0
REVIEW ARTICLES

Recent research advances in the dynamic behavior of shells: 1989–2000, Part 2: Homogeneous shells

[+] Author and Article Information
Mohamad S Qatu

Ford Motor Company, MD 1247, 20000 Rotunda Dr, Dearborn MI 48124

Appl. Mech. Rev 55(5), 415-434 (Sep 11, 2002) (20 pages) doi:10.1115/1.1483078 History: Online September 11, 2002
Copyright © 2002 by ASME
Topics: Shells , Pipes
Your Session has timed out. Please sign back in to continue.

References

Leissa AW (1973), Vibration of Shells, NASA SP388, US Government Printing Office, Washington DC, Republished 1993, Acoustical Soc of America.
Qatu  MS (2002), Recent research advances in the dynamic behavior of shells, 1989–1999, Part 1: Laminated shells, Appl. Mech. Rev. 55(7), 1989–2000.
Liew  KM, Kitipornchai  S, and Wang  CM (1993), Research developments in analyses of plates and shells, J Construct Steel Res 26(2–3), 231–248.
Liew  KM, Lim  CW, and Kitipornchai  S (1997), Vibration of shallow shells: A review with bibliography, Appl. Mech. Rev. 50(8), 431–444.
Qatu  MS (1992), Review of shallow shell vibration research, Shock Vib. Dig. 24(9), 3–15.
Soedel W (1993), Vibrations of Shells and Plates, 2nd Edition, Marcel Dekker.
Shen  IY (1997), Active constrained layer damping treatments for shell structures: A deep-shell theory, some intuitive results, and an energy analysis, Smart Mater. Struct. 6(1), 89–101.
Lam  KY and Hua  L (1997), Vibration analysis of a rotating truncated circular conical shell, Int. J. Solids Struct. 34(17), 2183–2197.
Shu  C (1996), Efficient approach for free vibration analysis of conical shells, Int. J. Mech. Sci. 38(8–9), 935–949.
Lam  KY and Loy  CT (1995), Free vibrations of a rotating multi-layered cylindrical shell, Int. J. Solids Struct. 32(5), 647–663.
Zhu  F (1995), Vibration and stability analysis of toroidal shells conveying fluid, J. Sound Vib. 183(2), 197–208.
Tzou  HS (1991), Distributed modal identification and vibration control of continua: theory and applications, J. Dyn. Syst., Meas., Control 113(3), 494–499.
Tzou  HS (1991), Distributed vibration control and identification of coupled elastic/piezoelectric shells: Theory and experiment, Mech. Syst. Signal Process. 5(3), 199–214.
Sivadas  KR and Ganesan  N (1990), Free vibration of cantilever conical shells with variable thickness, Comput. Struct. 36(3), 559–566.
Sivadas  KR and Ganesan  N (1991), Free vibration of circular cylindrical shells with axially varying thickness, J. Sound Vib. 147(1), 73–85.
Omprakash  V and Ramamurti  V (1990), Coupled free vibration characteristics of rotating tuned bladed disk systems, J. Sound Vib. 140(3), 413–435.
Ganesan  N and Sivadas  KR (1990), Vibration analysis of orthotropic shells with variable thickness, Comput. Struct. 35(3), 239–248.
Ganesan  N and Sivadas  KR (1990), Free vibration of cantilever circular cylindrical shells with variable thickness, Comput. Struct. 34(4), 669–677.
Koga  T and Saito  A (1988), Inextensional free vibrations of circular cylindrical shells, AIAA J. 26(12), 1499–1505.
Goncalves  PB and Ramos  NRSS (1996), Free vibration analysis of cylindrical tanks partially filled with liquid, J. Sound Vib. 195(3), 429–444.
Goncalves  PB and Ramos  NRSS (1997), Numerical method for vibration analysis of cylindrical shells, J. Eng. Mech. 123(6), 544–550.
Loy  KY and Lam  CT (1997), Vibration of cylindrical shells with ring support, Int. J. Mech. Sci. 39(4), 455–471.
Huang  D, Redekop  D, and Xu  B (1997), Natural frequencies and mode shapes of curved pipes, Comput. Struct. 63(3), 465–473.
Swaddiwudhipong  S, Tian  J, and Wang  CM (1995), Vibrations of cylindrical shells with intermediate supports, J. Sound Vib. 187(1), 69–93.
Guo  YZ, Wang  FQ, and Cai  YL (1996), Generalized variational principles for the natural frequencies of elastic cylindrical shells, Int. J. Pressure Vessels Piping 65(1), 21–25.
Luo  D, Li  H, and Luo  B (1995), Effects of damping material on steady-state response of submerged ring-stiffened cylindrical shells (Chinese), J. Vib. Eng. 8(3), 258–263.
Bert  CW and Malik  M (1996), Free vibration analysis of thin cylindrical shells by the differential quadrature method, ASME J. Pressure Vessel Technol. 118(1), 1–12.
Okazaki  A, Tatemichi  A, and Mirza  S (1994), Damping properties of two-layered cylindrical shells with an unconstrained viscoelastic layer, J. Sound Vib. 176(2), 145–161.
Han  RPS and Liu  JD (1994), Free vibration analysis of a fluid-loaded variable thickness cylindrical tank, J. Sound Vib. 176(2), 235–253.
Terhune  JH and Karim-Panahi  K (1993), Wave motion of a compressible viscous fluid contained in a cylindrical shell, ASME J. Pressure Vessel Technol. 155(3), 302–312.
Huang  YY (1991), Orthogonality of wet modes in coupled vibrations of cylindrical shells containing liquids, J. Sound Vib. 145(1), 51–60.
Rosario  RCH and Smith  RC (1997), Spline approximation of thin shell dynamics, Int. J. Numer. Methods Eng. 40(15), 2807–2840.
Lam  KY and Ng  TY (1999), Parametric resonance of cylindrical shells by different shell theories, AIAA J. 37(1), 137–140.
Tao  T and Zhang  ZL (1998), Frequency equation of thin shell vibration in the frequency range, J. Sound Vib. 217(1), 33–41.
Whally  R and Ebrahimi  M (1998), Torsional vibration in rotor shells, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 212(C4), 263–276.
Liew  KM and Lim  CW (1995), Higher-order theory for vibration analysis of curvilinear thick shallow shells with constrained boundaries, J. Vib. Control 1(1), 15–39.
Liew  KM and Lim  CW (1995), A Ritz vibration analysis of doubly-curved rectangular shallow shells using a refined first order theory, Comput. Methods Appl. Mech. Eng. 127(1–4), 145–162.
Liew  KM and Lim  CW (1995), Vibratory behavior of doubly-curved shallow shells of curvilinear planform, J. Eng. Mech. 121(12), 1277–1283.
Liew  KM and Lim  CW (1996), Vibration studies on moderately thick double-curved elliptic shallow shells, Acta Mech. 116(1–4), 83–96.
Liew  KM and Lim  CW (1997), Vibration of thick doubly-curved stress free shallow shells of curvilinear planform, J. Eng. Mech. 123(5), 413–421.
Kobayashi  Y and Leissa  AW (1995), Large amplitude free vibrations of thick shallow shells supported by shear diaphragms, Int. J. Non-Linear Mech. 30(1), 57–66.
Qatu  MS (1999), Accurate theory for laminated composite deep thick shells, Int. J. Solids Struct. 36(19), 2917–2941.
Liew  KM and Lim  CW (1996), Higher-order theory for vibration of doubly curved shallow shells, ASME J. Appl. Mech. 63(3), 587–593.
Palani  GS, Iyer  NR, and Appa-Rao  TVSR (1993), Efficient FE model for static and vibration analysis of plates with arbitrarily located eccentric stiffeners, J. Sound Vib. 166(3), 409–427.
Hirashima  K and Hirano  K (1990), Higher order theories for free vibration analysis of circular rings, Proc JSCE 416(I-13), 201–204.
McDaniel  JG and Ginsberg  JH (1993), Thickness expansions for higher-order effects in vibrating cylindrical shells, ASME J. Appl. Mech. 60(2), 463–469.
Mizusawa  T and Kato  T (1996), Application of the spline prism method to analyse vibration of thick circular cylindrical panels, Int. J. Solids Struct. 33(7), 967–976.
Ni  H and Weng  Z (1988), Space variable transform method for free vibration analysis of thick cylindrical shell with arbitrary boundary conditions, Appl. Math. Mech. 9(12), 1145–1151.
Pai  PF and Nayfeh  AH (1994), Unified nonlinear formulation for plate and shell theories, Nonlinear Dyn. 6(4), 459–500.
Saito  T, Endo  M, and Fujimoto  K (1991), Vibration analysis of thick rotating cylindrical shells based on the 2-D elasticity theory, JSME Int. J., Ser. III 32(4), 585–591.
Singal  RK and Williams  K (1988), Theoretical and experimental study of vibrations of thick circular cylindrical shells and rings, J. Vib. Acoust. Stress. Reliab. Des. 110(4), 533–537.
Sivadas  KR and Ganesan  N (1993), Free vibration analysis of combined and stiffened shells, Comput. Struct. 46(3), 537–546.
Sivadas  KR and Ganesan  N (1994), Free vibration and material damping analysis of moderately thick circular cylindrical shells, J. Sound Vib. 172(1), 47–61.
Sivadas  KR and Ganesan  N (1994), Effect of rotation on vibration of moderately thick circular cylindrical shells, J. Vibr. Acoust. 116(2), 198–202.
Suzuki  K and Leissa  AW (1990), Analysis of free vibrations of noncircular thick cylindrical shells having circumferentially varying thickness, Int. J. Solids Struct. 26(3), 255–270.
Tsai  CT and Palazotto  AN (1991), Finite element analysis of non-linear vibration for cylindrical shells with high-order shear deformation theory, Int. J. Non-Linear Mech. 26(3-4), 379–388.
Tsai  YM (1991), Longitudinal motion of a thick transversely isotropic hollow cylinder, ASME J. Pressure Vessel Technol. 113(4), 585–589.
Meish  VF (1997), Nonaxisymmetric vibration of isotropic cylindrical shells with the allowance for transverse normal and shear deformation, Prikl. Mekh. 33(7), 36–42.
Wang  H, Williams  K, and Guan  W (1998), Vibrational mode analysis of free finite length thick cylinders using the FEM, J. Vibr. Acoust. 120(2), 371–377.
Suzuki  K, Kosawada  T, Uehara  T, and Kumagai  H (1991), Free vibrations of a vessel consisting of circular plates and a shell of revolution having varying meridional curvature, J. Sound Vib. 144(2), 263–279.
Chao  CC, Tung  TP, and Chern  YC (1991), Axisymmetric free vibration of thick orthotropic hemispherical shells under various edge conditions, J. Vib. Acoust. Stress. Reliab. Des. 113(2), 152–159.
Gautham  BP and Ganesan  N (1992), Free vibration of thick spherical shells, Comput. Struct. 45(2), 307–313.
Cai  X (1993), Free vibration of a thick truncated conical shell, J. Vib. Eng. 6(3), 287–291.
Singh  AV, Mirza  S, and Gupgupoglu  K (1990), Dynamic response of sandwich shells of revolution, ASME J. Pressure Vessel Technol. 112(1), 98.
Singh  AV (1991), Vibrations of shells of revolution using Bezier polynominials, ASME J. Pressure Vessel Technol. 133(4), 579–584.
Singh  AV and Mirza  S (1991), Asymmetric vibrations of layered orhotropic shells of revolution, J. Sound Vib. 148(2), 265–277.
Canet  JM, Suarez  B, and Onate  E (1989), Dynamic analysis of structures using a Reissner-Mindlin finite strip formulation, Comput. Struct. 31(6), 967–975.
Kant  T, Kumar  S, and Singh  UP (1994), Shell dynamics with 3D degenerate FES, Comput. Struct. 50(1), 135–146.
Lim  CW, Liew  K M, and Kitipornchai  S (1998), Vibration of open cylindrical shells: a 3D elasticity approach, J. Acoust. Soc. Am. 104(3-Pt 1), 1436–1443.
Soldatos  KP and Hadjigeorgiou  VP (1990), Three dimensional solution of the free vibration problem of homogeneous isotropic cylindrical shells and panels, J. Sound Vib. 137(3), 369–384.
Ding  HJ and Chen  WQ (1996), Natural frequencies of an elastic spherically-isotropic hollow sphere submerged in a compressible fluid medium, J. Sound Vib. 192(1), 173–198.
Ding  H and Chen  WW (1996), Nonaxisymmetric free vibrations of a spherically isotropic spherical shell embedded in an elastic medium, Int. J. Solids Struct. 33(18), 2575–2590.
Photiadis  DM, Bucaro  JA, and Houstin  BH (1994), Scattering from flexural waves on a ribbed cylindrical shell, J. Acoust. Soc. Am. 96(5), 2785–2790.
Zeng  X and Zhao  F (1994), Coupled FE and boundary integral equation method based on exterior domain decomposition for fluid-structure interface problems, Int. J. Solids Struct. 31(8), 1047–1061.
Liew  KM and Hung  KC (1995), Three-dimensional vibratory characteristics of solid cylinders and some remarks on simplified beam theories, Int. J. Solids Struct. 32(23), 3499–3513.
Svetlichnaya  SD and Yanyutin  EG (1998), Unsteady deformation of elastic solids in the shape of a circular cylindrical segment, J. Appl. Math. Mech. 62(2), 315–318.
