آزمایشگاه تحقیقاتی آکوستیک- مدیر آزمایشگاه
مدیر آزمایشگاه

بازیابی تصاویر و رنگ‌ها

نام: دکتر سیدمحمد هاشمی نژاد

رتبه علمی: استاد

تلفن: 50-77240540 داخلی: 2936

فاکس: 77240488

پست الکترونیکی: hashemi AT iust.ac.ir

آدرس: دانشکده مهندسی مکانیک، دانشگاه علم و صنعت ایران، تهران، ایران

دانشگاه های محل تحصیل

  • دکترا، دانشگاه Colorado، آمریکا، 1992
  • فوق لیسانس، دانشگاه Santa Clara، آمریکا، 1985
  • لیسانس، دانشگاه Cal. State University Chico، آمریکا، 1983

تجربیات

  • Lecturer, Dept. of Mech. Eng., Colorado School of Mines, Golden, Colorado, USA, (1992-1993)
  • Lecturer, Westminster Community College, Westminster, Colorado, USA (1992-1993)
  • Lecturer, Dept. of Aerospace Eng., Research Div., Azad Univ., Poonak, Tehran, 1999-2002.
  • Research Assistant, Dept. of Mech. Eng., U.C. Boulder, Colorado, 1988-1992.
  • Engineering Technician, General Instruments, Palo Alto, California, 1983-1985.

زمینه های تحقیقاتی

  • آکوستیک سازه ای
  • ارتعاشات
  • جریان عدد رینولدز پایین

CAREER INTERESTS

Preference for Applied Mechanics-related research and education; interested in development of

analytical, computational and experimental techniques applicable to the theory and practice of Structural

Acoustics, Fluid/Solid Interaction, Multiple Scattering, Underwater/underground acoustics,

Environmental Acoustics, Building Acoustics, Active Noise and Vibration Control, Stress Wave

Propagation, Dynamic Poroelasticity, Flow-induced Vibration, Supersonic Flutter, Floating Structures,

Liquid Sloshing, Surface Gravity Waves, Elastodynamics, Structural Dynamics, Dynamic

Thermoelasticity, Heat Conduction, and Low Re Number Flow, with special focus on dynamic response

analysis and active control problems involving Functionally Graded, Nanocomposite, Piezoelectric,

Electrorheological, Magnetorheological, Auxetic, Shape Memory, and Micropolar materials.

EDUCATION

Ph.D., Mechanical Engineering, University of Colorado, Boulder, USA (1992).

M.S., Mechanical Engineering, Santa Clara University, Santa Clara, USA (1985).

B.S., Mechanical Engineering, Cal. State University Chico, California USA (1983).

KEY PUBLICATIONS

1. S. M. Hasheminejad and T.L. Geers, “Linear vibration analysis of an ultrasonic cleaning

problem,” Journal of the Acoustical Society of America, 1991, Vol. 90, no. 6, pp. 3238-3247.

2. S. M. Hasheminejad and T.L. Geers, “Doubly asymptotic approximations for an acoustic

halfspace,” ASME Journal of Vibration and Acoustics, 1992, Vol. 114, pp. 555-563.

3. S. M. Hasheminejad and T.L. Geers, “Modal impedances for two spherical surfaces in a

thermoviscous fluid,” Journal of the Acoustical Society of America, 1993, Vol. 94, pp. 2205-2214.

4. S. M. Hasheminejad, “Modal impedances for a spherical source in a fluid-filled spherical cavity

embedded within a fluid-infiltrated elastic porous medium,” International Journal of Solids and

Structures, 1998, Vol. 35, pp. 129-148.

5. S. M. Hasheminejad, “Modal acoustic force on a spherical radiator in an acoustic halfspace with

locally reacting boundary,”Acustica/Acta Acustica, 2001, Vol. 87, pp. 443-453.

6. S. M. Hasheminejad and H. Hosseini, “Radiation loading of a cylindrical source in a fluid-filled

cylindrical cavity embedded within a fluid saturated poroelastic medium,” ASME Journal of Applied

Mechanics, 2002, Vol. 69, pp. 675-683.

7. S. M. Hasheminejad and H. Hosseini, “Dynamic stress concentration near on a fluid-filled

permeable borehole induced by general modal vibrations of an internal cylindrical radiator,”Soil

Dynamics and Earthquake Engineering, 2002, Vol. 22, pp. 441-458.

8. S. M. Hasheminejad and B. Harsini, “Effects of dynamic viscoelastic properties on acoustic

diffraction by a solid sphere,” Archive of Applied Mechanics, 2002, Vol. 72, pp. 697-712.

