaystyle dx/dt=u+a}$

${\displaystyle du=\frac{\partial u}{\partial t}dt+(u+a)\frac{\partial u}{\partial x}dt=[\frac{\partial u}{\partial t}+(u+a)\frac{\partial u}{\partial x}]dt}$

(Eq. 6.116)

which is the change of ${\displaystyle u}$ in the direction ${\displaystyle dx/dt=u+a}$

In the same way

${\displaystyle dp=\frac{\partial p}{\partial t}dt+\frac{\partial p}{\partial x}dx=\frac{\partial p}{\partial t}dt+\frac{\partial p}{\partial x}\frac{dx}{dt}dt}$

(Eq. 6.117)

and thus, in the direction ${\displaystyle dx/dt=u+a}$

${\displaystyle dp=\frac{\partial p}{\partial t}dt+(u+a)\frac{\partial p}{\partial x}dt=[\frac{\partial p}{\partial t}+(u+a)\frac{\partial p}{\partial x}]dt}$

(Eq. 6.118)

If we go back and examine Eqn. \ref{eq:nonlin:a}, we see that Eqns. \ref{eq:du:b} and \ref{eq:dp:b} appear in the equation and thus it can now be rewritten as follows

${\displaystyle \frac{du}{dt}+\frac{1}{\rho a}\frac{dp}{dt}=0\Rightarrow du+\frac{dp}{\rho a}=0}$

(Eq. 6.119)

Eqn. \ref{eq:nonlin:a:ode} applies along a ${\displaystyle C^{+}}$ characteristic, i.e., a line in the direction ${\displaystyle dx/dt=u+a}$ in ${\displaystyle xt}$-space and is called the compatibility equation along the ${\displaystyle C^{+}}$ characteristic. If we instead chose a ${\displaystyle C^{-}}$ characteristic, i.e., a line in the direction ${\displaystyle dx/dt=u-a}$ in ${\displaystyle xt}$-space, we get

${\displaystyle du=[\frac{\partial u}{\partial t}+(u-a)\frac{\partial u}{\partial x}]dt}$

(Eq. 6.120)

${\displaystyle dp=[\frac{\partial p}{\partial t}+(u-a)\frac{\partial p}{\partial x}]dt}$

(Eq. 6.121)

which can be identified as subsets of Eqn. \ref{eq:nonlin:b} and thus

${\displaystyle \frac{du}{dt}-\frac{1}{\rho a}\frac{dp}{dt}=0}$

(Eq. 6.122)

In order to fulfil the relation above, either ${\displaystyle du=dp=0}$ or

${\displaystyle du-\frac{dp}{\rho a}=0}$

(Eq. 6.123)

Eqn. \ref{eq:nonlin:b:ode} applies along a ${\displaystyle C^{-}}$ characteristic, i.e., a line in the direction ${\displaystyle dx/dt=u-a}$ in ${\displaystyle xt}$-space and is called the compatibility equation along the ${\displaystyle C^{-}}$ characteristic.

So, what we have done now is that we have have found paths through a point (${\displaystyle x_1}$, ${\displaystyle t_1}$) along which the governing partial differential equations Eqns. \ref{eq:nonlin:a} and \ref{eq:nonlin:b} reduces to the ordinary differential equations \ref{eq:nonlin:a:ode} and \ref{eq:nonlin:b:ode}. The ${\displaystyle C^{+}}$ and ${\displaystyle C^{-}}$ characteristic lines are physically the paths of right- and left-running sound waves in the ${\displaystyle xt}$-plane.

If the compatibility equations are integrated along respective characteristic line, i.e., integrate \ref{eq:nonlin:a:ode} along the ${\displaystyle C^{+}}$ characteristic and \ref{eq:nonlin:b:ode} along the ${\displaystyle C^{-}}$ characteristic, we get the Riemann invariants ${\displaystyle J^{+}}$ and ${\displaystyle J^{-}}$.

${\displaystyle J^{+}=u+\int \frac{dp}{\rho a}=const}$

(Eq. 6.124)

${\displaystyle J^{-}=u-\int \frac{dp}{\rho a}=const}$

(Eq. 6.125)

The Riemann invariants are constants along the associated characteristic line.