Young  PG (2000), Application of a 3D shell theory to the free vibration of shells arbitrarily deep in one direction, J. Sound Vib. 238(2), 257–269.
Soldatos  KP (1994), Review of 3D dynamic analyses of circular cylinders and cylindrical shells, Appl. Mech. Rev. 47(10), 501–516.
Leissa  AW and So  J (1995), Three-dimensional vibrations of truncated hollow cones, J. Vib. Control 1(2), 145–158.
So  J and Leissa  AW (1997), Free vibrations of thick hollow circular cylinders from three-dimensional analysis, J. Vibr. Acoust. 199, 89–110.
Leissa  AW and Kang  J-H (1999), Three-dimensional vibration analysis of thick shells of revolution, J. Eng. Mech. 125(12), 1365–1371.
Kang  J-H and Leissa  AW (1999), Three-dimensional vibrations of hollow cones and cylinders with linear thickness variation, J. Acoust. Soc. Am. 106(2), 748–755.
McGee  OG and Spry  SC (1997), Three-dimensional analysis of the spheroidal and toroidal elastic vibrations of thick-walled spherical bodies of revolution, Int. J. Numer. Methods Eng. 40(8), 1359–1382.
Ding  H and Chen  W (1998), Exact shell theory analysis of submerged thin spherical shells, Int. J. Solids Struct. 35(33), 4381–4389.
Crossland  JA and Dickinson  SM (1997), Free vibration of thin rectangular planform shallow shells with slits, J. Sound Vib. 199(3), 513–521.
Liew  KM and Lim  CW (1994), Vibration of perforated doubly-curved shallow shells with rounded corners, Int. J. Solids Struct. 31(11), 1519–1536.
Liew  KM, Lim  CW, and Ong  LS (1994), Vibration of pretwisted cantilever shallow conical shells, Int. J. Solids Struct. 31(18), 2463–2476.
Liew  KM, Lim  CW, and Ong  LS (1994), Flexural vibration of doubly-tapered cylindrical shallow shells, Int. J. Mech. Sci. 36(6), 547–565.
Lim  CW and Liew  KM (1996), Vibration of moderately thick cylindrical shallow shells, J. Acoust. Soc. Am. 100(6), 3665–3673.
Qatu  MS (1995), Vibration studies on completely free shallow shells having triangular and trapezoidal planforms, Appl. Acoust. 44(3), 215–231.
Qatu  MS (1996), Vibration analysis of cantilevered shallow shells with triangular and trapezoidal planforms, J. Sound Vib. 191(2), 219–231.
Qatu  MS and Leissa  AW (1992), Effects of edge constraints upon shallow shell frequencies, Thin-Walled Struct. 14(5), 347–379.
Qatu  MS and Leissa  AW (1993), Vibration of shallow shells with two adjacent edges clamped and the others free, Mech. Struct. Mach. 21(3), 285–301.
Young  PG and Dickinson  SM (1995), Vibration of a class of shallow shells bounded by edges described by polynomials, Part I: Theoretical approach and validation, J. Sound Vib. 181(2), 203–214.
Kabir  HRH and Chaudhuri  RA (1991), Free vibration of shear flexible anti-symmetric angle-ply doubly curved panels, Int. J. Solids Struct. 28(1), 17–32.
Liew  KM and Lim  CW (1996), Vibration of doubly-curved shallow shells, Acta Mech. 114(1-4), 95–119.
Liew  KM, Lim  CW, and Kitipornchai  S (1996), Vibration characteristics of cantilevered thick cylindrical shallow shells, AIAA J. 34(11), 2451–2453.
Lim  CW, Kitipornchai  S, and Liew  KM (1996), Modeling the vibration of a variable thickness ellipsoidal cap with central point clamped or concentric surface-clamp, J. Acoust. Soc. Am. 99(1), 362–372.
Lim  CW, Kitipornchai  S, and Liew  KM (1997), Comparative accuracy of shallow and deep shell theories for vibration of cylindrical shells, J. Vib. Control 3(1), 119–143.
Lyubimov  VM and Pshenichnov  GI (1992), Natural vibrations of a momentless spherical shell, J. Appl. Math. Mech. 56(5), 771–773.
Grigorenko  YM and Gulyaev  VI (1991), Nonlinear problems of the theory of shells and methods of their solution: Review, Prikl. Mekh. 27(10), 3–23.
Brank  B, Brisegella  L, Tonello  N, and Damjanic  FB (1998), Nonlinear dynamics of shells: Implementation of energy momentum conserving algorithm for a finite rotation shell model, Int. J. Numer. Methods Eng. 42(3), 409–442.
Meek  JL and Wang  Y (1998), Nonlinear static and dynamic analysis of shell structures with finite rotation, Appl. Mech. Eng. 162(1–4), 301–315.
Andrianov  IV and Kholod  EG (1993), Nonlinear free vibration of shallow cylindrical shell by Bolotin’s asymptotic method, J. Sound Vib. 165(1), 9–17.
Coleby  JR and Mazumdar  J (1989), Nonlinear forced vibrations of shallow shells on regular polygonal bases, J. Acoust. Soc. Am. 85(4), 1577–1589.
Librescu  L and Lin  W (1996), Vibration of geometrically imperfect panels subjected to thermal and mechanical loads, J. Spacecr. Rockets 33(2), 285–291.
Li  D (1993), Time-mode approach to nonlinear vibrations of orthotropic thin shallow spherical shells, Int. J. Solids Struct. 30(22), 3113–3128.
Nie  G (1994), Nonlinear vibration of rectangular reticulated shallow shell structures, Appl. Math. Mech. 15(6), 525–535.
Ohnabe  H (1995), Nonlinear vibration of heated orthotropic sandwich plates and shallow shells, Int. J. Non-Linear Mech. 30(4), 501–508.
Paliwal  DN and Bhalla  V (1993), Large amplitude free vibration of shallow spherical shell on a Pasternak foundation, J. Vibr. Acoust. 115(1), 70–74.
Paliwal  DN and Bhalla  V (1993), Large amplitude free vibrations of cylindrical shell on Pasternak foundations, Int. J. Pressure Vessels Piping 54(3), 387–398.
Ye  ZM (1997), Nonlinear vibration and dynamic instability of thin shallow shells, J. Sound Vib. 202(3), 303–311.
Raouf  RA and Palazotto  AN (1994), Nonlinear free vibrations of curved orthotropic panels, Int. J. Non-Linear Mech. 29(4), 507–514.
Sathyamoorthy  M (1994), Vibrations of moderately thick shallow spherical shells at large amplitudes, J. Sound Vib. 172(1), 63–70.
Sathyamoorthy  M (1995), Nonlinear vibrations of moderately thick orthotropic shallow spherical shells, Comput. Struct. 57(1), 59–65.
Ambili  M, Pellicano  F, and Paidoussis  MP (1999), Further comments on nonlinear vibration of shells, J. Fluids Struct. 13(1), 159–160.
Sansour  C, Wriggers  P, and Sansour  J (1997), Nonlinear dynamics of shells: Theory, FE formulation and integration schemes, Nonlinear Dyn. 13(3), 279–305.
Birman  V and Twinprawate  P (1988), Free nonlinear vibrations of statically loaded long cylindrical shells, Z. Angew. Math. Phys. 39(5), 768–775.
Popov  AA, Thompson  JMT, and McRobie  FA (1998), Low dimensional models of shell vibrations: Parametrically excited vibrations of cylindrical shells, J. Sound Vib. 209(1), 163–186.
El-Damatty  AA and Korol  FA (1997), Large displacement extension of consistent shell element for static and dynamic analysis, Comput. Struct. 62(6), 943–960.
Goncalves  PB and Batista  RC (1988), Nonlinear vibration analysis of liquid-filled cylindrical shells, J. Sound Vib. 127(1), 133–143.
Cheikh  L, Pauchon  C, Lamarque  CH, Combescure  A, and Gilbert  RJ (1996), Nonlinear stability of a defective cylindrical shell, Mech. Res. Commun. 23(2), 151–164.
Raouf  RA and Nayfeh  AH (1990), One to one autoparametric resonances in infinitely long cylindrical shells, Comput. Struct. 35(2), 163–173.
Foale  S, Thompson  JMT, and McRobie  FA (1998), Numerical dimension reduction methods for nonlinear shell vibrations, J. Sound Vib. 215(3), 527–545.
Amiro  IY and Prokopenko  NY (1999), Study of nonlinear vibrations of cylindrical shells with regard to energy dissipation, Prikl. Mekh. 35(2), 30–35.
Kubenko  VD and Kovalchuk  PS (1998), Nonlinear problems of oscillations of thin shells, Prikl. Mekh. 34(8), 3–31.
Huang  Q and Huo  L (1996), Direct perturbation method of nonlinear vibration frequency about elastic circular cone flat shell of axial symmetry, (Chinese), J. Comput. Struct. Mech. Appl. 13(1), 106–111.
Alexander  T (1989), Nonlinear substructures of finitization of shell in space and time, Strojnicky Casopis 37(10), 713–733.
Andrianov  IV, Kholod  EG, and Olevsky  VI (1996), Approximate nonlinear boundary value problems of reinforced shell dynamics, J. Sound Vib. 194(3), 369–387.
Antuf’ev  BA (1988), Free nonlinear vibrations of shell with attached solid body, Sov. Appl. Mech. 24(1), 42–46.
Antuf’ev  BA (1988), Forced vibrations of a shell with an attached mass, Sov. Aeronaut. 31(3), 1–5.
Nie  GH (2000), Nonlinear free vibration of single-layer reticulated shallow spherical shells, Int. J. Space Struct. 15(1), 53–58.
Yeh  KY and Ji  Z (1988), Free vibration of nonlinear deformation ring and stringer-stiffened nonuniform shell, Appl. Math. Mech. 9(11), 1025–1037.
Yang  HTY and Wu  YC (1989), Geometrically nonlinear tensorial formulation of a skewed quadrilateral thin shell finite element, Int. J. Numer. Methods Eng. 28(12), 2855–2875.
Tesar  A (1998), Ultimate dynamics of corrugated shells, Comput. Struct. 69(2), 159–170.
Lee  YS and Kim  YW (1999), Nonlinear free vibration analysis of rotating hybrid cylindrical shells, Comput. Struct. 70(2), 161–168.
Valid  R (1992), Nonlinear principles of complementary energy in shell theory statistics and dynamics II: Dynamics, Eur. J. Mech. A/Solids 11(6), 791–834.
Qatu  MS (1994), On the validity of nonlinear shear deformation theories for laminated composite plates and shells, Compos. Struct. 27, 395–401.
Lim  CW and Liew  KM (1994), pb-2 Ritz formulation for flexural vibration of shallow cylindrical shells of rectangular planform, J. Sound Vib. 173(3), 343–375.
Lim  CW and Liew  KM (1995), Vibratory behavior of shallow conical shells by a global Ritz formulation, Eng. Struct. 17(1), 63–70.
Lim  CW and Liew  KM (1995), Higher order theory for vibration of shear deformable cylindrical shallow shells, Int. J. Mech. Sci. 37(3), 277–295.
Low  KH (1999), Comments on “Vibrational analysis of mass loaded plates and shallow shells by the receptance method with application to the steelplan,” J. Sound Vib. 222(3), 503–504.
Khader  N and Abu-Farsakh  G (1990), A triangular shell element for vibration analysis of cambered and twisted fan blades, Finite Elem. Anal. Design 6(4), 287–301.
Stavridis  LT (1998), Dynamic analysis of shallow shells of rectangular base, J. Sound Vib. 218(5), 861–882.
Godoy  LA and DeSouza  VCM (1998), Vibration of shallow shells due to removal of formwork, J. Sound Vib. 215(3), 425–437.
Chen  G, Coleman  MP, and Liu  K (1998), Boundary stabilization of Donnell’s shallow circular cylindrical shells, J. Sound Vib. 209(2), 265–298.
Bardell  NS, Dunsdon  JM, and Langley  RS (1997), Free vibration of completely free, open, cylindrically curved isotropic shell panels, J. Sound Vib. 207(5), 647–669.
Koga  T (1988), Effects of boundary conditions on the free vibrations of circular cylindrical shells, AIAA J. 26(11), 1387–1394.
Li  LY (1996), Approximate estimates of dynamic instability of long circular cylindrical shells under pure bending, Int. J. Pressure Vessels Piping 67(1), 37–40.
Hung  KC, Liew  KM, and Lim  MK (1995), Free vibrations of cantilevered cylinders: effects of cross-section and cavities, Acta Mech. 113, 37–52.
Magand  F and Chevret  P (1996), Time frequency analysis of energy distribution for circumferential waves on cylindrical elastic shells, Acustica 82(5), 707–716.
Wang  C and Lai  JCS (2000), Prediction of natural frequencies of finite length circular cylindrical shells, Appl. Acoust. 59(4), 385–400.
Niordson  FI (2000), Asymptotic theory for circular cylindrical shells, Int. J. Solids Struct. 37(13), 1817–1839.
Ding  H, Guo  Y, Yang  Q, and Chen  W (1997), Free vibration of piezoelectric cylindrical shells, Acta. Mech. Solida. Sinica 10(1), 48–55.
Srinivasan  MG and Kot  CA (1998), Damage index algorithm for a circular cylindrical shell, J. Sound Vib. 215(3), 587–591.
Price  NM, Liu  M, Taylor  RE, and Keane  AJ (1998), Vibrations of cylindrical pipes and open shells, J. Sound Vib. 218(3), 361–387.
Pierce  AD and Kil  HG (1990), Elastic wave propagation from point excitations on thin walled cylindrical shells, J. Vib. Acoust. Stress. Reliab. Des. 112(3), 399–406.
