G.G., Bach and J.H.S., Lee. High order perturbation solutions for blast waves. AIAA Journal, 7(4):742–744, 1969.Google Scholar

G.G., Bach and J.H.S., Lee. An analytical solution for blast waves. AIAA Journal, 8(8):271–275, 1970.Google Scholar

G.G., Bach, K.W., Chiu, and J.H.S., Lee. Contribution to the propagation of non-ideal blast waves. I. Far field equivalency. 5th Int. Coll. Gasdynamics of Explosions and Reactive Systems, Bourges, France, 1975.

W.E., Baker. Explosion in Air. Wilfred Baker Engineering, San Antonio, 1974.

H., Bethe. Blast waves, chapter 4. approximation for small. Technical report, Los Alamos Rept., 1947.

S.R., Brinkley and J.G., Kirkwood. Theory of the propagation of shock waves. Physical Review, 71(9):606–611, 1947.Google Scholar

D.S., Butler. Converging spherical and cylindrical shocks. Technical report, ARE Rept. 54/54, Kent, UK, 1954.

S., Chandrasekhar. On the decay of planar shock waves. Rept. 423, Aberdeen Proving Ground, 1943.

G., Chernyi. Introduction to Hypersonic Flow. Academic Press, New York, 1961.

W., Chester. The quasi-cylindrical shock tube. Philosophical Magazine Series 7, 45(371):1293– 1301, 1954.Google Scholar

R.F., Chisnell. The motion of a shock wave in a channel, with applications to cylindrical and spherical shock waves. Journal of Fluid Mechanics, 2:286–298, 1957.Google Scholar

K.W., Chiu, J.H.S., Lee, and R., Knystautas. The blast waves from asymmetrical explosions. Journal of Fluid Mechanics, 82(1):193–208, 1977.Google Scholar

J.D., Cole. Newtonian flow theory for slender bodies. Journal of the Aeronautical Sciences, 24(6):448–455, 1957.Google Scholar

R.H., Cole. Underwater Explosions. Princeton University Press, Princeton, 1948.

R.H., Cole. Underwater Explosions. Princeton University Press, Princeton, 1961.

R., Courant and K.O., Friedrichs. Supersonic Flow and Shock Waves. Interscience, New York, 1948.

E.K., Dabora. Variable energy blast waves. AIAA Journal, 10(10):1384–1386, 1972.Google Scholar

M.N., Director and E.K., Dabora. Predictions of variable-energy blast waves. AIAA Journal, 15(9):1315–1321, 1977.Google Scholar

N.C., Freeman. An approach to the unsteady motion of a piston into a gas at rest with special reference to the pinch effect in electrical discharges. Aeronautical Research Council Report ARC-20,339 F.M. 2707, 1958

N.C., Freeman. Newtonian theory of hypersonic flow at large distances from bluff axially symmetric bodies, in F.R., Riddel, editor, Hypersonic Flow Research, page 345, Elsevier, New York, 1962.

M.P., Friedman. An improved perturbation theory for shock waves propagating through nonuniform regions. Journal of Fluid Mechanics, 8:193–209, 1960.Google Scholar

K.O., Friedrichs. Formation and decay of shock waves. Communications on Pure and Applied Mathematics, 1(3):211–245, 1948.Google Scholar

I.I., Glass and J.P., Sislian. Nonstationary Flows and Shock Waves. Claredon Press, Oxford, 1994.

G.G., Guderley. Starke kugelige und zylindrische verdichtungstösse in der nähe des kugelmittelounktes bzw. der zylinderachse. Luftfahrtforschung, 19:302–312, 1942.Google Scholar

G.G., Guderley. Powerful spherical and cylindrical compression shocks in the neighborhood of the center of the sphere and of the cylinder axis. Luftfahrtforschung, 19:302–312, 1942.Google Scholar

Z., Han and X., Yin. Shock Dynamics. Kluwer Academic, 1993.

