�ݺ�ߣshows by User: PraveenVaidya1

�ݺ�ߣshows by User: PraveenVaidya1 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: PraveenVaidya1 / Wed, 10 Apr 2024 08:47:50 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: PraveenVaidya1 Fundamentals of Superconductivity and its applications /slideshow/fundamentals-of-superconductivity-and-its-applications/267192435 superconductivity2022-240410084750-6a9a51c1
"Superconductivity" is a topic related to Physics, Chemistry and Engineering and Technology, anybody who would like to know about superconductor can read this article. This article explains about the fundamental's of superconductors, its various effects like Meissner effect, its theory and applications in MRI, Magneto encephalography, flying vehicle or levitating vehicles etc.]]>
"Superconductivity" is a topic related to Physics, Chemistry and Engineering and Technology, anybody who would like to know about superconductor can read this article. This article explains about the fundamental's of superconductors, its various effects like Meissner effect, its theory and applications in MRI, Magneto encephalography, flying vehicle or levitating vehicles etc.]]> Wed, 10 Apr 2024 08:47:50 GMT /slideshow/fundamentals-of-superconductivity-and-its-applications/267192435 PraveenVaidya1@slideshare.net(PraveenVaidya1) Fundamentals of Superconductivity and its applications PraveenVaidya1 "Superconductivity" is a topic related to Physics, Chemistry and Engineering and Technology, anybody who would like to know about superconductor can read this article. This article explains about the fundamental's of superconductors, its various effects like Meissner effect, its theory and applications in MRI, Magneto encephalography, flying vehicle or levitating vehicles etc. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/superconductivity2022-240410084750-6a9a51c1-thumbnail.jpg?width=120&height=120&fit=bounds" /> "Superconductivity" is a topic related to Physics, Chemistry and Engineering and Technology, anybody who would like to know about superconductor can read this article. This article explains about the fundamental's of superconductors, its various effects like Meissner effect, its theory and applications in MRI, Magneto encephalography, flying vehicle or levitating vehicles etc.

Fundamentals of Superconductivity and its applications from Praveen Vaidya

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0 torsinal pendulum.docx /slideshow/torsinal-pendulumdocx/263753153 torsinalpendulum-231122070741-5e23ac2a
Modulus of rigidity is an elastic constant. that measures the elastic behavior of a material when it is twisted or sheared. torsion pendulum consists of a weight of given shape hanged to the ceiling through a metallic wire, on twisting this load through an angle and left, it starts to oscillate, back and forth, The number of oscillations per unit time is measured. In this article the theory and experimental procedure of the measurement of modulus rigidity of the given metallic wire is presented by using the principle of torsional pendulum]]>
Modulus of rigidity is an elastic constant. that measures the elastic behavior of a material when it is twisted or sheared. torsion pendulum consists of a weight of given shape hanged to the ceiling through a metallic wire, on twisting this load through an angle and left, it starts to oscillate, back and forth, The number of oscillations per unit time is measured. In this article the theory and experimental procedure of the measurement of modulus rigidity of the given metallic wire is presented by using the principle of torsional pendulum]]> Wed, 22 Nov 2023 07:07:41 GMT /slideshow/torsinal-pendulumdocx/263753153 PraveenVaidya1@slideshare.net(PraveenVaidya1) torsinal pendulum.docx PraveenVaidya1 Modulus of rigidity is an elastic constant. that measures the elastic behavior of a material when it is twisted or sheared. torsion pendulum consists of a weight of given shape hanged to the ceiling through a metallic wire, on twisting this load through an angle and left, it starts to oscillate, back and forth, The number of oscillations per unit time is measured. In this article the theory and experimental procedure of the measurement of modulus rigidity of the given metallic wire is presented by using the principle of torsional pendulum <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/torsinalpendulum-231122070741-5e23ac2a-thumbnail.jpg?width=120&height=120&fit=bounds" /> Modulus of rigidity is an elastic constant. that measures the elastic behavior of a material when it is twisted or sheared. torsion pendulum consists of a weight of given shape hanged to the ceiling through a metallic wire, on twisting this load through an angle and left, it starts to oscillate, back and forth, The number of oscillations per unit time is measured. In this article the theory and experimental procedure of the measurement of modulus rigidity of the given metallic wire is presented by using the principle of torsional pendulum