Kil  HG, Jarzynski  J, and Berthelot  YH (1998), Wave decomposition of the vibrations of a cylindrical shell with automated scanning laser vibrometer, J. Acoust. Soc. Am. 104(6), 3161–3168.
Amiro  IY (1998), Forced oscillations of a cylindrical shell: Transitional process under non-constant disturbing load, Prikl. Mekh. 34(7), 42–48.
Amiro  IY and Prokopenko  NY (1998), Interaction of vibration forms on amplitude-frequency dependencies of ribbed cylindrical shells, Prikl. Mekh. 34(11), 52–59.
Amiro  IY and Prokopenko  NY (1998), Effect of changes in the frequency of disturbing loading on the transition process of oscillations of a cylindrical shell, Prikl. Mekh. 34(12), 41–47.
Filippov  IG (1998), Boundary value problems of longitudinal oscillations of circular cylindrical shells, Prikl. Mekh. 34(12), 34–40.
Chakravorty  D and Bandyopadhyay  JN (1994), Effects of release of boundary constraints on the natural frequencies of clamped, thin, cylindrical shells, Comput. Struct. 52(3), 489–493.
Okazaki  K and Hirano  Y (1988), Vibration analysis of a circular cylindrical shell having a partial constraint on both ends, Trans. Jpn. Soc. Mech. Eng., Ser. C 54(501), 1047–1053.
Matsunaga  H (1998), Free vibration of thick circular cylindrical shells subjected to axial stresses, J. Sound Vib. 211(1), 1–17.
Beltman  WM, Burcsu  EN, Shephard  JE, and Zuhal  L (1999), Structural response of cylindrical shells to internal shock loading, ASME J. Pressure Vessel Technol. 121(3), 315–322.
Loy  CT, Lam  KY, and Reddy  JN (1999), Vibration of functionally graded cylindrical shells, Int. J. Mech. Sci. 41(3), 309–324.
Flores  FG and Godoy  LA (1999), Forced vibrations of silos leading to buckling, J. Sound Vib. 224(3), 431–454.
Naeem  MN and Sharma  CB (2000), Prediction of natural frequencies for thin circular cylindrical shells, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 214(C10), 1313–1328.
Mysore  GV, Liapis  SI, and Plaut  RH (1998), Dynamic analysis of single-anchor inflatable dams, J. Sound Vib. 215(2), 251–272.
Soldatos  KP (1999), Mechanics of cylindrical shells with non-circular cross-section, Appl. Mech. Rev. 52(8), 237–274.
Grigorenko  YM and Zakhariychenko  LI (1999), Calculation of corrugated cylindrical shells under different boundary (Russian), Prikl. Mekh. 35(9), 38–46.
Han  Q, Hu  Y, and Yang  G (1999), Study of chaotic motion in elastic cylindrical shells, Eur. J. Mech. A/Solids 18(2), 351–360.
Redekop  D (1994), Natural frequencies of a short curved pipe, Trans. Can. Soc. Mech. Eng. 18(1), 35–45.
Zhao  Y, Stevenson  JD, and Tang  HT (1996), Parametric nonlinear FE analysis of strain ratcheting in pressurized elbows based on random vibration, Shock Vib. Dig. 3(5), 373–387.
Li  Y and Kareem  A (1991), Simulation of multivariate nonstationary random processes by FFT, J. Eng. Mech. 117(5), 1037–1058.
Niordson  FI (1988), Spectrum of free vibrations of a thin elastic spherical shell, Int. J. Solids Struct. 24(9), 947–961.
Al-Jumaily  AM and Najim  FM (1997), Approximation to the vibrations of oblate spheroidal shells, J. Sound Vib. 204(4), 561–574.
Fosdick  R, Ketema  Y, and Yu  J-H (1998), Dynamics of a viscoelastic spherical shell with a nonconvex strain energy functions, Q. Appl. Math. 56(2), 221–244.
Gauthaman  BP and Ganesan  N (1997), Free vibration characteristics of isotropic and laminated orthotropic spherical cap, J. Sound Vib. 204(1), 17–40.
Hughes  DH and Marston  PL (1993), Local temporal variance of Wiger’s distribution function as a spectroscopic observable: Lamb wave resonances of a spherical shell, J. Acoust. Soc. Am. 94(1), 499–505.
Marston  PL and Sun  NH (1992), Resonance and interference scattering near the coincidence frequency of a thin spherical shell: An approximate synthesis, J. Acoust. Soc. Am. 92(6), 3315–3319.
Chou  CS, Chang  CO, and Hwang  JJ (1999), Vibration of a hemispherical shell gyro excited by an electrostatic field, Int. J. Appl. Electromagn. Mech. 10(5), 425–449.
Fan  SC, Liu  GY, and Wang  ZJ (1991), Flexural vibration of hemispherical shell, Appl. Math. Mech. 12(10), 1023–1030.
Young  PG and Dickinson  SM (1994), Free vibration of a class of solids with cavities, Int. J. Mech. Sci. 36(12), 1099–1107.
Thambiratnam  DP and Zhuge  Y (1993), Axisymmetric free vibration analysis of conical shells, Eng. Struct. 15(2), 83–89.
Huang  Y and Sun  BH (1991), Displacement type unified equation for bending, buckling and vibration of conical shells and its applications, Acta Mech. Solida Sinica 4(3), 299–317.
Liew  KM and Feng  ZC (2000), Vibration characteristics of conical shell panels with 3D flexibility, ASME J. Appl. Mech. 67(2), 314–320.
Lim  CW and Kitipornchai  S (1999), Effects of subtended and vertex angles on the free vibration of open conical shells: A conical coordinate approach, J. Sound Vib. 219(5), 813–835.
Lam  KY and Hua  L (1999), Influence of boundary conditions on the frequency characteristics of a rotating truncated conical shell, J. Sound Vib. 223(2), 171–195.
Kosawada  T, Suzuki  K, and Shikanai  G (1994), Free vibration analysis of two-layered shells of revolution, J. Sound Vib. 174(5), 577–590.
Houmat  A and Hutchinson  JR (1994), Free vibration of bodies of revolution by boundary collocation, J. Sound Vib. 171(1), 35–48.
Kaplunov  JD and Wilde  MV (2000), Edge and interfacial vibrations in elastic shells of revolution, Z. Angew. Math. Phys. 51(4), 530–549.
Zhang  RJ and Zhang  W (1991), Shell vibrations at high frequency, Acta Mech Solida Sinica 4(2), 163–173.
Zhang  RJ and Zhang  W (1991), Turning point solutions for thin shell vibrations, Int. J. Solids Struct. 27(10), 1311–1326.
Kossovich  LY and Parfenova  A (2000), Flexural transient waves in shells of revolution: An asymptotic approach, Z. Angew. Math. Phys. 51(4), 611–628.
Luah  MH and Fan  SC (1989), General free vibration analysis of shells of revolution using the spline FEM, Comput. Struct. 33(5), 1153–1162.
Fan  SC and Luah  MH (1989), Spline FE for axisymmetric free vibrations of shells of revolution, J. Sound Vib. 132(1), 61–72.
Tan  DY (1998), Free vibration analysis of shells of revolution, J. Sound Vib. 213(1), 15–33.
Qatu  MS (1999), Theory and vibration analysis of laminated barrel thin shells, J. Vib. Control 5, 851–889.
Tan  L, Zhang  Y, Yan  J, and Cai  K (1999), Static and dynamic analysis of the behavior of a non-cylindrical shell (Chinese), J. Huazhong Univ. Sci. Technol. 27(12), 89–91.
Leung  AYT and Kwok  NTC (1994), Free vibration analysis of a toroidal shell, Thin-Walled Struct. 18(4), 317–332.
Leung  AYT and Kwok  NTC (1995), Dynamic stiffness analysis of toroidal shells, Thin-Walled Struct. 21(1), 43–64.
Yamada  G, Kobayashi  Y, Ohta  Y, and Yokota  S (1989), Free vibration of a toroidal shell with elliptical cross-section, J. Sound Vib. 135(3), 411–425.
Kim  SH, Soedel  W, and Lee  JM (1994), Analysis of the beating response of bell type structures, J. Sound Vib. 173(4), 517–536.
Tsuiji  T and Sueoka  T (1990), Vibration analysis of twisted thin cylindrical panels by using the Rayleigh-Ritz method, JSME Int. J., Ser. III 33(4), 501–505.
Hu  XX and Tsuiji  T (1999), Free vibration analysis of curved and twisted thin panels, J. Sound Vib. 219(1), 63–88.
Choi  C-K and Noh  H-C (1999), Simulation of wind process by spectral representation method and application to cooling tower shell, Wind Struct. 2(2), 105–117.
Krivoshapko  SN (1999), Geometry and strength of general helicoidal shells, Appl. Mech. Rev. 52(5), 161–175.
Ogihara  K, Nakagawa  H, and Ueda  S (1994), Theoretical model for self-excited vibration of shell type roller gate, Proc. JSCE 503(II-29), 60–78.
Chebair  AEl, Paidoussis  MP, and Misra  AK (1989), Experimental study of annular flow induced instabilities of cylindrical shells, J. Fluids Struct. 3(4), 349–364.
Chiba  M (1993), Nonlinear hydroelastic vibration of a cantilever tank I: Experiment-empty case, Int. J. Non-Linear Mech. 28(5), 591–599.
Chiba  M (1993), Nonlinear hydroelastic vibration of a cantilever cylindrical tank II: Experiment-liquid filled case, Int. J. Non-Linear Mech. 28(5), 601–612.
Chiba  M (1993), Experimental studies on a nonlinear hydroelastic vibration of a clamped cylindrical tank partially filled with liquid, ASME J. Pressure Vessel Technol. 115(4), 381–388.
Chiba  M (1995), Free vibration of a clamped-free circular cylindrical shell partially submerged in a liquid, J. Acoust. Soc. Am. 97(4), 2238–2248.
Chiba  M (1996), Free vibration of a partially liquid-filled and partially submerged, clamped-free circular cylindrical shell, J. Acoust. Soc. Am. 100(4-P1), 2170–2180.
Klauson  A, Metsaveer  J, Decultot  D, Maze  G, and Ripoche  J (1996), Identification of the resonances of a cylindrical shell stiffened by an internal lengthwise rib, J. Acoust. Soc. Am. 100(5), 3135–3143.
Admire  JR, Tinker  ML, and Ivery  EW (1993), Mass-additive modal test method for verification of constrained structural models, AIAA J. 31(11), 2148–2153.
Dyshko  AL, Pavlenko  ID, and Selivanov  YM (1996), Approximate determination of inherent characteristics of a cylindrical shell with a hole (Russian), Prikl. Mekh. 32(2), 27–32.
Huang  YM and Hsu  CS (1997), Dynamic behavior of tubes subjected to internal and external cross flows, Shock Vib. Dig. 4(2), 77–91.
Ekimov  AE and Lebedev  AV (1996), Experimental study of local mass influence on sound radiation from a thin limited cylindrical shell, Appl. Acoust. 48(1), 47–57.
Raj  DM, Narayanan  R, Khadakkar  AG, and Paramasivam  V (1995), Effect of ring stiffeners on vibration of cylindrical and conical shell models, J. Sound Vib. 179(3), 413–426.
Takayanagi  M (1991), Parametric resonance of liquid storage axisymmetric shell under horizontal excitation, ASME J. Pressure Vessel Technol. 113(4), 511–523.
Takayanagi  M and Yamate  Y (1990), Parametric resonance of an axisymmetric shell-lumped weight system, JSME Int. J., Ser. III 33(2), 198–205.
Bonilha  MW and Fahy  FJ (1994), Measurements of vibration field correlation on a car body shell, Appl. Acoust. 43(1), 1–18.
Anaturk  AR (1991), Experimental investigation to measure hydrodynamic forces at small amplitudes and high frequencies, Appl. Ocean. Res. 13(4), 200–208.
Lecroq  F, Maze  G, Decultot  D, and Ripoche  J (1994), Acoustic scattering from an air-filled cylindrical shell with welded flat plate endcaps: Experimental and theoretical study, J. Acoust. Soc. Am. 95(2), 762–769.
Harari  A, Sandman  BE, and Zaldonis  JA (1994), Analytical and experimental determination of the vibration and pressure radiation from submerged, stiffened cylindrical shell with two end plates, J. Acoust. Soc. Am. 95(6), 3360–3368.
Woodard  SE, Lay  RR, Jarnot  RF, and Gell  DA (1997), Experimental investigation of spacecraft in-flight disturbances and dynamic response, J. Spacecr. Rockets 34(2), 199–204.
Carroll  GP (1999), Effect of sensor placement errors on cylindrical near-field acoustic holography, J. Acoust. Soc. Am. 105(4), 2269–2276.
El-Deeb  KMM and Royles  R (1999), Response measurements on an echinodome subjected to explosive loading, Shock Vib. Dig. 6(1), 45–57.
Fukuyama  M, Nakagawa  M, Yashiro  T, Toyoda  Y, and Akiyama  H (2000), Dynamic buckling experiments on liquid containing cantilever cylindrical shells under horizontal excitation, JSME Int. J., Ser. A 43(2), 146–155.
Mann  JA, Williams  E, Washburn  K, and Grosh  K (1991), Time domain analysis of the energy exchange between structural vibrations and acoustic radiation using near-field acoustical holography measurements, J. Acoust. Soc. Am. 90(3), 1656–1664.
Pratte  JM and Hart  JE (1991), Experiments on periodically forced flow over topography in a rotating fluid, J. Fluid Mech. 229, 87–114.
Verheiji  JW (1990), Measurements of structure-borne wave intensity on lightly damped pipes, Noise Control Eng. J. 35(2), 69–76.
Williams  EG (1996), Imaging the sources on a cylindrical shell from far-field pressure measured on a semicircle, J. Acoust. Soc. Am. 99(4), 2022–2032.