9. S. M. Hasheminejad and N. Safari, “Dynamic viscoelastic effects on sound wave diffraction by

spherical and cylindrical shells submerged in and filled with viscous compressible fluids,” Shock and

Vibration, 2003, Vol. 10, pp. 339-363.

10. S. M. Hasheminejad and M. Azarpeyvand, “Modal vibrations of an infinite cylinder in an

acoustic halfspace,” International Journal of Engineering Science, 2003, Vol. 41, pp. 2253-2271.

11. S. M. Hasheminejad and M. Azarpeyvand, “Energy distribution and radiation loading of a

cylindrical source suspended within a nonconcentric fluid cylinder,” Acta Mechanica, 2003, Vol. 164,

pp. 15-30.

12. S. M. Hasheminejad and M. Azarpeyvand, “Eccentricity effects on acoustic radiation from a

spherical source suspended within a thermoviscous fluid sphere,” IEEE Transactions on Ultrasonics

Ferroelectrics and Frequency Control, 2003, Vol. 50, pp. 1444-1454.

13. S. M. Hasheminejad and M. Azarpeyvand, “Non-axisymmetric acoustic radiation from a

transversely oscillating rigid sphere above a rigid/compliant planar boundary,” Acustica/Acta Acustica,

2003, Vol. 89, pp. 998-1007.

14. S. M. Hasheminejad, “Modal acoustic impedance force on a spherical source near a rigid

interface,” Acta Mechanica Sinica, 2003, Vol. 19, no. 1, pp. 33-39.

15. S. M. Hasheminejad and M. Najafi, "Modeling and prediction of acoustic performance of

reactive mufflers based on transmission loss approach," Amirkabir Journal of Science and Technology,

2003, Vol. 14, pp. 755-764.

16. S. M. Hasheminejad and M. Azarpeyvand, “Acoustic radiation from a pulsating spherical cap

set on a spherical baffle near a hard/soft flat surface,” IEEE Journal of Oceanic Engineering, 2004,

Vol. 29, no. 1, pp. 110-117.

17. S. M. Hasheminejad and S. A. Badsar,“Acoustic scattering by a poroelastic sphere near a flat

boundary,” Japanese Journal of Applied Physics, 2004, Vol. 43, no. 5A, pp. 2612-2623.

18. S. M. Hasheminejadand M. Azarpeyvand, “Harmonic radiation from a liquid-filled spherical

acoustic lens with an internal eccentric spherical source,” Mechanics Research Communications, 2004,

Vol. 31, no. 1, pp. 493-506.

19. S. M. Hasheminejad and M. Azarpeyvand, “Sound radiation from a liquid-filled underwater

spherical acoustic lens with an internal eccentric baffled spherical piston,” Ocean Engineering, 2004,

Vol. 31, pp. 1129-1146.

20. S. M. Hasheminejad and S. A. Badsar, “Acoustic scattering by a pair of poroelastic spheres,”

Quarterly Journal of Mechanics and Applied Mathematics, 2004, Vol. 57, pp. 95-113.

21. S. M. Hasheminejad and M. Azarpeyvand, “Vibrations of a cylindrical radiator over an

impedance plane,” Journal of Sound and Vibration, 2004, Vol. 278, pp. 461-477.

22. S. M. Hasheminejad and S. Mehdizadeh, “Acoustic radiation from a finite spherical source

placed in fluid near a poroelastic sphere,Archive of Applied Mechanics, 2004, Vol. 74, pp. 59-74.

23. S. M. Hasheminejad and M. Azarpeyvand, “Sound radiation due to modal vibrations of a

spherical source in an acoustic quarterspace,”Shock and Vibration, 2004, Vol. 11, pp. 625-635.

24. S. M. Hasheminejad and M. Azarpeyvand, “Acoustic radiation from a shell-encapsulated baffled

cylindrical cap,” Acoustical Physics, 2005, Vol. 51, pp. 419-427.

25. S. M. Hasheminejad and N. Safari, “Acoustic scattering from viscoelastically coated spheres

and cylinders in viscous fluids,Journal of Sound and Vibration, 2005, Vol. 280, pp. 101-125.

26. S. M. Hasheminejad and M. Azarpeyvand, “Acoustic radiation from a cylindrical source close to

a rigid corner,”Zeitschrift fur Angewandte Mathematik und Mechanik, 2005, Vol. 85, pp. 66-74.

27. S. M. Hasheminejad and S. A. Badsar, “Elastic wave scattering by two spherical inclusions in a

poroelastic medium,” ASCE Journal of Engineering Mechanics, 2005,Vol. 131, pp. 953-965.

28. S. M. Hasheminejad, “Acoustic scattering by a fluid-encapsulating spherical viscoelastic

membrane including thermoviscous effects,” Journal of Mechanics,2005, Vol. 21, pp. 205-215.