torsinal pendulum.docx from Praveen Vaidya

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0 relativity.pdf /slideshow/relativitypdf/263179270 relativity-231108044921-c6820688
The study of motion of the object is an important section of the physics. The motion of a body is can be measured as absolute motion and relative motion. Practically any motion is measured is relative only, because one or the other way all the bodies are in motion. In this case we as observer can not measure the exact speed of the an object, because measured quantity of motion of other object is vary with the magnitude and direction of our motion. This can be studied with mathematical proof in this chapter. The Inertial frame and non inertial frame of reference, Special theory of relativity is covered here. ]]>
The study of motion of the object is an important section of the physics. The motion of a body is can be measured as absolute motion and relative motion. Practically any motion is measured is relative only, because one or the other way all the bodies are in motion. In this case we as observer can not measure the exact speed of the an object, because measured quantity of motion of other object is vary with the magnitude and direction of our motion. This can be studied with mathematical proof in this chapter. The Inertial frame and non inertial frame of reference, Special theory of relativity is covered here. ]]> Wed, 08 Nov 2023 04:49:20 GMT /slideshow/relativitypdf/263179270 PraveenVaidya1@slideshare.net(PraveenVaidya1) relativity.pdf PraveenVaidya1 The study of motion of the object is an important section of the physics. The motion of a body is can be measured as absolute motion and relative motion. Practically any motion is measured is relative only, because one or the other way all the bodies are in motion. In this case we as observer can not measure the exact speed of the an object, because measured quantity of motion of other object is vary with the magnitude and direction of our motion. This can be studied with mathematical proof in this chapter. The Inertial frame and non inertial frame of reference, Special theory of relativity is covered here. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/relativity-231108044921-c6820688-thumbnail.jpg?width=120&height=120&fit=bounds" /> The study of motion of the object is an important section of the physics. The motion of a body is can be measured as absolute motion and relative motion. Practically any motion is measured is relative only, because one or the other way all the bodies are in motion. In this case we as observer can not measure the exact speed of the an object, because measured quantity of motion of other object is vary with the magnitude and direction of our motion. This can be studied with mathematical proof in this chapter. The Inertial frame and non inertial frame of reference, Special theory of relativity is covered here.

relativity.pdf from Praveen Vaidya

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0 Optical fiber Experiment.docx /slideshow/optical-fiber-experimentdocx/257781346 opticalfiberexperiment-230511102124-736f9bfc
This experiment is for the Undergraduate students of Engineering and Science background. The optical fiber experiment explains the principle of working of optical fiber and theory to determine the angle of acceptance and numerical aperture. ]]>
This experiment is for the Undergraduate students of Engineering and Science background. The optical fiber experiment explains the principle of working of optical fiber and theory to determine the angle of acceptance and numerical aperture. ]]> Thu, 11 May 2023 10:21:24 GMT /slideshow/optical-fiber-experimentdocx/257781346 PraveenVaidya1@slideshare.net(PraveenVaidya1) Optical fiber Experiment.docx PraveenVaidya1 This experiment is for the Undergraduate students of Engineering and Science background. The optical fiber experiment explains the principle of working of optical fiber and theory to determine the angle of acceptance and numerical aperture. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/opticalfiberexperiment-230511102124-736f9bfc-thumbnail.jpg?width=120&height=120&fit=bounds" /> This experiment is for the Undergraduate students of Engineering and Science background. The optical fiber experiment explains the principle of working of optical fiber and theory to determine the angle of acceptance and numerical aperture.