Zarutsky  VA and Sivak  VF (1999), Experimental researches in dynamics of ribbed shells of revolution (Russian), Prikl. Mekh. 35(3), 3–11.
Zarutsky  VO, Palchevsky  OS, and Sivak  VF (1997), Effect of the meridian form on the natural frequencies and form of vibrations of shells of revolution (Russian), Prikl. Mekh. 33(1), 59–60.
Hirano  K and Hirashima  K (1989), Formulation and accuracy of the circular cylindrical shell theory due to higher order approximation, JSME Int. J., Ser. I 32(3), 337–340.
Callahan  J and Baruh  H (1999), Closed-form solution procedure for circular cylindrical shell vibrations, Int. J. Solids Struct. 36(20), 2973–3013.
Lund  E and Olhoff  N (1994), Shape design sensitivity analysis of eigenvalues using ‘exact’ numerical differentiation of FE matrices, Struct. Optim. 8(1), 52–59.
Wang  CM, Swaddiwudhipong  S, and Tian  J (1997), Ritz method for vibration analysis of cylindrical shells with ring stiffeners, J. Eng. Mech. 123(2), 134–142.
Amabili  M (1997), Shell-plate interaction in the free vibrations of circular cylindrical tanks partially filled with a liquid: The artificial spring method, J. Sound Vib. 199(3), 431–452.
Omprakash  V and Ramamurti  V (1988), Natural frequencies of bladed disks by a combined cyclic symmetry and Rayleigh-Ritz method, J. Sound Vib. 125(2), 357–366.
Chen  PT and Ginsberg  JH (1992), Modal properties and eigenvalue veering phenomena in the axisymmetric vibration of spheroidal shells, J. Acoust. Soc. Am. 92(3), 1499–1508.
McGee  OG (1993), 3D vibration analysis of a cantilevered skewed helicoidal thick shell, J. Acoust. Soc. Am. 93(3), 1431–1444.
Sinha  G (2000), Transverse free vibration of stiffened plates-shells with elastically restrained edges by FEM, Int. Shipbuild. Prog. 47(450), 191–214.
Huang  DT and Soedel  W (1993), Natural frequencies and modes of a circular plate welded to a circular cylindrical shell at arbitrary axial positions, J. Sound Vib. 162(3), 403–427.
Huang  DT and Soedel  W (1993), Free vibrations of multiple plates welded to a cylindrical shell with special attention to mode pairs, J. Sound Vib. 166(2), 315–339.
Huang  DT and Soedel  W (1993), Study of the forced vibration of shell plate combinations using the receptance method, J. Sound Vib. 166(2), 341–369.
Huang  DT (2000), Influences of small curvatures on the modal characteristics of the joined hermetic shell structures, J. Sound Vib. 238(1), 85–111.
Tso  YK and Hansen  CH (1997), Investigation of the coupling loss factor for a cylinder-plate structure, J. Sound Vib. 199(4), 629–643.
Lepik  U (1996), Axisymmetric vibrations of elastic-plastic cylindrical shells by Galerkin’s method, Int. J. Impact Eng. 18(5), 489–504.
Lee  LT and Lu  JC (1995), Free vibration of cylindrical shells filled with liquid, Comput. Struct. 54(5), 997–1001.
Khatri  KN (1992), Vibration control of conical shells using viscoelastic materials, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 206(C3), 167–178.
Goncalves  PB (1994), Axisymmetric vibrations of imperfect shallow spherical caps under pressure loading, J. Sound Vib. 174(2), 249–260.
Yahner  J and Burroughs  CB (1993), Frequencies of resonance of axisymmetric modes of open prolate spheroidal shells, J. Acoust. Soc. Am. 94(1), 213–220.
Laing  CR, McRobie  A, and Thompson  JMT (1999), Post-processed Galerkin method applied to nonlinear shell vibrations, Dyn. Stability Syst. 14(2), 163–181.
Providakis  CP and Beskos  DE (1991), Free and forced vibrations of shallow shells by boundary and interior elements, Comput. Methods Appl. Mech. Eng. 92(1), 55–74.
Sinha  G and Mukhopadhyay  M (1997), Static, free and forced vibration analysis of arbitrary non-uniform shells with tapered stiffeners, Comput. Struct. 62(5), 919–933.
Sabir  AB, Sfendji  A, and Hughes  TG (1994), Strain based FE for the natural frequencies of cylindrical shells, Thin-Walled Struct. 18(1), 67–82.
Mirza  S and Alizadeh  Y (1995), Free vibration of partially supported cylindrical shells, Shock Vib. Dig. 2(4), 297–306.
Mazuch  T, Horacek  J, Trnka  J, and Vesely  J (1996), Natural modes and frequencies of a thin clamped-free steel cylindrical storage tank partially filled with water: FEM and measurement, J. Sound Vib. 193(3), 669–690.
McCollum  MD and Siders  CM (1996), Modal analysis of a structure in a compressible fluid using a FE-BE approach, J. Acoust. Soc. Am. 99(4), 1949–1957.
Santiago  JM and Wisniewski  HL (1989), Convergence of FE frequency predictions for a thin walled cylinder, Comput. Struct. 32(3–4), 745–759.
Tzou  HS and Tseng  CI (1990), Distributed piezoelectric sensor-actuator design for dynamic measurement control of distributed parameter systems: A piezoelectric finite element approach, J. Sound Vib. 138(1), 17–34.
Fan  SC, Liu  GY, and Wang  ZJ (1991), Vibration of hemispherical shell by using FEM, Appl. Math. Mech. 12(12), 1169–1175.
Hwang  DY and Forster  WA (1992), Analysis of axisymmetric free vibration of isotropic shallow spherical shells with a circular hole, J. Sound Vib. 157(2), 331–343.
Fan  SC and Luah  MH (1995), Free vibration analysis of arbitrary thin shell structures by using spline FE, J. Sound Vib. 179(5), 763–776.
Wang  HC and Banerjee  PK (1990), Free vibration of axisymmetric solids by BEM using particular integrals, Int. J. Numer. Methods Eng. 29(5), 985–1001.
Allman  DJ (1996), Implementation of a flat facet shell FE for applications in structural dynamics, Comput. Struct. 59(4), 657–663.
Krawczuk  M (1994), Rectangular shell FE with an open crack, Finite Elem. Anal. Design 15(3), 233–253.
Noor  AK, Peters  JM, and Min  BJ (1989), Mixed finite element models for free vibrations of thin-walled beams, Finite Elem. Anal. Design 5(4), 291–305.
Ozakca  M and Hinton  E (1994), Free vibration analysis and optimization of axisymmetric plates and shells, I: FE formulation, Comput. Struct. 52(6), 1181–1197.
Ozakca  M and Hinton  E (1994), Free vibration analysis and optimization of axisymmetric plates and shells II: Shape optimization, Comput. Struct. 52(6), 1199–1211.
Ozakca  M, Hinton  E, and Rao  NVR (1994), Free vibration analysis and shape optimization of prismatic folded plates and shells with circular curved planform, Int. J. Numer. Methods Eng. 37(10), 1713–1739.
Palani  GS, Iyer  NR, and Appa Rao  TVSR (1992), Efficient FE model for static and vibration analysis of eccentrically stiffened plates and shells, Comput. Struct. 43(4), 651–666.
Rappaz  J, Hubert  JS, Palencia  ES, and Vassiliev  D (1997), Spectral pollution in the FE approximation of thin elastic ‘membrane’ shells, Numer. Math. 75(4), 473–500.
Yao  ZH (1992), Some applications of semi-analytical FEM in static and dynamic analysis of structures, Acta Mech. Solida Sinica 5(1), 75–84.
Rajakumar  C, Ali  A, and Yunus  SM (1992), New acoustic interface element for fluid-structure interaction problems, Int. J. Numer. Methods Eng. 33(2), 369–386.
Rajasankar  J, Iyer  NR, and Rao  A (1993), New 3D FE model to evaluate added mass for analysis of fluid-structure interaction problems, Int. J. Numer. Methods Eng. 36(6), 997–1012.
Rengarajan  G, Aminpour  MA, and Knight  NF (1995), Improved assumed-stress hybrid shell element with drilling dof for linear stress, buckling and free vibration analyses, Int. J. Numer. Methods Eng. 38(11), 1917–1943.
Senjanovic  I and Ying  F (1990), Modelling of thin-walled girders and accuracy of vibration analysis performed by the finite element technique related to ship structures, Comput. Struct. 34(4), 603–614.
Shankar  RP, Sinha  G, and Mukhopadhyay  M (1993), Vibration of submerged stiffened plates by the FEM, Int. Shipbuild. Prog. 40(423), 251–292.
Sinha  G and Mukhopadhyay  M (1994), Finite element free vibration analysis of stiffened shells, J. Sound Vib. 171(4), 529–548.
Stepanishen  PR and Chen  HW (1992), Acoustic harmonic radiation and scattering from shells of revolution using FE and internal source density methods, J. Acoust. Soc. Am. 92(6), 3343–3357.
To  CWS and Wang  B (1991), Axisymmetric thin shell FE for vibration analysis, Comput. Struct. 40(3), 555–568.
Aksu  T (1997), Finite element formulation for free vibration analysis of shells of general shape, Comput. Struct. 65(5), 687–694.
Chung  J and Lee  JM (1999), Vibration analysis of a nearly axisymmetric shell structure using a new finite ring element, J. Sound Vib. 219(1), 35–50.
Gennaretti  M, Giordani  A, and Morino  L (1999), Third-order BEM for exterior acoustics with applications to scattering by rigid and elastic shells, J. Sound Vib. 222(5), 699–722.
Hua  L and Lam  KY (1998), Frequency characteristics of a thin rotating cylindrical shell using the generalized differential quadrature method, Int. J. Mech. Sci. 40(5), 443–459.
Hua  L (2000), Frequency analysis of rotating truncated circular orthotropic conical shells with different boundary conditions, Compos. Sci. Technol. 60(16), 2945–2955.
Loy  CT, Lam  KY, and Shu  C (1997), Analysis of cylindrical shells using generalized differential quadrature, Shock Vib. Dig. 4(3), 193–198.
Ng  TY and Lam  KY (1999), Effects of elastic foundation on the dynamic stability of cylindrical shells, Struct. Eng. Mech. 8(2), 193–205.
Cheung  YK, Li  WY, and Tham  LG (1989), Free vibrations analysis of singly curved shell by spline finite strip method, J. Sound Vib. 128(3), 411–422.
Hinton  E, Ozakca  M, and Rao  NVR (1995), Free vibration analysis and shape optimization of variable thickness plates, prismatic folded plates and curved shells, Part 1: Finite strip formulation, J. Sound Vib. 181(4), 553–566.
Hinton  E, Ozakca  M, and Rao  NVR (1995), Free vibration analysis and shape optimization of variable thickness plates, prismatic folded plates and curved shells, Part 2: Shape optimization, J. Sound Vib. 181(4), 567–581.
Au  FTK and Cheung  YK (1996), Free vibration and stability analysis of shells by the isoparametric spline finite strip method, Thin-Walled Struct. 24(1), 53–82.
Cheung  YK and Kong  J (1995), Vibration and buckling of thin walled structures by a new finite strip, Thin-Walled Struct. 21(4), 327–343.
Suarez  B, Canet  JM, and Onate  E (1988), Free vibration analysis of plates, bridges and axisymmetric shells using a thick finite strip method, Eng. Comput. 5(2), 158–164.
Mikami  T and Yoshimura  J (1990), Collocation method for determining the natural vibration characteristics of cylindrical shells with either internal or external fluids, Proc. JSCE 422(I-14), 97–107.
Gennakakes  GN and Wang  PC (1991), Vibration analysis of arbitrarily shaped shell panels using B3 spline finite strips, Comput. Struct. 39(5), 489–492.
Tavakoli  MS and Singh  R (1989), Eigensolutions of joined-hermetic shell structures using the state space method, J. Sound Vib. 130(1), 97–123.
Wong  SK and Sze  KY (1998), Application of matched asymptotic expansions to the free vibration of a hermetic shell, J. Sound Vib. 209(4), 593–607.
Wong  SK and Bush  WB (1993), Axisymmetric vibrations of a clamped cylindrical shell using matched asymptotic expansions, J. Sound Vib. 160(3), 523–531.
Averbukh  AZ and Mavlyutov  IG (1988), Vibrations of a cylindrical shell acted upon by concentrated loads, Mech. Solids 23(5), 130–135.
Fil’shtinskii  LA and Khizhnyak  LA (1988), Reaction of a piezoceramic shell to concentrated dynamical actions, J. Appl. Math. Mech. 52(1), 136–139.
Guzhas  DR (1989), Vibration excitation in a cylindrical shell by concentrated forces, Vib. Eng. 3(4), 575–581.
Glandier  CY, Bertelot  YH, and Jarzynski  J (1992), Wave-vector analysis of the forced vibrations of cylindrical shells of finite length, J. Acoust. Soc. Am. 92(4 Pt 1), 1985–1993.
Koga  T and Kodama  T (1991), Bifurcation buckling and free vibrations of cylindrical shells under pressure, Int. J. Pressure Vessels Piping 45(2), 223–235.