29. S. M. Hasheminejad and S. A. Badsar, “Scattering of plane waves by a rigid sphere in an

acoustic quarterspace,” JSME International Journal, 2005,Vol. 48, pp.776-782.

30. S. M. Hasheminejad and M. Azarpeyvand, “Radiation impedance loading of a spherical source

in a two-dimensional perfect acoustic waveguide,” Acoustical Physics, 2006, Vol. 52, pp.104-115.

31. S. M. Hasheminejad and M. A. Alibakhshi, “Dynamic viscoelastic and multiple scattering

effects in fiber suspensions,” Journal of Dispersion Science and Technology, 2006, Vol. 27, pp. 219-

234.

32. S. M. Hasheminejad and S. Mehdizadeh, “Acoustic performance of a multilayer close-fitting

hemispherical enclosure,” Noise Control Engineering Journal,2006, Vol. 54, pp. 86-100.

33. S. M. Hasheminejad and R. Avazmohammadi, “Acoustic diffraction by a pair of poroelastic

cylinders,” Zeitschrift fur Angewandte Mathematik und Mechanik, 2006, Vol. 8, pp. 589-605.

34. S. M. Hasheminejad and M. Azarpeyvand, “Sound pressure attenuation in an acoustically lined

parallel plate duct containing an off-center cylindrical radiator,” Acustica/Acta Acustica, 2006, Vol. 92,

pp. 417-426.

35. S. M. Hasheminejad and R. Sanaei, “Ultrasonic scattering by a viscoelastic fiber of elliptic cross

section suspended in a viscous fluid medium,” Journal of Dispersion Science and Technology, 2006,

Vol. 27, pp. 1165-1179.

36. S. M. Hasheminejad and R. Avazmohammadi, “Harmonic wave diffraction by two circular

cavities in a poroelastic formation,” Soil Dynamics and Earthquake Engineering, 2007, Vol. 27, pp. 29-

41.

37. S. M. Hasheminejad and M. A. Alibakhshi, “Ultrasonic scattering from compressible cylinders

including multiple scattering and thermoviscous effects,” Archives of Acoustics, 2006, Vol. 31, pp. 243-

263.

38. S. M. Hasheminejad and M. A. Alibakhshi, “Two-Dimensional Scattering from an Impenetrable

Cylindrical Obstacle in an Acoustic Quarterspace,” Forschungim Ingenieurwesen(Engineering

Research), 2006, Vol. 70, pp. 179-186.

39. S. M. Hasheminejad and M. Maleki, “Diffraction of elastic waves by a spherical inclusion with

an anisotropic graded interfacial layer and dynamic stress concentrations,” Journal of Nondestructive

Evaluation, 2006, Vol. 25, pp. 67-81.

40. S. M. Hasheminejad and M. A. Alibakhshi, “Diffraction of sound by a poroelastic cylindrical

absorber near an impedance plane,” International Journal of Mechanical Sciences, 2007, Vol. 49, pp.

1-12.

41. S. M. Hasheminejad and M. Maleki, “Interaction of a plane progressive sound wave with a

functionally graded spherical shell,” Ultrasonics, 2006, Vol. 45, pp. 165-177.

42. S. M. Hasheminejad and R. Avazmohammadi, “Elastic wave scattering in porous unidirectional

fiber-reinforced composites,” Journal of Reinforced Plastics and Composites, 2007, Vol. 26, pp. 495-

517.

43. S. M. Hasheminejad and R. Sanaei, “Acoustic scattering by an elliptic cylindrical absorber,”

Acustica/Acta Acustica, 2007,Vol. 93, pp.789-803.

44. S. M. Hasheminejad and R. Sanaei, “Ultrasonic scattering by a spheroidal suspension including

dissipative effects” Journal of Dispersion Science and Technology, 2007, Vol. 28, pp. 1093 – 1107.

45. S. M. Hasheminejad and A.K. Miri, “Effect of inter-fiber distance on energy transfer in

unidirectional composites containing transverse ultrasonic waves,” Advanced Composites Letters,2006,

Vol. 15, pp.157-166.

46. S. M. Hasheminejad and A. H. Pasdar, “Computation of acoustic field by a spherical source near

a thermoviscous fluid sphere,” Journal of Computational Acoustics, 2007, Vol. 15, pp.159-180.

47. S. M. Hasheminejad and M. Rajabi, “Acoustic resonance scattering from a submerged

functionally graded cylindrical shell,Journal of Sound and Vibration, 2007, Vol. 302, pp. 208-228.

48. S. M. Hasheminejad and R. Sanaei, “Acoustic radiation force and torque on a solid elliptic

cylinder” Journal of Computational Acoustics, 2007, Vol. 15, pp. 377-399.