Optical fiber Experiment.docx from Praveen Vaidya

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0 To detemine the wavelength of semiconductor laser /slideshow/to-detemine-the-wavelength-of-semiconductor-laser/250222034 laserexperiment-210917111531
The laser is part of almost all industrial sectors now. Laser is a coherent highly monochromatic concentrated beam of light. Right from the computer data reading to metal welding the laser is used. The PowerPoint presentation here explains the laser experiment to determine the wavelength of a semiconductor laser, my the method of Grazing incidence (diffraction over the graduations of metal scale). The aim is to study the diffraction of patterns of laser scattered from the graduations of metal scale and hence determine the wavelength. The experiment is part of the physics curriculum in Technological universities and other science colleges. ]]>
The laser is part of almost all industrial sectors now. Laser is a coherent highly monochromatic concentrated beam of light. Right from the computer data reading to metal welding the laser is used. The PowerPoint presentation here explains the laser experiment to determine the wavelength of a semiconductor laser, my the method of Grazing incidence (diffraction over the graduations of metal scale). The aim is to study the diffraction of patterns of laser scattered from the graduations of metal scale and hence determine the wavelength. The experiment is part of the physics curriculum in Technological universities and other science colleges. ]]> Fri, 17 Sep 2021 11:15:30 GMT /slideshow/to-detemine-the-wavelength-of-semiconductor-laser/250222034 PraveenVaidya1@slideshare.net(PraveenVaidya1) To detemine the wavelength of semiconductor laser PraveenVaidya1 The laser is part of almost all industrial sectors now. Laser is a coherent highly monochromatic concentrated beam of light. Right from the computer data reading to metal welding the laser is used. The PowerPoint presentation here explains the laser experiment to determine the wavelength of a semiconductor laser, my the method of Grazing incidence (diffraction over the graduations of metal scale). The aim is to study the diffraction of patterns of laser scattered from the graduations of metal scale and hence determine the wavelength. The experiment is part of the physics curriculum in Technological universities and other science colleges. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/laserexperiment-210917111531-thumbnail.jpg?width=120&height=120&fit=bounds" /> The laser is part of almost all industrial sectors now. Laser is a coherent highly monochromatic concentrated beam of light. Right from the computer data reading to metal welding the laser is used. The PowerPoint presentation here explains the laser experiment to determine the wavelength of a semiconductor laser, my the method of Grazing incidence (diffraction over the graduations of metal scale). The aim is to study the diffraction of patterns of laser scattered from the graduations of metal scale and hence determine the wavelength. The experiment is part of the physics curriculum in Technological universities and other science colleges.

To detemine the wavelength of semiconductor laser from Praveen Vaidya

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0 Semiconductor physics for undergraduates /slideshow/semiconductor-physics-for-undergraduates/250039348 semiconductorphysicsforundergraduates-210824094442
The above document throws light on the fundamentals of semiconducting materials that includes the formation of bonds, distribution of carriers, p-type and n-type semiconductors, position of Fermi energy in intrinsic and extrinsic semiconductors, direct and indirect bandgap semiconductors and their applications, carrier concentration, the electric conductivity of semiconductors and Hall effect theory and applications.]]>
The above document throws light on the fundamentals of semiconducting materials that includes the formation of bonds, distribution of carriers, p-type and n-type semiconductors, position of Fermi energy in intrinsic and extrinsic semiconductors, direct and indirect bandgap semiconductors and their applications, carrier concentration, the electric conductivity of semiconductors and Hall effect theory and applications.]]> Tue, 24 Aug 2021 09:44:41 GMT /slideshow/semiconductor-physics-for-undergraduates/250039348 PraveenVaidya1@slideshare.net(PraveenVaidya1) Semiconductor physics for undergraduates PraveenVaidya1 The above document throws light on the fundamentals of semiconducting materials that includes the formation of bonds, distribution of carriers, p-type and n-type semiconductors, position of Fermi energy in intrinsic and extrinsic semiconductors, direct and indirect bandgap semiconductors and their applications, carrier concentration, the electric conductivity of semiconductors and Hall effect theory and applications. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/semiconductorphysicsforundergraduates-210824094442-thumbnail.jpg?width=120&height=120&fit=bounds" /> The above document throws light on the fundamentals of semiconducting materials that includes the formation of bonds, distribution of carriers, p-type and n-type semiconductors, position of Fermi energy in intrinsic and extrinsic semiconductors, direct and indirect bandgap semiconductors and their applications, carrier concentration, the electric conductivity of semiconductors and Hall effect theory and applications.