Laneville  A and Mazouzi  A (1996), Wind-induced ovalling oscillations of cylindrical shells: Critical onset velocity and mode prediction, J. Fluids Struct. 10(7), 691–704.
Mikhasev  GI (1997), Free and parametric vibrations of cylindrical shells under static and periodic axial loads, Tech Mech 17(3), 209–216.
Mikhasev  GI (1998), Traveling wave packets in an infinite thin cylindrical shell under internal pressure, J. Sound Vib. 209(4), 543–559.
Ng  TY and Lam  KY (1999), Vibration and critical speed of a rotating cylindrical shell subjected to axial loading, Appl. Acoust. 56(4), 273–282.
Zhang  Y and Ma  Z (1999), Radial vibrations of axisymmetrically loaded stepped pressure vessel, Appl. Math. Mech. 20(1), 105–109.
Achong  A (1996), Vibrational analysis of mass loaded plates and shallow shells by the receptance method with application to the steelpan, J. Sound Vib. 191(2), 207–217.
Trotsenko  VA and Kladinoga  VS (1994), Nonaxisymmetric oscillations of preliminarily stressed shell of revolution with fastened rigid disc, Prikl. Mekh. 30(7), 17–24.
Babich  DV (1996), Natural vibrations and stability loss of compressed shells (Russian), Prikl. Mekh. 32(5), 45–50.
Baumgarten  R, Kreuzer  E, and Popov  AA (1997), Bifurcation analysis of the dynamics of a simplified shell model, Nonlinear Dyn. 12(4), 307–317.
Borshch  SP, Popov  AL, and Chernyshev  GN (1990), Method of extracting singularities in the problem of the hydroelastic vibrations of a shell excited by concentric forces, J. Appl. Math. Mech. 54(4), 512–518.
Fanous  F and Greimann  L (1990), Simplified axisymmetric analysis of steel containment under general dynamic pressure, ASME J. Pressure Vessel Technol. 112(1), 65–70.
Fanous  F and Greimann  L (1991), Steel containment resistance under dynamic pressure, Nucl. Eng. Des. 130(2), 163–170.
Christoforou  AP and Swanson  SR (1990), Analysis of simply-supported orthotropic cylindrical shells subject to lateral impact loads, ASME J. Appl. Mech. 57(2), 376–382.
Drewko  J and Sperski  M (1991), Vibration of multi-chamber shell structures with discontinuously variable cross-sections, Rozprawy Inzynierskie (Eng. Trans.) 39(2), 163–180.
Auslender  F and Combescure  A (2000), Spherical elastic-plastic structures under internal explosion: Approximate analytical solutions and applications, Eng. Struct. 22(8), 984–992.
Mukhoi  VP (1999), Nonstationary dynamic behavior of gas-filled closed shell under the effect of the inner explosive load (Russian), Prikl. Mekh. 35(3), 76–82.
Martineau  RL, Anderson  CA, and Smith  FW (2000), Expansion of cylindrical shells subjected to internal explosive detonations, Exp. Mech. 40(2), 219–225.
Librescu  L, Lin  W, Nemeth  MP, and Starnes  JH (1996), Frequency-load interaction of geometrically imperfect curved panels subjected to heating, AIAA J. 34(1), 166–177.
Botogova  MG and Mikhasev  GI (1996), Free vibrations of a non-uniformly heated viscoelastic cylindrical shell, Tech. Mech. 16(3), 251–256.
Librescu  L and Lin  W (1997), Vibration of thermomechanically loaded flat and curved panels taking into account geometric imperfections and tangential edge restraints, Int. J. Solids Struct. 34(17), 2161–2181.
Wu  N, Rauch  BJ, and Kessel  PG (1991), Perturbation solution to the dynamic response of orthotropic cylindrical shells using the generalized theory of thermoelasticity, J. Therm. Stresses 14(4), 465–477.
Mecitoglu  Z (1996), Free vibrations of a conical shell with temperature-dependent material properties, J. Therm. Stresses 19(8), 711–729.
Yang  JC, Hamins  A, and Donnelly  MK (2000), Reduced gravity combustion of thermoplastic spheres, Combust. Flame 120(1-2), 61–74.
Achong  A (1999), Nonlinear analysis of compressively-thermally stressed elastic shell structures on the steel pan and the underlying theory of the tuning process, J. Sound Vib. 222(4), 597–620.
Hu  J, Huang  J, Dong  S, and Chen  W (2000), Finite element analysis of reticulated shells for wind vibration (Chinese), J. Shanghai Jiaotong Univ. 34(8), 1053–1056.
Ng  TY and Lam  KY (1998), Effects of boundary conditions on the parametric resonance of cylindrical shells under axial loading, Shock Vib. Dig. 5(5-6), 343–354.
Lam  KY and Ng  TY (1997), Dynamic stability of cylindrical shells subjected to conservative periodic axial loads using different shell theories, J. Sound Vib. 207(4), 497–520.
Ng  TY, Lam  KY, and Reddy  JN (1998), Parametric resonance of a rotating cylindrical shell subjected to periodic axial loads, J. Sound Vib. 213(3), 513–529.
Ng  TY, Lam  KY, and Reddy  JN (1999), Dynamic stability of cylindrical panels with transverse shear effects, Int. J. Solids Struct. 36(23), 3483–3496.
Kobayashi  Y and Yamada  G (1991), Free vibration of a spinning polar orthotropic shallow spherical shell, JSME Int. J., Ser. III 34(2), 233–238.
Huang  SC and Chen  LH (1996), Vibration of a spinning cylindrical shell with internal-external ring stiffeners, J. Vibr. Acoust. 118(2), pp. 227–236; 34(2), 233–238.
Yamada  G, Kobayashi  Y, Sawae  T, and Irie  T (1988), Free vibration of a spinning spherical shell, Trans. JSME C 54(505), 2009–2015.
Chang  CO, Hwang  JJ, and Chou  CS (1996), Modal precession of a rotating hemispherical shell, Int. J. Solids Struct. 33(19), 2739–2757.
Bauer  HF (1988), Coupled frequencies of a rotating hydroelastic shell-liquid system under zero gravity, J. Fluids Struct. 2(5), 407–423.
Bauer  HF and Komatsu  K (1994), Coupled frequencies of a hydroelastic system of a elastic 2D sector-shell and frictionless liquid in zero-gravity, J. Fluids Struct. 8(8), 817–831.
Dzygadlo  Z, Nowotarski  I, Olejnik  A, and Zalewski  P (1991), Discrete dynamic model of rotating shell-plate-disc structures, J. Tech. Phys. 32(2), 267–291.
Dintrans  B, Rieutord  M, and Valdettaro  L (1999), Gravito-inertial waves in a rotating stratified sphere or spherical shell, J. Fluid Mech. 398, 271–297.
Loveday  PW and Rogers  CA (1998), Free vibration of elastically supported thin cylinders including gyroscopic effects, J. Sound Vib. 217(3), 547–562.
Amiro  IY and Prokopenko  NY (1994), Effect of strengthening parameters on the amplitude-frequency characteristics of ribbed cylindrical shell, Prikl. Mekh. 30(8), 64–69.
Amiro  IY and Zarutsky  VA (1998), Account of discrete distribution of ribs under the study of the stress-strained state, oscillations and stability of ribbed shells (Russian), Prikl. Mekh. 34(4), 3–22.
Zarutsky  VA and Skosarenko  YV (1991), Effect of transverse shear deformations on natural oscillations of cylindrical shells reinforced with ring ribs (Russian), Prikl. Mekh. 27(2), 54–61.
Bardell  NS and Mead  DJ (1989), Free vibration of an orthogonally stiffened cylindrical shell, Part I: Discrete line simple supports, J. Sound Vib. 134(1), 29–54.
Bardell  NS and Mead  DJ (1989), Free vibration of an orthogonally stiffened cylindrical shell, Part II: Discrete general stiffeners, J. Sound Vib. 134(1), 55–72.
Bhimaraddi  A, Moss  PJ, and Carr  AJ (1991), Free-vibration response of column-supported, ring-stiffened cooling tower, J. Eng. Mech. 117(4), 770–788.
Houston  BH, Marcus  MH, Bucaro  JA, Williams  EG, and Photiadis  DM (1996), Structural acoustics and active control of interior noise in a ribbed cylindrical shell, J. Acoust. Soc. Am. 99(6), 3497–3512.
Jiang  J and Olson  MD (1994), Vibration analysis of orthogonally stiffened cylindrical shells using super FEs, J. Sound Vib. 173(1), 73–83.
Palamarchuk  VG (1988), Parametric vibrations of a ribbed cylindrical shell with an attached beam, Sov. Appl. Mech. 24(8), 768–775.
Photiadis  DM (1996), Wave mixing effects on a periodically ribbed cylindrical shell, J. Vibr. Acoust. 118(1), 100–106.
Stanley  AJ and Ganesan  N (1997), Free vibration characteristics of stiffened cylindrical shells, Comput. Struct. 65(1), 33–45.
Ross  CTF and Richards  WD (1994), Vibration of ring-stiffened cones under external water pressure, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 208(C3), 177–185.
Skopetsky  VV and Deineka  VS (1998), Numerical determination of frequencies and discontinuous forms of free oscillations of a thick long shell regularly strengthened by a circular rib, Prikl. Mekh. 34(8), 68–74.
Schneider  MH, Snel  RF, Tracy  JJ, and Powers  DR (1991), Buckling and vibration of externally pressurized conical shells with continuous and discontinuous rings, AIAA J. 29(9), 1515–1522.
Blocka  B (1988), Free vibrations of thin, elastic, segmented shells of revolution reinforced with circumferential rings, Arch. Mech. 40(2-3), 183–199.
Blocka  B (1989), Free vibrations of thin, elastic, orthogonally stiffened shells of revolution with stiffeners treated as discrete elements, Rozprawy Inzynierskie (Eng. Trans.) 37(1), 65–85.
Ross  CTF and Etheridge  J (2000), Buckling and vibration of tube-stiffened axisymmetric shells under external hydrostatic pressure, Ocean Eng. 27(12), 1373–1390.
Kuznetsov  OV (1990), Analysis of vibrations of shells of revolution reinforced by stiffeners, Mech. Solids 25(2), 186–190.
Haftka  R, Cohen  GA, and Mroz  Z (1990), Derivatives of buckling loads and vibrations frequencies with respect to stiffness and initial strain parameters, ASME J. Appl. Mech. 57(1), 18–24.
Langley  RS (1992), Dynamic stiffness technique for the vibration analysis of stiffened shell structures, J. Sound Vib. 156(3), 521–540.
Ryaboy  VM and Weller  T (1996), Simple model of a stiffened shell-type structure for an investigation into the vibration-buckling correlation, ASME J. Appl. Mech. 63(2), 517–522.
Xu  MB, Zhang  XM, and Zhang  WH (1999), Space-harmonic analysis of input power flow in a periodically stiffened shell filled with fluid, J. Sound Vib. 222(4), 531–546.
Wedel-Heinen  J (1991), Vibration of geometrically imperfect beam and shell structures, Int. J. Solids Struct. 27(1), 29–47.
Hui  D (1990), Accurate backbone curves for a modified-Duffing equation for vibrations of imperfect structures with viscous damping, J. Vib. Acoust. Stress Reliab. Des. 112(3), 304–311.
Brevart  BJ and Fuller  CR (1993), Active control of coupled wave propagation in fluid-filled elastic cylindrical shells, J. Acoust. Soc. Am. 94(3), 1467–1475.
Guo  YM and Yang  QD (1997), Free vibrations of piezoelectric cylindrical shells filled with compressible fluid, Int. J. Solids Struct. 34(16), 2025–2034.
Brevart  BJ and Fuller  CR (1993), Effect of an internal flow on the distribution of vibrational energy in an infinite fluid-filled thin cylindrical elastic shell, J. Sound Vib. 167(1), 149–163.
Howard  CQ, Hansen  CH, and Pan  J (1997), Power transmission from a vibrating body to a circular cylindrical shell through passive and active isolators, J. Acoust. Soc. Am. 101(3), 1479–1491.
Pan  X and Hansen  CH (1997), Active control of vibration transmission in a cylindrical shell, J. Sound Vib. 203(3), 409–434.
Qiu  J and Tani  J (1995), Vibration control of a cylindrical shell using distributed piezoelectric sensors and actuators, J. Intell. Mater. Syst. Struct. 6(4), 474–481.
Qiu  J and Tani  J (1996), Vibration suppression of a cylindrical shell using a hybrid control method, J. Intell. Mater. Syst. Struct. 7(3), 278–287.
Yang  JS and Batra  RC (1995), Thickness shear vibrations of a circular cylindrical piezoelectric shell, J. Acoust. Soc. Am. 97(1), 309–312.
Tani  J, Qiu  J, and Miura  H (1995), Vibration control of a cylindrical shell using piezoelectric actuators, J. Intell. Mater. Syst. Struct. 6(3), 380–388.
Baz  A and Chen  T (2000), Control of axi-symmetric vibrations of cylindrical shells using active constrained layer damping, Thin-Walled Struct. 36(1), 1–20.
Tzou  HS (1992), Distributed sensor and actuator theory for intelligent shells, J. Sound Vib. 153(2), 335–349.
Tzou  HS and Zhong  JP (1993), Electromechanics and vibrations of piezoelectric shell distributed systems, J. Dyn. Syst., Meas., Control 115(3), 506–517.