W.D., Hayes and F.R., Probstein. Hypersonic flow theory, Volume 1. Inviscid Flows. Academic Press, New York, 1966.

E., Jouguet. Mécanique des explosifs. Octave Doin et fils, Paris, 1917.

J.G., Kirkwood and S.R., Brinkley. Theory of propagation of shock waves from explosive sources in air and water. Technical Report A-318, NDRC Rept., 1945.

A.S., Kompaneets. A point explosion in an inhomogeneous atmosphere. Soviet Physics Doklady, 5:46, 1960.Google Scholar

V.I., Korobenikov and P.I., Clushkin. Thermal Prokladnol Mekhenika i Tekklinika Fizika, 4(48), 1963.

J., Kynch. Blast waves, in L., Howarth, editor, Modern Developments in Fluid Dynamics: High Speed Flow, volume 1, pp. 146–157, Oxford University Press, Oxford, 1953.

L.D., Landau. On shock waves at large distance from the place of their origin. Journal of Physics- USSR, 9:496–503, 1945.Google Scholar

L.D., Landau and E.M., Lifshitz. Fluid Mechanics. Pergamon Press, 1959.

D.D., Laumbach and R.F., Probstein. A point explosion in a cold exponential atmosphere. Journal of Fluid Mechanics, 35(01):53–75, 1969.Google Scholar

A., Lax. Decaying shock, a comparison of an approximate analytical solution with a finite difference method. Communications on Pure and Applied Mathematics, 1(3):247–257, 1948.Google Scholar

B.H.K., Lee. Non-uniform propagation of imploding shocks and detonations. AIAA Journal, 5(11):1997–2003, 1967.Google Scholar

J.H., Lee. The propagation of shocks and blast waves in a detonating gas. PhD thesis, McGill University, Montreal, Canada, 1965.

J.H., Lee. Gasdynamics of detonations. Astronautica Acta, 17:455–466, 1972.Google Scholar

J.H., Lee. The Detonation Phenomenon. Cambridge University Press, Cambridge, 2008.

J.H., Lee, B.H.K., Lee, and I., Shanfield. Two-dimensional unconfined gaseous detonation waves. Symposium (International) on Combustion, 10(1):805–815, 1965.Google Scholar

L., Lees and T., Kubota. Inviscid hypersonic flow over blunt-nosed slender bodies. Journal of the Aeronautical Sciences, 24(3):195–202, 1957.Google Scholar

C.K., Lewis. Plane, Cylindrical, and Spherical Blast Waves Based Upon Oshima's Quasisimilarity Model. Arnold Engineering Development Center, Tennessee, 1961.

M.J., Lighthill. The piston of the shock wave in certain aerodynamic problems. Quarterly Journal of Mechanics and Applied Mathematics, 1:309–318, 1948.Google Scholar

S.C., Lin. Cylindrical shock waves produced by instaneous energy release. Journal of Applied Physics, 25(1):54–57, 1954.Google Scholar

J.A., McFodden. Initial behavior of a spherical blast. Journal of Applied Physics, 23:269, 1952.Google Scholar

K., Oshima. Blast wave produced by exploding wires, in W. G., Chace and H. K., Moore, editors, Exploding Wires, volume 2, pages 159–174. Plenum Press, New York, 1962.

K., Oshima, K., Sugaya, M., Yamamoto, and T., Totoki. Diffraction of a plane shock wave around a corner. Rept. 393, Institute of space and Aero. Univ. Tokyo, 1965.

K., Oswatitsch. Gasdynamics, English versionby G., Kuerti. Academic Press, New York, 1956.

W.J., Rae. Nonsimilar solutions for impact-generated shock propagation in solids final report. Technical Report NASA-CR-54251, Cornell Aeronautical Lab., 1965.

W.J., Rae and H.P., Kirchner. Final report on a study of meteoroid impact phenomena. Technical Report RM-1655-M-4, Cornell Aeronautical Lab., 1963.