Semiconductor physics for undergraduates from Praveen Vaidya

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0 Fundamentals of modern physics, the de-Broglie hypothesis /slideshow/fundamentals-of-modern-physics-the-debroglie-hypothesis/241384528 fundamentalsofmodernphysics-210115095016
The presentation uploaded here educates about the failure of classical physics to explain Blackbody radiation and the success of quantum theory to explain the Blackbody radiation spectrum and other phenomena, the de-Broglie hypothesis and its significance, nature of de-broglie waves and the representation. Numerical problems are given at the end.]]>
The presentation uploaded here educates about the failure of classical physics to explain Blackbody radiation and the success of quantum theory to explain the Blackbody radiation spectrum and other phenomena, the de-Broglie hypothesis and its significance, nature of de-broglie waves and the representation. Numerical problems are given at the end.]]> Fri, 15 Jan 2021 09:50:16 GMT /slideshow/fundamentals-of-modern-physics-the-debroglie-hypothesis/241384528 PraveenVaidya1@slideshare.net(PraveenVaidya1) Fundamentals of modern physics, the de-Broglie hypothesis PraveenVaidya1 The presentation uploaded here educates about the failure of classical physics to explain Blackbody radiation and the success of quantum theory to explain the Blackbody radiation spectrum and other phenomena, the de-Broglie hypothesis and its significance, nature of de-broglie waves and the representation. Numerical problems are given at the end. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/fundamentalsofmodernphysics-210115095016-thumbnail.jpg?width=120&height=120&fit=bounds" /> The presentation uploaded here educates about the failure of classical physics to explain Blackbody radiation and the success of quantum theory to explain the Blackbody radiation spectrum and other phenomena, the de-Broglie hypothesis and its significance, nature of de-broglie waves and the representation. Numerical problems are given at the end.

Fundamentals of modern physics, the de-Broglie hypothesis from Praveen Vaidya

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0 Young's modulus by single cantilever method /slideshow/youngs-modulus-by-single-cantilever-method/239116840 youngsmodulusbysinglecantilevermethod-201106104306
Young's modulus is a method to find the elasticity of a given solid material. The present article gives the explanation how to perform the experiment to determine the young's modulus by the use of material in the form of cantilever. The single cantilever method is used here.]]>
Young's modulus is a method to find the elasticity of a given solid material. The present article gives the explanation how to perform the experiment to determine the young's modulus by the use of material in the form of cantilever. The single cantilever method is used here.]]> Fri, 06 Nov 2020 10:43:06 GMT /slideshow/youngs-modulus-by-single-cantilever-method/239116840 PraveenVaidya1@slideshare.net(PraveenVaidya1) Young's modulus by single cantilever method PraveenVaidya1 Young's modulus is a method to find the elasticity of a given solid material. The present article gives the explanation how to perform the experiment to determine the young's modulus by the use of material in the form of cantilever. The single cantilever method is used here. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/youngsmodulusbysinglecantilevermethod-201106104306-thumbnail.jpg?width=120&height=120&fit=bounds" /> Young's modulus is a method to find the elasticity of a given solid material. The present article gives the explanation how to perform the experiment to determine the young's modulus by the use of material in the form of cantilever. The single cantilever method is used here.

Young's modulus by single cantilever method from Praveen Vaidya

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0 Fundamenals of magnetism and applications /slideshow/fundamenals-of-magnetism-and-applications/239047788 fundamenalsofmagnetism-201102063821
The present article gives the fundamental properties magnetism, different materials, properties of different magnetic materials like, dia,para and ferro magnetic materials. The notes also explain how magnetism appear in materials, type of magnets and brief applications of magnetic materials. The materials is best for undergraduate science and engineering students and any other people of interest in magnetism]]>
The present article gives the fundamental properties magnetism, different materials, properties of different magnetic materials like, dia,para and ferro magnetic materials. The notes also explain how magnetism appear in materials, type of magnets and brief applications of magnetic materials. The materials is best for undergraduate science and engineering students and any other people of interest in magnetism]]> Mon, 02 Nov 2020 06:38:21 GMT /slideshow/fundamenals-of-magnetism-and-applications/239047788 PraveenVaidya1@slideshare.net(PraveenVaidya1) Fundamenals of magnetism and applications PraveenVaidya1 The present article gives the fundamental properties magnetism, different materials, properties of different magnetic materials like, dia,para and ferro magnetic materials. The notes also explain how magnetism appear in materials, type of magnets and brief applications of magnetic materials. The materials is best for undergraduate science and engineering students and any other people of interest in magnetism <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/fundamenalsofmagnetism-201102063821-thumbnail.jpg?width=120&height=120&fit=bounds" /> The present article gives the fundamental properties magnetism, different materials, properties of different magnetic materials like, dia,para and ferro magnetic materials. The notes also explain how magnetism appear in materials, type of magnets and brief applications of magnetic materials. The materials is best for undergraduate science and engineering students and any other people of interest in magnetism