49. S. M. Hasheminejad and R. Sanaei, “Effects of fiber ellipticity and orientation on dynamic stress

concentrations in porous fiber-reinforced composites,” Computational Mechanics, 2007, Vol. 40, pp.

1015-1036.

50. S. M. Hasheminejad and M. Maleki, “Acoustic resonance scattering from a submerged

anisotropic sphere,” Acoustical Physics, 2008, Vol. 54, pp. 168-179.

51. S. M. Hasheminejad and A.K. Miri, “Ultrasonic energy transfer and stress concentrations in a

single-fiber composite with absorbing interface layer,” Journal of Thermoplastic Composite Materials,

2008, Vol. 21, pp. 473-509.

52. S. M. Hasheminejad and A.K. Miri, “Dynamic interaction of an eccentric multipole cylindrical

radiator suspended in a fluid-filled borehole within a poroelastic formation,” Acta Mechanica Sinica,

2007, Vol. 23, pp. 399-408.

53. S. M. Hasheminejad and M. Maleki, “Effect of interface anisotropy on elastic wave propagation

in particulate composites,” Journal of Mechanics, 2008, Vol. 24, pp. 77-93.

54. S. M. Hasheminejad and M. A. Alibakhshi, “Eccentricity and thermoviscous effects on

ultrasonic scattering from a liquid-coated fluid cylinder,” Journal of Zhejiang University Science, 2008,

Vol. 9, pp. 65-78.

55. S. M. Hasheminejadand S. Kazemirad, “Dynamic response of an eccentrically lined circular

tunnel in poroelastic soil under seismic excitation,”Soil Dynamics and Earthquake Engineering, 2008,

Vol. 28, pp. 277-292.

56. S. M. Hasheminejad and M. Rajabi, “Acoustic scattering characteristics of a thick-walled

orthotropic cylindrical shell at oblique incidence,Ultrasonics, 2007, Vol. 47, pp. 32-48.

57. S. M. Hasheminejad and H. Hosseini, “Nonaxisymmetric interaction of a spherical radiator in a

fluid-filled permeable borehole,” International Journal of Solids and Structures, 2008, Vol. 45, pp. 24-

47.

58. S. M. Hasheminejad and M. Komeili,"Dynamic response of a thick FGM tube under a moving

load," Proceedings of the IMECHE, Part C, Journal of Mechanical Engineering Science, 2007, Vol.

221, pp.1545-1554.

59. S. M. Hasheminejad and H. Hosseini, “Dynamic interaction of a spherical radiator in a fluidfilled

cylindrical borehole within a poroelastic formation,” Mechanics Research Communications, 2008,

Vol. 35, pp.158-171.

60. S. M. Hasheminejad and S. Kazemirad, “Scattering and absorption of sound by a compound

cylindrical porous absorber with an eccentric core,”Acustica/Acta Acustica, 2008, Vol. 94, pp.79-90.

61. S. M. Hasheminejad, A. Shahsavarifard, and M. Shahsavarifard, “Dynamic Viscoelastic Effects

on Free Vibrations of a Submerged Fluid-filled Thin Cylindrical Shell,” Journal of Vibration and

Control, 2008, Vol. 14, pp.849-865.

62. S. M. Hasheminejad and R. Sanaei, “Ultrasonic scattering by a fluid cylinder of elliptic cross

section including viscous effects” IEEE Transactions on Ultrasonics Ferroelectrics and Frequency

Control, 2008, Vol. 55, pp. 391-404.

63. S. M. Hasheminejad and M. Shabanimotlagh, “Sound insulation characteristics of functionally

graded panels,”Acustica/Acta Acustica, 2008, Vol. 94, pp. 290-300.

64. S. M. Hasheminejad and S. Kazemirad, “Dynamic viscoelastic effects on sound wave scattering

by an eccentric compound circular cylinder,”Journal of Sound and Vibration, 2008, Vol. 318, pp.506-

526.

65. S. M. Hasheminejad and R. Avazmohammadi, “Dynamic stress concentrations in lined twin

tunnels within fluid-saturated soil,” ASCE Journal of Engineering Mechanics, 2008, Vol. 134, pp.542-

554.

66. S. M. Hasheminejad and M. Rajabi, “Scattering and active acoustic control from a submerged

piezoelectric-coupled orthotropic hollow cylinder,” Journal of Sound and Vibration, 2008, Vol. 318,

pp.50-73.

67. S. M. Hasheminejad and A.K. Miri, “Seismic isolation effect of lined circular tunnels with

damping treatments,” Earthquake Engineering and Engineering Vibration, 2008, Vol. 7, pp.305-319.