M.H., Rogers. Similarity flows behind strong shock waves. Journal of Mechanics and Applied Mathematics, 11(4):411–422, 1958.Google Scholar

J., Rosciszewski. Calculations of the motion of non-uniform shock waves. Journal of Fluid Mechanics, 8:337–367, 1960.Google Scholar

M., Rosenbluth and M., Garwin. Infinite conductivity theory of the pinch, Technical report, Los Alamos Rept., LA-1850 1954.

A., Sakurai. On the propagation and structure of blast waves I. Journal of the Physical Society of Japan, 8(5):662–669, 1953.Google Scholar

A., Sakurai. On the propagation and structure of blast waves II. Journal of the Physical Society of Japan, 9(2):256–266, 1954.Google Scholar

A., Sakurai. On exact solution of the blast wave problem. Journal of the Physical Society of Japan, 10(9):827–828, 1955.Google Scholar

A., Sakurai. On the problem of a shock wave arriving at the edge of a gas. Communications on Pure and Applied Mathematics, 13:353–370, 1960.Google Scholar

A., Sakurai. Blast wave theory, in M., Holt, editor, Basic Developments in Fluid Dynamics, volume 1, pages 309–375. Academic Press, New York, 1965.

L.I., Sedov. Similarity and Dimensional Methods in Mechanics. Academic Press, New York, 1959.

A.H., Shapiro. The Dynamics and Thermodynamics of Compressible Fluid Flow. Ronald Press, New York, 1953.

R. J., Swigart. Third order blast wave theory and its application to hypersonic flow past blunt-nosed cylinders. Journal of Fluid Mechanics, 9:613–620, 1960.Google Scholar

G.I., Taylor. Air wave surrounding an expanding sphere. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 186(1006):273–292, 1946.Google Scholar

G.I., Taylor. The dynamics of the combustion of products behind plane and spherical detonation fronts in explosives. Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 200(1061):235–247, 1950a.Google Scholar

G.I., Taylor. The formation of a blast wave by a very intense explosion. i. theoretical discussion. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 201:159–174, 1950b.Google Scholar

G.I., Taylor. The formation of a blast wave by a very intense explosion. ii. the atomic explosion of 1945. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 201:175–186, 1950c.Google Scholar

P.A., Thompson. Compressible-Fluid Dynamics. McGraw-Hill, New York, 1988.

S.von, Hoerner. Lösungen der hydronamischen gleichungen mit linearem verlauf der geschwindigkeit. Z. Naturforsch, 10:687–692, 1955.

vonNeumann, . The point source solution, in Collected Works of von Neumann, Volume 6. Pergamon Press, Oxford, 1963.

R.L., Welsh. Technical report, University of California, Rept. No. AS-66.1, Berkeley, USA, 1966.

G.B., Whitham. On the propagation of weak shock waves. Journal of Fluid Mechanics, 1(3):290– 318, 1956.Google Scholar

G.B., Whitham. On the propagation of shock waves through regions of non-uniform area or flow. Journal of Fluid Mechanics, 4:337–360, 1958.Google Scholar

G.B., Whitham. Linear and Nonlinear Waves. John Wiley & Sons, New York, 1974.

Ya.B., Zel'dovich. On the pressure and velocity distribution in detonative blast products, in particular for spherical propagation of the detonation wave. ZhETF, 12(9):389–406, 1942.

Y.B., Zel'dovich.Motion of a gas due to a pressure of short duration shock. Soviet Physics-Acoustic (English Transl.), 2:25–35, 1956.

Y.B., Zel'dovich and Y.P., Raizer. Physic of Shock Waves and High Temperature Hydrodynamic Phenomena. Academic Press, New York, 1966.

Y.B., Zel'dovich and Y.P., Raizer. Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena, volume 1. Academic Press, New York, 1967.

M.J., Zucrow and J.D., Hoffman. Gasdynamics, volume 1. John Wiley & Sons, New York, 1976.