Fundamenals of magnetism and applications from Praveen Vaidya

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0 Introduction nanoscience /slideshow/introduction-nanoscience/238973181 introductionnanoscience-201026063206
The nanoscience is study of production of material of size as small as nanometer size, in practice a material should be of size between 1nm to 100nm at least one of three dimensions to be called a nanomaterial. The properties of material different from its bulk counterpart when it reduced its dimensions to nanoscale. Here some fundamentals about nanoscience, nanotechnology, properties and materials is discussed.]]>
The nanoscience is study of production of material of size as small as nanometer size, in practice a material should be of size between 1nm to 100nm at least one of three dimensions to be called a nanomaterial. The properties of material different from its bulk counterpart when it reduced its dimensions to nanoscale. Here some fundamentals about nanoscience, nanotechnology, properties and materials is discussed.]]> Mon, 26 Oct 2020 06:32:06 GMT /slideshow/introduction-nanoscience/238973181 PraveenVaidya1@slideshare.net(PraveenVaidya1) Introduction nanoscience PraveenVaidya1 The nanoscience is study of production of material of size as small as nanometer size, in practice a material should be of size between 1nm to 100nm at least one of three dimensions to be called a nanomaterial. The properties of material different from its bulk counterpart when it reduced its dimensions to nanoscale. Here some fundamentals about nanoscience, nanotechnology, properties and materials is discussed. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/introductionnanoscience-201026063206-thumbnail.jpg?width=120&height=120&fit=bounds" /> The nanoscience is study of production of material of size as small as nanometer size, in practice a material should be of size between 1nm to 100nm at least one of three dimensions to be called a nanomaterial. The properties of material different from its bulk counterpart when it reduced its dimensions to nanoscale. Here some fundamentals about nanoscience, nanotechnology, properties and materials is discussed.