Tzou  HS and Zhong  JP (1994), New theory of linear piezoelectric shell vibrations, J. Sound Vib. 175(1), 77–88.
Tzou  HS and Bao  Y (1995), Dynamics and control of adaptive shells with curvature transformation, Shock Vib. Dig. 2(2), 143–154.
Vovk  IV and Oliynik  VN (1996), Sound radiation by a cylindrical piezoelastic shell with an asymmetric insertion, J. Acoust. Soc. Am. 99(1), 133–138.
Karnaukhove  VG and Kirichok  IF (1997), Electromechanical harmonic oscillations and dissipated heating of shells of revolution of viscoelastic piezoactive materials with regard for their depolarization, Prikl. Mekh. 33(9), 34–42.
Rosario  RCH (1998), LQR control of thin shell dynamics: Formulation and numerical implementation, J. Intell. Mater. Syst. Struct. 9(4), 301–320.
Kirichok  IF and Vengrenyuk  YA (1998), Effect of thermal depolarization and thermomechanical dependence on harmonious piezoelectric shells, Prikl. Mekh. 34(8), 62–67.
Karlash  VL (1998), Form oscillations and mechanical losses of energy in a hollow truncated piezoceramic cone, Prikl. Mekh. 34(11), 32–37.
Banks  HT and Wang  Y (1995), Modeling of piezoceramic patch interactions with shells, plates and beams, Q. Appl. Math. 539(2), 353–381.
Ruckman  CE and Fuller  CR (1994), Numerical simulation of active structural-acoustic control for a fluid-loaded spherical shell, J. Acoust. Soc. Am. 96(5), 2817–2825.
Kelmanson  MA and Maunder  SB (1999), Modeling high-velocity impact phenomena using unstructured dynamically-adaptive Eulerian meshes, J. Mech. Phys. Solids 47(4), 731–762.
Yang  JS, Fang  HY, and Jiang  Q (2000), Vibrating piezoelectric ceramic shell as a rotation sensor, Smart Mater. Struct. 9(4), 445–451.
Barrett  TS and Palazzolo  AB (1995), Active vibration control of rotating machinery using piezoelectric actuators incorporating flexible casing effects, J. Eng. Gas Turbines Power 117(1), 176–187.
Altman  W, Goncalves  M, and Oliveira  DE (1990), Vibration and stability of shell panels with slight internal damping under follower forces, J. Sound Vib. 136(1), 45–50.
Okazaki  A, Urata  Y, and Tatemichi  A (1990), Damping properties of three layered shallow spherical shells with a constrained viscoelastic layer, JSME Int. J., Ser. I 33(2), 145–151.
Lu  YP and Roscoe  AJ (1991), Analysis of the response of damped cylindrical shells carrying discontinuously constrained beam elements, J. Sound Vib. 150(3), 395–403.
Boily  S and Charron  F (1999), Vibroacoustic response of a cylindrical shell structure with viscoelastic and poroelastic materials, Appl. Acoust. 58(2), 131–152.
Klosowski  P and Woznica  K (1999), Different types of constitutive equations in dynamic response of an elasto-viscoplastic circular plate and cylindrical panel, Arch. Civil Eng. 45(2), 231–243.
Huang  YM and Fuller  CR (1997), Effects of dynamic absorbers on the forced vibration of a cylindrical shell and its coupled interior sound field, J. Sound Vib. 200(4), 401–418.
Huang  YM and Chen  CC (2000), Optimal design of dynamic absorbers on vibration and noise control of the fuselage, Comput. Struct. 76(6), 619–702.
Mohring  J (1999), Helmholtz resonators with large aperture, Acustica 85(6), 751–763.
He  JF and Ma  BA (1996), Vibration analysis of viscoelastically damped sandwich shells, Shock Vib. Dig. 3(6), 403–417.
Wagner  DA, Gur  Y, Ward  SM, and Samus  MA (1997), Modeling foam damping materials in automotive structures, ASME J. Eng. Mater. Technol. 119(3), 279–283.
Niziol  J and Kozien  MS (2000), White noise excited vibrations of viscoelastic shallow shells, J Theor Appl Mech 38(2), 351–366.
Brevart  BJ, Journeau  C, and Fuller  CR (1996), High frequency response of a fluid-filled cylindrical shell with an internal column of gas bubbles: Application to active acoustic gas leak detection, J. Sound Vib. 194(3), 417–437.
Muftu  S and Cole  KA (1999), Fluid-structure interaction in supporting a thin flexible cylindrical web with an air cushion, J. Fluids Struct. 13(6), 681–708.
Bo  L and Tang  J (1994), Vibration studies of base-isolated liquid storage tanks, Comput. Struct. 52(5), 1051–1059.
Zhu  F (1994), Rayleigh quotients for coupled free vibrations, J. Sound Vib. 171(5), 641–649.
Akyuz  U and Ertepinar  A (1999), Stability and asymmetric vibrations of pressurized compressible hyperelastic cylindrical shells, Int. J. Non-Linear Mech. 34(3), 391–404.
Amabili  M (1996), Free vibration of a fluid-filled circular cylindrical shell with lumped masses attached, using the reacceptance method, Shock Vib. Dig. 3(3), 159–167.
Amabili  M (1996), Free vibration of partially-filled, horizontal cylindrical shells, J. Sound Vib. 191(5), 757–780.
Amabili  M and Dalpiaz  G (1995), Breathing vibrations of a horizontal circular cylindrical tank shell, partially filled with liquid, J. Vibr. Acoust. 117(2), 187–191.
Brevart  BJ and Fuller  CR (1996), Energy exchange between the coupled media of impulsively-excited, fluid-filled, elastic cylinders, J. Sound Vib. 190(5), 763–774.
Journeau  C (1995), High-frequency vibrations of liquid-filled thick elastic cylindrical shells: A simplified modal approach, J. Acoust. Soc. Am. 97(3), 1670–1677.
Maze  G, Leon  F, Ripoche  J, Klauson  A, Metsaveer  J, and Uberall  H (1995), Nature of Scholte interface waves on cylindrical shells, Acustica 81(3), 201–213.
Hoop  AT, Hon  BP, and Kurkjian  AL (1994), Calculation of transient tube-wave signals in cross-borehole acoustics, J. Acoust. Soc. Am. 95(4), 1773–1789.
Brenneman  B and Au-Yang  MK (1992), Fluid-structure dynamics with a modal hybrid method, ASME J. Pressure Vessel Technol. 114(2), 133–138.
Williams  AN and Moubayed  WI (1990), Green’s function solution for axisymmetric vibration of flexible liquid-filled storage tanks, Eng. Struct. 12(1), 49–59.
Huang  H and Gaunaurd  GC (1997), Acoustic scattering of a plane wave by two spherical elastic shells above the coincidence frequency, J. Acoust. Soc. Am. 101(5), 2659–2668.
Xu  MB and Zhang  WH (2000), Vibrational power flow input and transmission in a circular cylindrical shell filled with fluid, J. Sound Vib. 234(3), 387–403.
Bai  MR and Wu  K (1994), Free vibration of a thin spherical shell containing a compressible fluid, J. Acoust. Soc. Am. 95(6), 3300–3310.
Gaunaurd  GC and Werby  MF (1991), Lamb and creeping waves around submerged spherical shells resonantly excited by sound scattering. II. Further applications, J. Acoust. Soc. Am. 89(4), 1656–1667.
Saravanan  C, Ganesan  N, and Ramamurti  V (2000), Study on energy dissipation pattern in vibrating fluid filled cylindrical shells with a constrained viscoelastic layer, Comput. Struct. 75(6), 575–591.
Amabili  M, Pellicano  F, and Vakakis  AF (2000), Nonlinear vibrations and multiple resonances of fluid-filled, circular shells, Part 1: Equations of motion and numerical results, J. Vibr. Acoust. 122(4), 346–354.
Amabili  M, Pellicano  F, and Paidoussis  MP (2000), Nonlinear dynamics and stability of circular cylindrical shells containing flowing fluid, Part III: Truncation effect without flow and experiments, J. Sound Vib. 237(4), 617–640.
Amabili  M, Pellicano  F, and Paidoussis  MP (2000), Nonlinear dynamics and stability of circular cylindrical shells containing flowing fluid, Part IV: Large-amplitude vibrations with flow, J. Sound Vib. 237(4), 641–666.
Amabili  M and Garziera  R (2000), Vibrations of circular cylindrical shells with nonuniform constraints, elastic bed and added mass, Part I: Empty and fluid-filled shells, J. Fluids Struct. 14(5), 669–690.
Pellicano  F, Amabili  M, and Vakakis  AF (2000), Nonlinear vibrations and multiple resonances of fluid-filled, circular shells, Part 2: Perturbation analysis, J. Vibr. Acoust. 122(4), 355–364.
Ruzzene  M and Baz  A (2000), Finite element modeling of vibration and sound radiation from fluid-loaded damped shells, Thin-Walled Struct. 36(1), 21–46.
Ruzzene  M and Baz  A (2000), Active-passive control of sound radiation and power flow in fluid-loaded shells, Thin-Walled Struct. 38(1), 17–42.
Blocka  B (1992), Forced vibrations of liquid filled shells of revolution. Bibliographical review, Marine Tech. Trans. 3, 5–24.
Mistry  J and Menezes  JC (1995), Vibration of cylinders partially-filled with liquids, J. Vibr. Acoust. 117(1), 87–93.
Van Dijk  R, van Keulen  F, and Sterk  JC (2000), Simulation of closed thin-walled structures partially filled with fluid, Int. J. Solids Struct. 37(42), 6063–6083.
Bondaryk  JE and Schmidt  H (1996), Hybrid processing structure for the analysis of scattering from stiffened, fluid-loaded cylindrical shells, J. Acoust. Soc. Am. 99(4), 2176–2182.
Oda  H and Suzuki  I (1999), Normal mode oscillations of a sphere with solid-gas-solid structure, J. Acoust. Soc. Am. 105(2), 693–699.
Kiiko  IA (1999), Formulation of the problem of the flutter of a shell of revolution and a shallow shell in a high-velocity supersonic gas flow, J. Appl. Math. Mech. 63(2), 305–312.
Metsaveer  J and Klauson  A (1996), Influence of the curvature on the dispersion curves of a submerged cylindrical shell, J. Acoust. Soc. Am. 100(3), 1551–1560.
Klauson  A, Maze  G, and Metsaveer  J (1994), Acoustic scattering by submerged cylindrical shell stiffened by an internal lengthwise rib, J. Acoust. Soc. Am. 96(3), 1575–1581.
Bogomolov  VG and Poruchikov  BB (1990), Dynamics of a spherical elastic shell in a fluid, Mech. Solids 25(4), 140–149.
Choi  SH, Achenbach  JD, and Igusa  T (1994), Effect of periodically attached substructures on the excitation of submerged cylindrical shells, J. Sound Vib. 177(3), 379–392.
Choi  SH, Igusa  T, and Achenbach  JD (1995), Nonaxisymmetric vibration and acoustic radiation of a submerged cylindrical shell of finite length containing internal substructures, J. Acoust. Soc. Am. 98(1), 353–362.
Huang  XY (1994), Effect of multiple scattering of sound waves on motion of parallel cylindrical shells, J. Sound Vib. 178(3), 349–359.
Harari  A and Sandman  BE (1990), Radiation and vibrational properties of submerged stiffened cylindrical shells, J. Acoust. Soc. Am. 88(4), 1817–1830.
Ho  JM (1993), Acoustic scattering by submerged elastic cylindrical shells: Uniform ray asymptotics, J. Acoust. Soc. Am. 94(5), 2936–2946.
Ho  JM (1994), Geometrical theory of acoustic scattering by thin elastic shells, J. Acoust. Soc. Am. 96(5), 3115–3125.
Ho  JM (1994), Near field ray acoustic reponse of submerged elastic spherical shells, J. Acoust. Soc. Am. 96(10), 525–535.
Tesei  A, Fox  WLJ, Lovik  A, and Maguer  A (2000), Target parameter estimation using resonance scattering analysis applied to air-filled, cylindrical shells in water, J. Acoust. Soc. Am. 108(6), 2891–2900.
Junger  MC (1992), Vibrations of simply supported cylindrical shells isolated from ambient acoustic medium by a compliant layer, J. Acoust. Soc. Am. 92(4 Pt 1), 1994–1997.
Gaunaurd  GC and Werby  MF (1989), Near field effects in acoustic scattering by submerged rigid bodies and elastic shells, J. Acoust. Soc. Am. 85(6), 2465–2471.
Sprague  MA and Geers  TL (1999), Response of empty and fluid-filled, submerged spherical shells to plane and spherical, step-exponential acoustic waves, Shock Vib. Dig. 6(3), 147–157.
Jones-Oliveira  JB and Harten  LP (1994), Transient fluid-solid integration of submerged spherical shells revisited: Proliferation of frequencies and acoustic radiation effects, J. Acoust. Soc. Am. 96(2), 918–925.
Jones-Oliveira  JB (1996), Transient analytic and numerical results for the fluid-solid interaction of prolate spheroidal shells, J. Acoust. Soc. Am. 99(1), 392–407.
Chen  Y, Wen  L, Luo  D, and Wu  C (1999), Study on sound radiation of a double shell in fluid field (Chinese), J. Huazhong Univ. Sci. Technol. 27(7), 83–85.