We have assumed isentropic flow and thus we may use the isentropic relations

${\displaystyle p=C_1{T}^{\gamma /(\gamma -1)}=C_2{a}^{2\gamma /(\gamma -1)}}$

(Eq. 6.126)

where ${\displaystyle C_1}$ and ${\displaystyle C_2}$ are constants. Differentiating Eqn. \ref{eq:isentropic:a} gives

${\displaystyle dp=C_2\left(\frac{2\gamma }{\gamma -1}\right)a^{[2\gamma /(\gamma -1)-1]}da}$

(Eq. 6.127)

Now, if we further assume the gas to be calorically perfect

${\displaystyle a^2=\gamma RT=\frac{\gamma p}{\rho }\Rightarrow \rho =\frac{\gamma p}{a^2}}$

(Eq. 6.128)

Eqn. \ref{eq:isentropic:a} in \ref{eq:isentropic:c} gives

${\displaystyle \rho =C_2\gamma a^{[2\gamma /(\gamma -1)-2]}}$

(Eq. 6.129)

and thus

${\displaystyle J^{+}=u+\int \frac{C_2\left(\frac{2\gamma }{\gamma -1}\right)a^{[2\gamma /(\gamma -1)-1]}}{C_2\gamma a^{[2\gamma /(\gamma -1)-2]}a}da=u+\left(\frac{2}{\gamma -1}\right)\int da}$

(Eq. 6.130)

${\displaystyle J^{+}=u+\frac{2a}{\gamma -1}}$

(Eq. 6.131)

${\displaystyle J^{-}=u-\frac{2a}{\gamma -1}}$

(Eq. 6.132)

Eqns. \ref{eq:riemann:a:b} and \ref{eq:riemann:b:b} are the Riemann invariants for a calorically perfect gas. The Riemann invariants are constants along ${\displaystyle C^{+}}$ and ${\displaystyle C^{-}}$ characteristics and if the situation shown in Fig. \ref{fig:characteristics} appears, that fact can be used to calculate the flow velocity and speed of sound in the location (${\displaystyle x_1}$, ${\displaystyle t_1}$).

${\displaystyle J^{+}+J^{-}=u+\frac{2a}{\gamma -1}+u-\frac{2a}{\gamma -1}=2u\Rightarrow u=\frac{1}{2}(J^{+}+J^{-})}$

(Eq. 6.133)

${\displaystyle J^{+}=u+\frac{2a}{\gamma -1}=\frac{1}{2}(J^{+}+J^{-})+\frac{2a}{\gamma -1}\Rightarrow a=\frac{\gamma -1}{4}(J^{+}-J^{-})}$

(Eq. 6.134)

The expansion wave propagation into the driver section in a shock tube can be described using characteristic lines.

The expansion is propagating into stagnant fluid in region four (the driver section), which means that the flow properties ahead of the expansion wave are constant.

${\displaystyle J_a^{+}=J_b^{+}}$

(Eq. 6.135)

${\displaystyle J^{+}}$ invariants constant along ${\displaystyle C^{+}}$ characteristics

${\displaystyle J_a^{+}=J_c^{+}=J_e^{+}}$

(Eq. 6.136)

${\displaystyle J_b^{+}=J_d^{+}=J_f^{+}}$

(Eq. 6.137)

Since ${\displaystyle J_a^{+}=J_b^{+}}$ this also implies ${\displaystyle J_e^{+}=J_f^{+}}$. In fact, since the flow properties ahead of the expansion are constant, all ${\displaystyle C^{+}}$ lines will have the same ${\displaystyle J^{+}}$ value.