Introduction nanoscience from Praveen Vaidya

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0 Zener diode experiment. /slideshow/zener-diode-experiment/215234431 zenerdiodeexperiment-200104084148
The Zener diode is fabricated in such a way that, its advantage is in its reverse bios. After a sufficient increase in reverse voltage across the junction, the minority carriers get sufficient kinetic energy due to the strong electric field. The high kinetic energy free electrons can collide strongly with the lattice ions so that they emit more free electrons, these liberated electrons also get high kinetic energy due to reverse applied electric field and they create more free electrons by collision cumulatively. This process may continue repeatedly and soon large free electron gas is created in the depletion layer, at which a small change in potential creates huge recombination and surge of carriers across the junction and hence large current through the circuit spontaneously and hence the entire diode will become conductive. Zener diode is an important electronic device mainly used as voltage regulator. The experiment explains the determination of zener voltage and resistance of diode.]]>
The Zener diode is fabricated in such a way that, its advantage is in its reverse bios. After a sufficient increase in reverse voltage across the junction, the minority carriers get sufficient kinetic energy due to the strong electric field. The high kinetic energy free electrons can collide strongly with the lattice ions so that they emit more free electrons, these liberated electrons also get high kinetic energy due to reverse applied electric field and they create more free electrons by collision cumulatively. This process may continue repeatedly and soon large free electron gas is created in the depletion layer, at which a small change in potential creates huge recombination and surge of carriers across the junction and hence large current through the circuit spontaneously and hence the entire diode will become conductive. Zener diode is an important electronic device mainly used as voltage regulator. The experiment explains the determination of zener voltage and resistance of diode.]]> Sat, 04 Jan 2020 08:41:48 GMT /slideshow/zener-diode-experiment/215234431 PraveenVaidya1@slideshare.net(PraveenVaidya1) Zener diode experiment. PraveenVaidya1 The Zener diode is fabricated in such a way that, its advantage is in its reverse bios. After a sufficient increase in reverse voltage across the junction, the minority carriers get sufficient kinetic energy due to the strong electric field. The high kinetic energy free electrons can collide strongly with the lattice ions so that they emit more free electrons, these liberated electrons also get high kinetic energy due to reverse applied electric field and they create more free electrons by collision cumulatively. This process may continue repeatedly and soon large free electron gas is created in the depletion layer, at which a small change in potential creates huge recombination and surge of carriers across the junction and hence large current through the circuit spontaneously and hence the entire diode will become conductive. Zener diode is an important electronic device mainly used as voltage regulator. The experiment explains the determination of zener voltage and resistance of diode. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/zenerdiodeexperiment-200104084148-thumbnail.jpg?width=120&height=120&fit=bounds" /> The Zener diode is fabricated in such a way that, its advantage is in its reverse bios. After a sufficient increase in reverse voltage across the junction, the minority carriers get sufficient kinetic energy due to the strong electric field. The high kinetic energy free electrons can collide strongly with the lattice ions so that they emit more free electrons, these liberated electrons also get high kinetic energy due to reverse applied electric field and they create more free electrons by collision cumulatively. This process may continue repeatedly and soon large free electron gas is created in the depletion layer, at which a small change in potential creates huge recombination and surge of carriers across the junction and hence large current through the circuit spontaneously and hence the entire diode will become conductive. Zener diode is an important electronic device mainly used as voltage regulator. The experiment explains the determination of zener voltage and resistance of diode.

Zener diode experiment. from Praveen Vaidya

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0 Maxwell's equations and their derivations. /slideshow/maxwells-equations-and-their-derivations/158273820 maxwellsequations-190727064525
Being the partial differential equations along with the Lorentz law the Maxwell's equation laid the foundation for classical electromagnetism, classical optics, and electric circuits. The equations provide a mathematical model for electric, optical, and radio technologies, such as power generation, electric motors, wireless communication, lenses, radar etc. Maxwell's equations describe how electric and magnetic fields are generated by charges, currents, and changes of the fields.[note 1] One important consequence of the equations is that they demonstrate how fluctuating electric and magnetic fields propagate at a constant speed (c) in the vacuum, the "speed of light". Known as electromagnetic radiation, these waves may occur at various wavelengths to produce a spectrum from radio waves to γ-rays. The equations are named after the physicist and mathematician James Clerk Maxwell, who between 1861 and 1862 published an early form of the equations that included the Lorentz force law. He also first used the equations to propose that light is an electromagnetic phenomenon.]]>
Being the partial differential equations along with the Lorentz law the Maxwell's equation laid the foundation for classical electromagnetism, classical optics, and electric circuits. The equations provide a mathematical model for electric, optical, and radio technologies, such as power generation, electric motors, wireless communication, lenses, radar etc. Maxwell's equations describe how electric and magnetic fields are generated by charges, currents, and changes of the fields.[note 1] One important consequence of the equations is that they demonstrate how fluctuating electric and magnetic fields propagate at a constant speed (c) in the vacuum, the "speed of light". Known as electromagnetic radiation, these waves may occur at various wavelengths to produce a spectrum from radio waves to γ-rays. The equations are named after the physicist and mathematician James Clerk Maxwell, who between 1861 and 1862 published an early form of the equations that included the Lorentz force law. He also first used the equations to propose that light is an electromagnetic phenomenon.]]> Sat, 27 Jul 2019 06:45:25 GMT /slideshow/maxwells-equations-and-their-derivations/158273820 PraveenVaidya1@slideshare.net(PraveenVaidya1) Maxwell's equations and their derivations. PraveenVaidya1 Being the partial differential equations along with the Lorentz law the Maxwell's equation laid the foundation for classical electromagnetism, classical optics, and electric circuits. The equations provide a mathematical model for electric, optical, and radio technologies, such as power generation, electric motors, wireless communication, lenses, radar etc. Maxwell's equations describe how electric and magnetic fields are generated by charges, currents, and changes of the fields.[note 1] One important consequence of the equations is that they demonstrate how fluctuating electric and magnetic fields propagate at a constant speed (c) in the vacuum, the "speed of light". Known as electromagnetic radiation, these waves may occur at various wavelengths to produce a spectrum from radio waves to γ-rays. The equations are named after the physicist and mathematician James Clerk Maxwell, who between 1861 and 1862 published an early form of the equations that included the Lorentz force law. He also first used the equations to propose that light is an electromagnetic phenomenon. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/maxwellsequations-190727064525-thumbnail.jpg?width=120&height=120&fit=bounds" /> Being the partial differential equations along with the Lorentz law the Maxwell's equation laid the foundation for classical electromagnetism, classical optics, and electric circuits. The equations provide a mathematical model for electric, optical, and radio technologies, such as power generation, electric motors, wireless communication, lenses, radar etc. Maxwell's equations describe how electric and magnetic fields are generated by charges, currents, and changes of the fields.[note 1] One important consequence of the equations is that they demonstrate how fluctuating electric and magnetic fields propagate at a constant speed (c) in the vacuum, the "speed of light". Known as electromagnetic radiation, these waves may occur at various wavelengths to produce a spectrum from radio waves to γ-rays. The equations are named after the physicist and mathematician James Clerk Maxwell, who between 1861 and 1862 published an early form of the equations that included the Lorentz force law. He also first used the equations to propose that light is an electromagnetic phenomenon.