68. S. M. Hasheminejad and M. Rajabi, “Effect of FGM core on dynamic response of a buried

sandwich cylindrical shell in poroelastic soil to harmonic body waves,” International Journal of

Pressure Vessels and Piping, 2008, Vol. 85, pp.762-771.

69. S. M. Hasheminejad and M. Maleki, “Acoustic wave interaction with a laminated transversely

isotropic spherical shell with imperfect bonding,” Archive of Applied Mechanics, 2009, Vol. 79, pp.97-

112.

70. S. M. Hasheminejad and A. Rafsanjani, “Steady state vibration of an FGM plate strip under a

moving line load,” Mechanics of Advanced Materials and Structures, 2009, Vol. 16, pp.417-428.

71. S. M. Hasheminejad and M. Komeili, “Effect of imperfect bonding on axisymmetric

elastodynamic response of a lined circular tunnel in poroelastic soil due to a moving ring

load,”International Journal of Solids and Structures, 2009, Vol. 46, pp.398-411.

72. M. Maleki and S. M. Hasheminejad, “Elastic Wave Scattering in Semi-crystalline Polymers,”

International Journal of Engineering Science, 2009, Vol. 47, pp.767-776.

73. S. M. Hasheminejad and M. Aghabeigi, “Liquid sloshing in half-full horizontal elliptical tanks,”

Journal of Sound and Vibration, 2009, Vol. 324, pp.332-349.

74. S. M. Hasheminejad and M. Maleki, “Free vibration and forced harmonic response of an

electrorheological fluid-filled sandwich plate,” Smart Materials and Structures, 2009, Vol. 18, art. no.

055013.

75. S. M. Hasheminejad and Y. Mirzaei, “Free vibration analysis of an eccentric hollow cylinder

using exact three dimensional elasticity theory,” Journal of Sound and Vibration, 2009, Vol. 326,

pp.687-702.

76. M. Rajabi and S. M. Hasheminejad and, “Acoustic resonance scattering from a multilayered

cylindrical shell with imperfect bonding,” Ultrasonics, 2009, Vol. 49, pp.682-695.

77. S. M. Hasheminejad and A. Ahamdi-Savadkoohi, “Vibro-acoustic behavior of a hollow FGM

cylinder excited by on-surface mechanical drives,” Composite Structures, 2010, Vol. 92, pp.86-96.

78. S. M. Hasheminejad and R. Avazmohammadi, “Size-dependent effective dynamic properties of

unidirectional nanocomposites with interface energy effects,” Composites Science and Technology,

2009, Vol. 69, pp.2538-2546.

79. S. M. Hasheminejad, S. M. Hosseinimaab and M. Maleki, “Acoustic scattering and active

control from a near-surface underwater piezoelastic spherical shell transducer,” IEEE Journal of

Oceanic Engineering, 2010, Vol. 35, pp.438-447.

80. S. M. Hasheminejad and M. Shabanimotlagh, “Magnetic field-dependent sound transmission

properties of magnetorheological elastomer-based adaptive panels,” Smart Materials and Structures,

2010, Vol. 19, art. no. 035006.

81. S. M. Hasheminejad, A. Bahari and S. Abbasion, “Modelling and simulation of acoustic pulse

interaction with a fluid-filled hollow elastic sphere through numerical Laplace inversion,” Applied

Mathematical Modelling, 2011, Vol. 35, pp.22-49.

82. S. M. Hasheminejad, S. Abbasion, and A. Bahari, “Time domain computation and visualization

of shock induced sound fields for a doubly fluid-loaded hollow cylinder,” Computers & Structures,

2010, Vol. 88, pp.1077-1091.

83. B. Gheshlaghi, S. M. Hasheminejad, and S. Abbasion, “Size dependent torsional vibration of

nanotubes,” Physica E: Low-Dimensional Systems and Nanostructures, 2010, Vol. 43, pp.45-48.

84. M.E. Aryaee-Panah, and S. M. Hasheminejad, “Vibration suppression of an elastic plate by use

of an electrorheological patch and constraining layer,” International Journal Of Structural Changes In

Solids, 2010, Vol. 2, art. pp.65-75.

85. S. M. Hasheminejad, S. Abbasion, and Y. Mirzaei, “Acoustic pulse interaction with a

submerged FGM hollow cylinder,” Acoustical Physics, 2011, Vol. 57, pp.20-35.

86. S. M. Hasheminejad and M. M. Mohammadi, “Effect of anti-slosh baffles on free liquid

oscillations in partially filled horizontal circular tanks,” Ocean Engineering, 2011, Vol. 38, pp.49-62.