${\displaystyle J^{-}}$ invariants constant along ${\displaystyle C^{-}}$ characteristics

${\displaystyle J_c^{-}=J_d^{-}}$

(Eq. 6.138)

${\displaystyle J_e^{-}=J_f^{-}}$

(Eq. 6.139)

${\displaystyle \begin{array}{cc}& u_e=\frac{1}{2}(J_e^{+}+J_e^{-})\\ & u_f=\frac{1}{2}(J_f^{+}+J_f^{-})\\ & J_e^{-}=J_f^{-}\\ & J_e^{+}=J_f^{+}\end{array}\}\Rightarrow u_e=u_f\Rightarrow a_e=a_f}$

(Eq. 6.140)

Due to the fact the ${\displaystyle J^{+}}$ is constant in the entire expansion region, ${\displaystyle u}$ and ${\displaystyle a}$ will be constant along each ${\displaystyle C^{-}}$ line.

The constant ${\displaystyle J^{+}}$ value can be used to obtain relations for the variation of flow properties through the expansion region. Evaluation of the ${\displaystyle J^{+}}$ invariant at any position within the expansion region should give the same value as in region 4.

${\displaystyle u+\frac{2a}{\gamma -1}=u_4+\frac{2a_4}{\gamma -1}=0+\frac{2a_4}{\gamma -1}}$

(Eq. 6.141)

and thus

${\displaystyle \frac{a}{a_4}=1-\frac{\gamma -1}{2}\left(\frac{u}{a_4}\right)}$

(Eq. 6.142)

Eqn. \ref{eq:expansion:a} and ${\displaystyle a=\sqrt{\gamma RT}}$ gives

${\displaystyle \frac{T}{T_4}={[1-\frac{\gamma -1}{2}\left(\frac{u}{a_4}\right)]}^2}$

(Eq. 6.143)

Using isentropic relations, we can get pressure ratio and density ratio

${\displaystyle \frac{p}{p_4}={[1-\frac{\gamma -1}{2}\left(\frac{u}{a_4}\right)]}^{2\gamma /(\gamma -1)}}$

(Eq. 6.144)

${\displaystyle \frac{\rho }{{\rho }_4}={[1-\frac{\gamma -1}{2}\left(\frac{u}{a_4}\right)]}^{2/(\gamma -1)}}$

(Eq. 6.145)

From the analysis of the incident shock, we have a relation for the induced flow behind the shock

${\displaystyle u_2=u_p=\frac{a_1}{{\gamma }_1}(\frac{p_2}{p_1}-1){\left(\frac{\left({\displaystyle \frac{2{\gamma }_1}{{\gamma }_1+1}}\right)}{\left({\displaystyle \frac{{\gamma }_1-1}{{\gamma }_1+1}}\right)+\left({\displaystyle \frac{p_2}{p_1}}\right)}\right)}^{1/2}}$

(Eq. 6.146)

The velocity in region 3 can be obtained from the expansion relations

${\displaystyle \frac{p_3}{p_4}={[1-\frac{{\gamma }_4-1}{2}\left(\frac{u_3}{a_4}\right)]}^{2{\gamma }_4/({\gamma }_4-1)}}$

(Eq. 6.147)

Solving for ${\displaystyle u_3}$ gives

${\displaystyle u_3=\frac{2a_4}{{\gamma }_4-1}[1-{\left(\frac{p_3}{p_4}\right)}^{({\gamma }_4-1)/(2{\gamma }_4)}]}$

(Eq. 6.148)

There is no change in pressure or velocity over the contact surface, which means ${\displaystyle u_2=u_3}$ and ${\displaystyle p_2=p_3}$.

${\displaystyle u_2=\frac{2a_4}{{\gamma }_4-1}[1-{\left(\frac{p_2}{p_4}\right)}^{({\gamma }_4-1)/(2{\gamma }_4)}]}$

(Eq. 6.149)

Now, we have two ways of calculating ${\displaystyle u_2}$. Setting Eqn. \ref{eq:shocktube:up:a} equal to Eqn. \ref{eq:shocktube:up:d} leads to the shock tube relation

${\displaystyle \frac{p_4}{p_1}=\frac{p_2}{p_1}{\{1-\frac{({\gamma }_4-1)(a_1/a_4)(p_2/p_1-1)}{\sqrt{2{\gamma }_1[2{\gamma }_1+({\gamma }_1+1)(p_2/p_1-1)]}}\}}^{-2{\gamma }_4/({\gamma }_4-1)}}$

(Eq. 6.150)