Chen  PT, Ju  SH, and Cha  KC (2000), Symmetric formulation of coupled BEM-FEM in solving responses of submerged elastic structures for large dof, J. Sound Vib. 233(3), 407–422.
Ho  JM and Felsen  LB (1994), Fully 3D exact and ray asymptotic formulation of the characteristic wave fields on a spherical shell surface, J. Acoust. Soc. Am. 95(1), 265–285.
Ye  G, Chen  W, Cai  J, and Ding  H (2000), Free vibration of a submerged FGM hollow sphere, Acta Mech Solida Sinica 13(3), 223–229.
Akkas  N, Zakout  U, and Tupholme  GE (2000), Propagation of waves from a spherical cavity with and without a shell embedment, Acta Mech. 142(1-4), 1–11.
Barbone  PE and Crighton  DG (1994), Vibrational modes of submerged elastic bodies, Appl. Acoust. 43(3), 295–317.
Antione  H and Cristini  P (1999), Influence of the presence of an elastic shell in shallow water: Theoretical and experimental study, Acustica 85(1), 24–30.
Chen  SS (1991), Flow induced vibrations in two-phase flow, ASME J. Pressure Vessel Technol. 113(2), 234–241.
Cheng  L and Richard  MJ (1995), New formulation for the vibration analysis of a cylindrical vessel containing fluid via the use of artificial spring systems, Thin-Walled Struct 21(1), 17–30.
Choi  SH, Igusa  T, and Achenbach  JD (1996), Acoustic radiation from a finite-length shell with non-axisymmetric substructures using a surface variational principle, J. Sound Vib. 197(3), 329–350.
Endo  R and Tosaka  N (1989), Free vibration analysis of coupled external fluid-elastic cylindrical shell-internal fluid systems, JSME Int. J., Ser. I 32(2), 217–221.
Ettouney  MM, Daddazio  RP, and DiMaggio  FL (1992), Wet modes of submerged structures Part 1: Theory, J. Vib. Acoust. Stress Reliab. Des. 114(4), 433–439.
Everstine  GC (1991), Prediction of low frequency vibrational frequencies of submerged structures, J. Vib. Acoust. Stress Reliab. Des. 113(2), 187–191.
Gaunaurd  GC and Akay  A (1994), Isolation of the spectrograms and rosettes of insonified sets of submerged, concentric, thin shells, J. Vibr. Acoust. 116(4), 573–577.
Finnveden  S (1997), Spectral FE analysis of the vibration of straight fluid-filled pipes with flanges, J. Sound Vib. 199(1), 125–154.
Gol’denveizer  AL and Kaplunov  YD (1988), Dynamic boundary layer in problems of vibration of shells, Mech. Solids 23(4), 146–155.
Guiggiani  M (1989), Dynamic instability in fluid-coupled coaxial cylindrical shell under harmonic excitation, J. Fluids Struct. 3(3), 211–228.
Gupta  RK (1995), Sloshing in shallow cylindrical tanks, J. Sound Vib. 180(3), 397–415.
Halle  H, Chenoweth  JM, and Wambsganss  MW (1989), Shellside water flow-induced tube vibration in heat exchanger configurations with tube pitch-to-diameter raio of 1.42, ASME J. Pressure Vessel Technol. 111(4), 441–449.
Horacek  J and Zolotarev  I (1991), Acoustic structural coupling of vibrating cylindrical shells with flowing liquid, J. Fluids Struct. 5(5), 487–501.
Horacek  J and Zolotarev  I (1993), Influence of the acoustic-structural couplings upon free vibrations of mechanical systems, Arch. Acoust. 18(2), 297–309.
Horacek  J (1993), Theory of annular-flow-induced instabilities of cylindrical shells, J. Fluids Struct. 7(2), 123–135.
Ishii  N and Knisley  CW (1992), Flow-induced vibration of shell-type long-span gates, J. Fluids Struct. 6(6), 681–703.
Ishii  N, Knisely  CW, and Nakata  A (1994), Coupled-mode vibration of gates with simultaneous over and underflow, J. Fluids Struct. 8(5), 455–469.
Ishii  N, Knisely  CW, and Nakata  A (1995), Field study of a long-span shell-type gate undergoing flow induced vibrations, J. Fluids Struct. 9(1), 19–41.
Jakubauskas  VF and Weaver  DS (1996), Axial vibrations of fluid-filled bellows expansion joints, ASME J. Pressure Vessel Technol. 118(4), 484–490.
Jeong  KH and Lee  SC (1996), Fourier series expansion method for free vibration analysis of either a partially liquid-filled or a partially liquid-surrounded circular cylindrical shell, Comput. Struct. 58(5), 937–9466.
Jeans  RA and Mathews  IC (1994), Elastoacoustic analysis of submerged fluid-filled thin shells, Int. J. Numer. Methods Eng. 37(17), 2911–2919.
Kallivokas  LF and Bielak  J (1993), Element for the analysis of transient exterior fluid-structure interaction problems using the FEM, Finite Elem. Anal. Design 15(1), 69–81.
Kaplunov  JD and Veksler  ND (1990), Peripheral waves in cylindrical shells immersed in water, Acustica 72(2), 131–139.
Kaplunov  YD and Korsunskii  VM (1992), Description of the resonances of higher Lamb modes in the scattering problem for cylindrical shell, Sov. Phys. Acoust. 38(3), 261–264.
Kaplunov  YD (1991), Slowly varying high-frequency stress-strain rates in immersed shells, J. Appl. Math. Mech. 55(3), 390–396.
Kaplunov  YD (1991), Vibrations of shells of revolution in response to high-frequency edge excitation, Mech. Solids 26(6), 147–154.
Kargl  SG and Marston  PL (1990), Longitudinal resonances in the form function for backscattering from a spherical shell: Fluid shell case, J. Acoust. Soc. Am. 88(2), 1114–1122.
Koga  T and Tsushima  M (1990), Breathing vibrations of a liquid filled circular cylindrical shell, Int. J. Solids Struct. 26(9-10), 1005–1015.
Krasnopolskaya  TS and Heijst  GJF (1996), Wave pattern formation in a fluid annulus with a radially vibrating inner cylinder, J. Fluid Mech. 328, 229–252.
Kuzelka  V (1990), Mathematical modeling of dynamic deformations in a cylindrical shell excited by turbulent flow, Nucl. Eng. Des. 121(1), 39–43.
Lakis  AA and Sinno  A (1992), Free vibration of axisymmetric and beam-like cylindrical shells, partially filled with liquid, Int. J. Numer. Methods Eng. 33(2), 235–268.
Kubenko  VD and Lakiza  VD (1996), Dynamic behavior of gas-liquid media in ellipsoidal shells subjected to the effect of vibration (Russian), Prikl. Mekh. 32(2), 12–19.
Nakata  A, Ishii  N, Knisely  CW, Irie  K, and Moriya  Y (1996), Effects of weir plate inclination angle on flow-induced vibrations of long-span, shell-type gates, JSME Int. J., Ser. C 39(2), 203–211.
Pierce  AD (1993), Waves on fluid-loaded inhomogeneous elastic shells of arbitrary shape, J. Vibr. Acoust. 115(4), 384–390.
Patitsas  SN and Patitsas  AJ (1990), Vibrations in a fluid layer between an elastic or rigid sphere and a concentric rigid or elastic shell, J. Fluids Struct. 4(2), 203–217.
Peake  N (1997), Behavior of a fluid-loaded cylindrical shell with mean flow, J. Fluid Mech. 338, 387–410.
Peng  C, Lee  JM, and Toksoz  MN (1996), Pressure in a fluid-filled borehole caused by a seismic source in stratified media, Geophysics 61(1), 43–55.
Pettigrew  MJ, Taylor  CE, and Kim  BS (1989), Vibration of tube bundles in two-phase cross-flow, Part 1: Hydrodynamic mass and damping, ASME J. Pressure Vessel Technol. 111(4), 466–477.
Podolsky  IV (1994), Natural frequencies of vibrations of ribbed cylindrical shells in a liquid, Prikl. Mekh. 30(8), 59–63.
Rogacheva  NN (1987), Influence of fluid viscosity and pressure on shell vibrations in a fluid, J. Appl. Math. Mech. 51(4), 504–509.
Rogacheva  NN (1988), Forced vibrations of piezoceramic cylinder shell with longitudinal polarization, J. Appl. Math. Mech. 52(5), 641–646.
Rogers  RJ, Merg  MM, Rampen  WHS, Soh  YT, Teu  HM, and Wang  TK (1990), Harmonic modeling of nonlinear fluid forces in finite length, cylindrical squeeze films, J. Fluids Struct. 4(6), 583–603.
Tani  J and Zhang  H (1988), Hydroelastic vibrations of liquid-filled finite length, rotating cylindrical shells, Trans. JSME C 54(507), 2633–2639.
Weaver  RL (1994), Diffuse waves on submerged thin shells, J. Acoust. Soc. Am. 95(2), 857–865.
Yoshikawa  S, Williams  EG, and Washburn  KB (1994), Vibration of two concentric submerged cylindrical shells coupled by the entrained fluid, J. Acoust. Soc. Am. 95(6), 3273–3286.
Zeng  X and Bielak  J (1995), Stable symmetric FE: Boundary integral coupling methods for fluid-structure interface problems, Eng. Anal. Boundary Elem. 15(1), 79–91.
Zhu  F (1991), Orthogonality of wet modes in coupled vibration, J. Sound Vib. 146(3), 439–448.
Zhu  F (1992), Free vibration of fluid filled toroidal shells, J. Sound Vib. 155(2), 343–352.
Zhu  YY (1992), Vibration characteristics of offshore cylindrical tanks, Appl. Math. Mech. 13(1), 17–28.
Zhu  Y and Guo  R (1996), Vibration of elastic spherical shell in bubbly layer, J Vib Eng 9(3), 237–243.
Ross  CTF and Richards  WD (1998), Vibration of ring-reinforced circular cylinders under external water pressure, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 212(C4), 299–306.
Ross  CTF and Johns  T (1989), Dynamic buckling of thin-walled domes under external water pressure, Res. Mech. 28(1–4), 113–137.
Ross  CTF (1996), Vibration and elastic instability of thin-walled domes under uniform external pressure, Thin-Walled Struct. 26(3), 159–177.
Ross  CTF (1995), Vibration and elastic instability of thin-walled conical shells under external pressure, Comput. Struct. 55(1), 85–94.
Ross  CTF, Johns  T, and Stanton  RM (1992), Vibrations of circular cylindrical shells under external water pressure, Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci. 206(C2), 79–86.
Smith  MJ and Hodges  DH (2000), Evaluation of computational algorithms suitable for fluid-structure interactions, J. Aircr. 37(2), 282–294.
Mead  DG (1996), Wave propagation in continuous periodic structures: Research contributions from Southampton, 1964–1995, J. Sound Vib. 190(3), 495–524.
Blaise  A and Lesueur  C (1992), Acoustic transmission through a 2D orthotropic multilayered infinite cylindrical shell, J. Sound Vib. 155(1), 95–109.
Blaise  A, Lesueur  C, Gotteland  M, and Barbe  M (1991), Sound transmission into an orthotropic infinite shell: Comparison with Koval’s results and understanding of phenomena, J. Sound Vib. 150(2), 233–243.
Borgiotti  GV and Rosen  EM (1992), State vector approach to the wave and power flow of the forced vibrations of a cylindrical shell Part 1: Infinite cylinders in vacuum, J. Acoust. Soc. Am. 91(2), 911–925.
Borgiotti  GV and Rosen  EM (1993), State vector approach to the wave analysis of the forced vibration of a cylindrical shell, Part II: Finite cylinders in vacuum, J. Acoust. Soc. Am. 93(2), 864–874.
Borgiotti  GV and Rosen  EM (1994), Power flow analysis of surface waves on a cylindrical elastic shell in an acoustic fluid, J. Acoust. Soc. Am. 95(1), 244–255.
Choi  MS and Joo  YS (1997), Theory of the background amplitudes in acoustic resonance scattering, J. Acoust. Soc. Am. 101(4), 2083–2087.
Crane  SP, Cunefare  KA, Englestad  SP, and Powell  EA (1997), Comparison of design optimization formulations for minimization of noise transmission in a cylinder, J. Aircr. 34(2), 236–243.
Cushieri  JM and Feit  D (1994), Hybrid solution for the response Green’s function of a fluid-loaded cylindrical shell, J. Acoust. Soc. Am. 96(5), 2776–2784.
Cushieri  JM and Feit  D (1995), Acoustic scattering from a fluid-loaded cylindrical shell with discontinuities: Single plate bulkhead, J. Acoust. Soc. Am. 98(1), 320–338.
Cushieri  JM and Feit  D (1995), Acoustic scattering from a fluid-loaded cylindrical shell with discontinuities: Double plate bulkhead, J. Acoust. Soc. Am. 98(1), 339–352.
Cushieri  JM and Feit  D (2000), Influence of circumferential partial coating on the acoustic radiation from a fluid-loaded shell, J. Acoust. Soc. Am. 107(6), 3196–3207.
Feng  L (1995), Noise and vibration of a fluid filled elastic pipe coated with absorptive layer on the inner side of the wall, J. Sound Vib. 183(1), 169–178.
Junger  MC (1993), Scattering enhancement by supersonic resonances of cylindrical shells, J. Acoust. Soc. Am. 93(4), 1743–1746.
Lebedev  AV (1993), Asymptotic method for predicting low-frequency acoustic radiation from a cylindrical shell of finite length, J. Acoust. Soc. Am. 94(6), 3493–3502.