87. S. M. Hasheminejad, S. Rezaei, and P. Hosseini, “Exact solution for dynamic response ofan

elastic elliptical membrane,” Thin-Walled Structures, 2011, Vol.49, pp.371-378.

88. S. M. Hasheminejad and A. Rafsanjani, “Two-dimensional elasticity solution for transient

response of simply supported beams under moving loads,” Acta Mechanica, 2011, Vol. 217, pp.205-218.

89. S. M. Hasheminejad and Y. Mirzaei, “Exact 3D elasticity solution for free vibrations of an

eccentric hollow sphere,” Journal of Sound and Vibration, 2011, Vol. 330, pp.229-244.

90. S. M. Hasheminejad and B. Gheshlaghi,“Dissipative surface stress effects on free vibrations of

nanowires,” Applied Physics Letters, 2010, Vol. 97, article no. 253103.

91. S. M. Hasheminejad, B. Gheshlaghi,Y. Mirzaei, and S. Abbasion “Free transverse vibrations of

cracked nanobeams with surface effects,” Thin Solid Films, 2011, Vol. 519, pp.2477-2482.

92. S. M. Hasheminejad and M. Aghabeigi, “Transient sloshing in half-full horizontal elliptical

tanks under lateral excitation,” Journal of Sound and Vibration, 2011, Vol. 330, pp.3507-3525.

93. S. M. Hasheminejad and M. Aghabeigi, “Sloshing characteristics in half-full horizontal elliptical

tanks with vertical baffles,” Applied Mathematical Modelling, 2012, Vol. 36, pp.57-71.

94. B. Gheshlaghi,and S. M. Hasheminejad, “Surface effects on nonlinear free vibration of

nanobeams,” Composites: Part B, 2011, Vol. 42, pp.934-937.

95. B. Gheshlaghi,and S. M. Hasheminejad, “Adsorption-induced resonance frequency shift in

Timoshenko microbeams,” Current Applied Physics, 2011, Vol. 11, pp.1035-1041.

96. S. M. Hasheminejad, S.Malakooti, and H. MousaviAkbarzadeh, “Acoustic radiation from a

submerged hollow FGM sphere,” Archive of Applied Mechanics, 2011, Vol. 81, pp.1889-1902.

97. S. M. Hasheminejad, A. Ghaheri, and S. Rezaei, “Semi-analytic solutions for the free in-plane

vibrations of confocal annular elliptic plates with elastically restrained edges,” Journal of Sound and

Vibration, 2012, Vol. 331, pp.434-456.

98. S. M. Hasheminejad and M. Alaei, “Vibroacoustic response and active control of a fluid-filled

FGPM composite cylinder,” Journal of Intelligent Material Systems and Structures, 2012, Vol. 23,

pp.775-790.

99. S. M. Hasheminejad and Y. Mirzaei, “Three dimensional vibration analysis of a class of

traction-free solid elastic bodies with an eccentric cavity,” Shock and Vibration, 2012, Vol. 19, pp.1341-

1357.

100. S. M. Hasheminejad, M. Nezami, and M.E. Aryaee Panah, “Flutter suppression of an elastically

supported plate with electro-rheological fluid core under yawed supersonic flows,” International

Journal of Structural Stability and Dynamics, 2013, Vol. 13, 1250073, DOI:

10.1142/S0219455412500733.

101. B. Gheshlaghi and S. M. Hasheminejad,“Vibration analysis of piezoelectric nanowires with

surface and small-scale effects,” Current Applied Physics, 2012, Vol. 12, pp.1096-1099.

102. S. M. Hasheminejad, M. Nezami, and M.E. Aryaee-Panah, “Supersonic flutter suppression of

electrorheological fluid-based adaptive panels resting on elastic foundations using sliding mode control,”

Smart Materials and Structures, 2012, Vol. 21, art. No. 045005.

103. S. M. Hasheminejad, Rezgar Shakeri, and Shahed Rezaei, “Vibro-acoustic response of an

elliptical plate-cavity coupled system to external shock loads,” Applied Acoustics, 2012, Vol. 73, pp.757-

769.

104. S. M. Hasheminejad, H. Mousavi-Akbarzadeh, and Y. Mirzaei, “Nonaxisymmetric

elastoacoustic analysis of a submerged eccentric hollow sphere: an exact solution,” Acta Mechanica,

2012, Vol. 223, pp.1397-1416.

105. S. M. Hasheminejad, and H. Mousavi-Akbarzadeh, “Vibroacoustic response of an eccentric

hollow cylinder,” Journal of Sound and Vibration, 2012, Vol. 331, pp.3791-3808.

106. S. M. Hasheminejad, and B. Gheshlaghi, “Three-dimensional elastodynamic solution for an

arbitrary thick FGM rectangular plate resting on a two parameter viscoelastic foundation,” Composite

Structures, 2012, Vol. 94, pp.2746-2755.

107. Gheshlaghi, and S. M. Hasheminejad, “Size dependent surface dissipation in thick nanowires,”

Applied Physics Letters, 2012, Vol. 100, article no. 263112.

108. S. M. Hasheminejad, and B. Gheshlaghi, “Eigenfrequencies and quality factors of nanofilm

resonators with dissipative surface stress effects,” Wave Motion, 2013, Vol. 50, pp. 94-100.

109. S. M. Hasheminejad, A. Moshrefzadeh, and M. Jarrahi, “Transient sloshing in partially filled

laterally-excited spherical vessels,” ASCE Journal of Engineering Mechanics, 2013, Vol. 139, pp. 802-

813.

110. S. M. Hasheminejad, S. Rezaei, and R. Shakeri, “Flexural transient response of elastically

supported elliptical plates under in-plane loads using Mathieu function,” Thin-Walled Structures, 2013,

Vol. 62, pp.37-45.

111. S. M. Hasheminejad, and H. Mousavi-Akbarzadeh, “Three dimensional non-axisymmetric

transient acoustic radiation from an eccentric hollow cylinder,” Wave Motion, 2013, Vol. 50, pp.723-

738.

112. S. M. Hasheminejad, A. Ghaheri, and S. Vaezian, “Exact solution for free in-plane vibration

analysis of an eccentric elliptical plate,” Acta Mechanica, 2013, Vol. 224, pp.1609-1624.

113. S. M. Hasheminejad and M. Alaei, “Acoustic radiation and active control from a smart

functionally graded submerged hollow cylinder,” Journal of Vibration and Control, 2014, Vol. 20,

pp.2202-2220.

114. S. M. Hasheminejad, M.M. Keshvari, and M.R. Ashory, “Dynamic stability of super-elliptical

plates resting on elastic foundations under periodic in-plane loads,” ASCE Journal of Engineering

Mechanics, 2014, Vol. 140, pp.172-181.

115. S. M. Hasheminejad, and A. Ghaheri, “Free vibration analysis of a finite-length isotropic solid

elliptic cylinder using exact three dimensional elasticity theory,” Applied Mathematical Modelling,

2013, Vol. 37, pp.8725-8741.

116. S. M. Hasheminejad, and H. Keshavarzpour, “Active sound radiation control of a thick

piezolaminated smart rectangular plate,” Journal of Sound and Vibration, 2013, Vol. 332, pp. 4798-

4816.

117. S. M. Hasheminejad, and S. Vaezian, “Free vibration analysis of an elliptical plate with

eccentric elliptical cut-outs,” Meccanica, 2014, Vol. 49, pp.37-50.

118. B. Gheshlaghi, and S. M. Hasheminejad, “Size dependent damping in axisymmetric vibrations

of circular nanoplates,” Thin Solid Films, 2013, Vol. 537, pp.212-216.

119. S. M. Hasheminejad, H. A. Khaani and R. Shakeri, “Free vibration and dynamic response of a

fluid-coupled double elliptical plate system using Mathieu functions,” International Journal of

Mechanical Sciences, 2013, Vol. 75, pp.66-79.

120. S. M. Hasheminejad, and M. Vahedi, “Active vibration control of a thick piezolaminated beam

with imperfectly integrated sensor and actuator layers,” International Journal of Automation and

Control, 2014, Vol. 8, pp.58-87.

121. A. Oveisi, M. Gudarzi, and S. M. Hasheminejad, “Dynamic response of a thick piezoelectric

circular cylindrical panel: an exact solution,” Shock and Vibration, Vol. 2014, article ID 592165,

http://dx.doi.org/10.1155/2014/592165.

122. A. Oveisi, M. Gudarzi, and S. M. Hasheminejad, “An investigation on free/forced vibration of a

piezoelectric circular cylindrical panel located on an elastic foundation,” International Journal of

Mechanics, 2013, Vol. 7, pp.45-56.

123. S. M. Hasheminejad, and M. Aghayi Motaaleghi, “Supersonic flutter control of an

electrorheological fluid-based smart circular cylindrical shell,” International Journal of Structural

Stability and Dynamics, 2014, Vol. 14, DOI: 10.1142/S0219455413500648.

124. S. M. Hasheminejad, M. M. Mohammadi, and M. Jarrahi, “Liquid sloshing in partly-filled

laterally-excited circular tanks equipped with baffles,” Journal of Fluids and Structures, 2014, Vol. 44,

pp.97-114.

125. S. M. Hasheminejad, and A. Ghaheri, “Exact solution for free vibration analysis of an eccentric

elliptical plate,” Archive of Applied Mechanics, 2014, Vol. 84, pp.543-552.