Leon  F, Lecroq  F, Decultot  D, and Maze  G (1992), Scattering of an obliquely incident acoustic wave by an infinite hollow cylindrical shell, J. Acoust. Soc. Am. 91(3), 1388–1397.
Photiadis  DM, Williams  EG, and Houston  BH (1997), Wave-number space response of a near periodically ribbed shell, J. Acoust. Soc. Am. 101(2), 877–886.
Photiadis  DM, Houston  BH, Williams  EG, and Bucaro  JA (2000), Resonant response of complex shell structures, J. Acoust. Soc. Am. 108(3-Pt1), 1027–1035.
Qaisi  MI (1989), Axisymmetric acoustic vibrations of simply-supported cylindrical shells, Appl. Acoust. 26(1), 33–43.
Radlinski  R and Simon  MM (1993), Acoustic and elastic wave scattering from elliptic cylindrical shells, J. Acoust. Soc. Am. 93(5), 2443–2453.
Shulga  VM (1999), Propagation of acoustoelectric waves in the hollow cylinder with the radial axis of symmetry of physico-mechanical properties (Russian), Prikl. Mekh. b(7), 49–58.
Utschig  M, Achenbach  JD, and Igusa  T (1996), Reduction to parts: A semianalytical approach to the structural acoustics of a cylindrical shell with hemispherical endcaps, J. Acoust. Soc. Am. 100(1), 871–881.
Veksler  ND, Izbicki  JL, and Conoir  JM (1994), Bending A wave in the scattering by a circular cylindrical shell: Its relation with the bending free modes, J. Acoust. Soc. Am. 96(1), 287–293.
Veksler  ND, Maze  G, Ripoche  J, and Porochovskii  V (1996), Scattering of an obliquely incident plane acoustic wave by a circular cylindrical shell: Results of computations, Acustica 82(5), 689–697.
Veksler  N, Izbicki  JL, and Conoir  JM (1999), Elastic wave scattering by a cylindrical shell, Wave Motion 29(3), 195–209.
Wu  C, Chen  H, and Huang  X (1998), Theoretical prediction of sound radiation from a heavy fluid-loaded cylindrical coated shell, Chinese J. Mech. Eng. 11(4), 249–256.
Wu  CJ, Chen  HL, and Huang  XQ (1999), Vibroacoustic analysis of a fluid-loaded cylindrical shell excited by a rotating load, J. Sound Vib. 225(1), 79–94.
Wu  JH, Chen  HL, and An  WB (2000), Method to predict sound radiation from a plate-ended cylindrical shell excited by an external force, J. Sound Vib. 237(5), 793–803.
Wang  C and Lai  JCS (2000), Sound radiation efficiency of finite length acoustically thick circular cylindrical shells under mechanical excitation—I: Theoretical analysis, J. Sound Vib. 232(2), 431–447.
Rumerman  ML (1991), Increased accuracy in the application of the Sommerfeld-Watson transformation to acoustic scattering from cylindrical shells, J. Acoust. Soc. Am. 90(5), 2739–2750.
Doria  A and Morellati  D (1998), Influence of aspect ratio and material on the sound radiation of low frequency modes of baffled cylindrical shells, J. Sound Vib. 209(2), 377–384.
Sun  JQ, Norris  MA, Rossetti  DJ, and Highfill  JH (1996), Distributed piezoelectric actuators for shell interior noise control, J. Vibr. Acoust. 118(4), 676–681.
Ismail  F and Fyfe  KR (1990), Modeling cylinder acoustics of flexural and shell modes, Int. J. Anal. Exp. Modal Anal. 5(1), 25–32.
Wen  L, Luo  D, Chen  Y, and Chen  M (1999), Sound radiation from finite submerged stiffened cylindrical shell (Chinese), J. Huazhong Univ. Sci. Technol. 27(8), 54–56.
Hickling  R, Ball  JF, Burrows  RK, and Petrovic  M (1992), Computational structural acoustics applied to scattering of sound by spherical shells, J. Acoust. Soc. Am. 92(1), 499–509.
Pathak  AG and Stepanishen  PR (1994), Acoustic harmonic radiation from fluid-loaded spherical shells using elasticity theory, J. Acoust. Soc. Am. 96(4), 2564–2575.
Zhang  J (1990), Time-domain analysis for vibration and sound radiation of submerged spherical shell excited by force, Chinese J Acoustics 9(2), 129–138.
Zhang  J and Zhang  G (1990), Analysis of acoustic radiation and scattering from a submerged spherical shell by energy streamlines, J. Acoust. Soc. Am. 88(4), 1981–1985.
Rossing  TD, Zhao  H, and Fystrom  DO (1992), Acoustics of snare drums, J. Acoust. Soc. Am. 92(1), 84–94.
Eisinger  FL (1994), Unusual acoustic vibration of a shell and tube process heat exchanger, ASME J. Pressure Vessel Technol. 166(2), 141–149.
Norris  A and Vasudevan  N (1992), Acoustic wave scattering from thin shell structures, J. Acoust. Soc. Am. 92(6), 3320–3336.
Partridge  C (1996), Acoustic scattering from viscoelastically coated bodies, J. Acoust. Soc. Am. 99(1), 72–78.
Werby  MF (1991), Isolation of resonances and the ideal acoustical background for submerged elastic shells, Acoust. Lett. 15(4), 65–70.
Rebinsky  DA and Norris  NA (1996), Dispersion of flexural waves on shells, J. Vibr. Acoust. 118(3), 526–529.
Smoglie  C (1996), Acoustical resonance of tube-in shell units, J. Vibr. Acoust. 118(3), 299–305.
Sorokin  SV (1995), Analysis of vibrations of a spatial acoustic system by the boundary integral equations method, J. Sound Vib. 180(4), 657–667.
Stepanishen  PR and Ramakrishna  S (1993), Acoustic radiation from cylinders with a plane of symmetry using internal multipole line source distributions, J. Acoust. Soc. Am. 93(2), 658–672.
Veksler  ND (1992), Frequencies of the maximal Q-factor of Lamb-type peripheral waves for the problem of acoustic wave scattering by an elastic shell, Acoust. Lett. 16(4), 78–83.
Veksler  ND and Izbicki  JL (1996), Modal resonances of peripheral waves, Acustica 82(3), 401–410.
Amabili  M and Dalpiaz  G (1997), Free vibrations of cylindrical shells with non-axisymmetric mass distribution on elastic bed, Meccanica 32(1), 71–84.
Yim  JS, Sohn  DS, and Lee  YS (1998), Free vibration of clamped free circular cylindrical shell with a plate attached at an arbitrary axial position, J. Sound Vib. 213(1), 75–88.
McDaniel  JG (1998), Power flow to a cylindrical shell with an attached structure, J. Acoust. Soc. Am. 103(6), 3386–3392.
Cheng  L and Nicolas  J (1992), Free vibration analysis of a cylindrical shell-circular plate system with general coupling and various boundary conditions, J. Sound Vib. 155(2), 231–247.
Librescu  L and Lin  W (1997), Postbuckling and vibration of shear deformable flat and curved panels on a nonlinear elastic foundation, Int. J. Non-Linear Mech. 32(2), 211–225.
Paliwal  DN and Sivastava  R (1994), Vibrations of a shallow spherical shell on a Kerr foundation, J. Vibr. Acoust. 116(1), 47–52.
Paliwal  DN, Kanagasabapathy  H, and Gupta  KM (1995), Vibrations of an orthotropic shallow spherical shell on a Kerr foundation, Int. J. Pressure Vessels Piping 64(1), 17–24.
Paliwal  N, Pandey  RK, and Nath  T (1996), Free vibrations of circular cylindrical shell on Winkler and Pasternak foundations, Int. J. Pressure Vessels Piping 69(1), 79–89.
Rudnikki  M (1989), Modified hypothesis of theory of thin magnetoelastic shells, Mech. Teor. Stosawana 27(3), 407–417.
Folso  R (1998), Spectral fatigue damage calculation in the side shells of ships, with due account taken of the effect of alternating wet and dry areas, Mar. Struct. 11(7–8), 319–343.
Liew  KM, Lim  MK, Lim  CW, Li  DB, and Zhang  YR (1995), Effects of initial twist and thickness variation on the vibration behavior of shallow conical shells, J. Sound Vib. 180(2), 271–296.
Liew  KM, Hung  KC, and Lim  MK (1995), Vibration of stress free hollow cylinders of arbitrary cross section, ASME J. Appl. Mech. 42(4), 880–886.
Sivadas  KR and Ganesan  N (1993), Axisymmetric vibration analysis of thick cylindrical shell with variable thickness, J. Sound Vib. 160(3), 387–400.
Missaoui  J, Cheng  L, and Richard  MJ (1996), Free and forced vibration of a cylindrical shell with a floor partition, J. Sound Vib. 190(1), 21–40.
Liu  WH and Huang  CC (1992), Vibration analysis of folded plates, J. Sound Vib. 157(1), 123–137.
Sivasubramonian  B, Kulkarni  AM, Rao  GV, and Krishnan  A (1997), Free vibration of curved panels with cutouts, J. Sound Vib. 200(2), 227–234.
Levin  EM and Pankova  NV (1989), Excitation of elastic vibrations during directional displacement of a split shell with a specified rotational axis, Sov Machine Sci 6, 61–66.
Hinton  E, Ozakca  M, and Sienz  J (1993), Optimum shapes of vibrating axisymmetric plates and shells, J. Sound Vib. 167(3), 511–528.
Hinton  E, Ozakca  M, and Rao  NVR (1993), Structural shape optimization of vibrating shells and folded plates using two-noded finite strips, Eng. Comput. 10(2), 139–157.
Afonso  SMB and Hinton  E (1995), Free vibration analysis and shape optimization of variable thickness plates and shells, I: FE studies, Comput. Syst. Eng. 6(1), 27–45.
Afonso  SMB and Hinton  E (1995), Free vibration analysis and shape optimization of variable thickness plates and shells II: Sensitivity analysis and shape optimization, Comput. Syst. Eng. 6(1), 47–66.
Inoue  K, Townsend  DP, and Coy  JJ (1993), Optimum design of a gearbox for low vibration, J. Mech. Des. 115(4), 1002–1007.
Nordgren  RP (1989), Design of tension leg platforms by a constrained optimization method, ASME J. Offshore Mech. Arct. Eng. 111(3), 194–202.
Dudnik  RA, Makeyeva  EA, and Fiyaksel  EA (1990), Influence of inhomogeneities on the vibrations of a cylindrical shell, J. Appl. Math. Mech. 54(4), 508–512.
Hamdan  FH (2000), Seismic behavior of cylindrical steel liquid storage tanks, J. Construct. Steel Res. 53(3), 307–333.
Huang  SC and Hsu  BS (1992), Vibration of spinning ring-stiffened thin cylindrical shells, AIAA J. 30(9), 2291–2298.
Huang  JJ, Chou  CS, and Chang  CO (1997), Precession of vibrational modes of a rotating hemispherical shell, J. Vibr. Acoust. 119(4), 612–617.
Au-Yang  MK and Brenneman  B (1995), Flow induced vibration test of an advanced water reactor model, Part 1: Turbulence induced forcing function, Nucl. Eng. Des. 157(1–2), 93–109.
Cheng  L (1995), Fluid-structural coupling of a plate-ended cylindrical shell: Vibration and internal sound field, J. Sound Vib. 174(5), 641–654.
Coquart  L, Depeursinge  C, Curnier  A, and Ohayon  R (1992), Fluid-structure interaction problem in biomechanics: Prestressed vibrations of the eye by the FEM, J. Biomech. 25(10), 1105–1118.
Horacek  J, Trnka  J, and Vesely  J (1992), Dynamic properties of a thin cylindrical liquid storage tank, Strojnicky Casopis 43(2), 135–148.
Kaduchak  G and Marston  PL (1993), Observation of the midfrequency enhancement of tone bursts back scattered by a thin spherical shell in water near the coincidence frequency, J. Acoust. Soc. Am. 93(1), 224–230.
D’Cruz  J (1997), Global attenuation of random vibrations in a tapered and swept panel, J. Sound Vib. 199(5), 751–776.
Bardell  NS, Dunsdon  JM, and Langley  RS (1998), Free vibration of thin, isotropic conical shells, J. Sound Vib. 217(2), 297–320.
Lim  CW and Liew  KM (1996), Vibration of shallow conical shells with shear flexibility: A first-order theory, Int. J. Solids Struct. 33(4), 451–468.
Ng  TY, Hua  L, Lam  KY, and Loy  CT (1999), Parametric instability of conical shells by the generalized differential quadrature method, Int. J. Numer. Methods Eng. 44(6), 819–837.
Stanley  AJ and Ganesan  N (1996), Frequency response of shell-plate combinations, Comput. Struct. 59(6), 1083–1094.
Ramesh  TC and Ganesan  N (1994), Orthotropic cylindrical shells with a viscoelastic core: A vibration and damping analysis, J. Sound Vib. 175(4), 535–555.
Shu  H, Li  S, Sun  L, Zhong  Y, and Huazhong  J (2000), Dynamic response and sensitivity analysis of cylindrical shells based on finite strip model (Chinese), Univ. Sci. Tech. 28(3), 36–38.

Figures

Grahic Jump Location
Number of articles on shell dynamics per year

Tables

Errata

Discussions

Some tools below are only available to our subscribers or users with an online account.

Related Content

Customize your page view by dragging and repositioning the boxes below.

Related Journal Articles
Related eBook Content
Topic Collections

Sorry! You do not have access to this content. For assistance or to subscribe, please contact us:

  • TELEPHONE: 1-800-843-2763 (Toll-free in the USA)
  • EMAIL: asmedigitalcollection@asme.org
Sign In