126. S. M. Hasheminejad, M. Vahedi, and A.H.D. Markazi, “Multi-objective robust active vibration

control of an arbitrary thick piezolaminated beam,” Mechanics of Advanced Materials and Structures,

2014, DOI: 10.1080/15376494.2014.882460.

127. S. M. Hasheminejad, and A. Ghaheri, “Exact solution for free vibration analysis of an eccentric

elliptical membrane,” Zeitschrift fur Angewandte Mathematik und Mechanik, 2014,

DOI: 10.1002/zamm.201300118.

128. S. M. Hasheminejad, and M. Tafani, “Coupled hydroelastic vibrations of an elliptical cylindrical

tank with an elastic bottom,” Journal of Hydrodynamics, 2014, Vol. 26, pp.264-276.

129. S. M. Hasheminejad, A.H. Rabiee, M. Jarrahi, and A.H.D. Markazi, “Active vortex-induced

vibration control of a circular cylinder at low Reynolds number using an adaptive fuzzy sliding mode

controller,” Journal of Fluids and Structures, 2014, DOI: 10.1016/j.jfluidstructs.2014.06.011.

130. S. M. Hasheminejad, and M. Gudarzi, “Active sound radiation control of a submerged

piezocomposite hollow sphere,” Journal of Intelligent Material Systems and Structures, 2014, DOI:

10.1177/1045389X14549863.

131. S. M. Hasheminejad, and B. Afsharmanesh, “Vibroacoustic response of an annular sandwich

electrorheological disc,” Journal of Low Frequency Noise, Vibration and Active Control, 2014, in

press.

132. S. M. Hasheminejad, and M. Jarrahi, “Numerical simulation of two dimensional vortexinduced

vibrations of an elliptic cylinder at low Reynolds numbers,” Computers and Fluids, 2014, in

press.

PROFESSIONAL EXPERIENCE

A. Positions Held

Professor, Dept. of Mech. Eng., Iran Univ. of Sci. & Tech., Tehran, 1993-present.

Lecturer, Dept. of Aerospace Eng., Research Div., Azad Univ., Poonak, Tehran, 1999- present.

Lecturer, Westminster Community College, Westminster, Colorado, USA (1992-1993)

Lecturer, Dept. of Mech. Eng., Colorado School of Mines, Golden, Colorado, USA (1992-1993)

Research Assistant, Dept. of Mech. Eng., U.C. Boulder, Colorado, 1988-1992.

Engineering Technician, General Instruments, Palo Alto, California, 1983-1985.

B. Applied Research Expertise

Have conducted (consulted in) various national research projects, including design and construction of

high-power underwater piezoelectric transducers, acoustic silencers & mufflers, sound absorbers

(acoustic foams) and insulators, vibration damping treatments, pneumatic mounts, broadcasting studios;

noise and vibration control in automobiles, airplanes, trains, buildings, residential and industrial

environments; development of standards, specifications and guidelines on environmental noise and

vibration control; design, construction, and testing of vent silencers for urban natural gas pressure

reduction station, and is currently involved in seismic/blast-proof design of underground gas pipelines.

C. Teaching Experience

Have instructed following course at various levels*:

1- Ph.D. level Advanced Engineering Mathematics (II); 20 semesters, IUST, Tehran, Iran.

2- Ph.D. level Acoustic Wave Propagation; 2 semesters, IUST, Tehran, Iran.

3- M.S. level Advanced Engineering Mathematics (I); 30 semesters, IUST, Tehran, Iran.

4- M.S. level Advanced Engineering Vibrations; 10 semesters, IUST, Tehran, Iran.

5- M.S. level Advanced Dynamics of Structures; 10 semesters, Azad Unv., Tehran, Iran.

6- B.S. level Dynamics; 15 semesters, IUST, Tehran, Iran.

7- B.S. level Engineering Vibrations; 30 semesters, IUST, Tehran, Iran.

8- B.S. level Linear Control Systems; 2 semesters , IUST, Tehran, Iran

9- B.S. level Dynamics; 2 semesters, Colorado School of Mines, Golden, Colorado, USA.

10- B.S. level Physics (I); 2 semesters, Westminster Community College, Colorado, USA.

D. Computer Programming and Systems

Proficient in computer and internet search-engine use.

Familiar with MP COMPLEX-FORTRAN, MATHEMATICA, MATLAB, MAPLE, IMSL, Netlib.

E. Additional Skills

Proficient in English technical writing and oral communication; Familiar with theory and applications of

finite and boundary element methods.

BACKGROUND

DOB: July 1962; married, two children; excellent health; athletic; references on request.

 


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