Maxwell's equations and their derivations. from Praveen Vaidya

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0 Series parallel resonance circuit /slideshow/series-parallel-resonance-circuit/140301837 seriesparallel-190410105607
This is the experiment for undergraduate science and engineering students in the subjects of Physics, Applied Physics, Basic electronics etc. The experiment is explained in detail so that the students and faculty member can get the better knowledge of the experiment.]]>
This is the experiment for undergraduate science and engineering students in the subjects of Physics, Applied Physics, Basic electronics etc. The experiment is explained in detail so that the students and faculty member can get the better knowledge of the experiment.]]> Wed, 10 Apr 2019 10:56:07 GMT /slideshow/series-parallel-resonance-circuit/140301837 PraveenVaidya1@slideshare.net(PraveenVaidya1) Series parallel resonance circuit PraveenVaidya1 This is the experiment for undergraduate science and engineering students in the subjects of Physics, Applied Physics, Basic electronics etc. The experiment is explained in detail so that the students and faculty member can get the better knowledge of the experiment. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/seriesparallel-190410105607-thumbnail.jpg?width=120&height=120&fit=bounds" /> This is the experiment for undergraduate science and engineering students in the subjects of Physics, Applied Physics, Basic electronics etc. The experiment is explained in detail so that the students and faculty member can get the better knowledge of the experiment.

Series parallel resonance circuit from Praveen Vaidya

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0 Quantum mechanics for Engineering Students /slideshow/quantum-mechanics-for-engineering-students/129661405 quantummechanics-190129045157
The Quantum mechanics study material gives insight into the fundamentals of the modern theory of physics related to Heisenberg uncertainty principle, wavefunction, concepts of potential well etc.]]>
The Quantum mechanics study material gives insight into the fundamentals of the modern theory of physics related to Heisenberg uncertainty principle, wavefunction, concepts of potential well etc.]]> Tue, 29 Jan 2019 04:51:57 GMT /slideshow/quantum-mechanics-for-engineering-students/129661405 PraveenVaidya1@slideshare.net(PraveenVaidya1) Quantum mechanics for Engineering Students PraveenVaidya1 The Quantum mechanics study material gives insight into the fundamentals of the modern theory of physics related to Heisenberg uncertainty principle, wavefunction, concepts of potential well etc. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/quantummechanics-190129045157-thumbnail.jpg?width=120&height=120&fit=bounds" /> The Quantum mechanics study material gives insight into the fundamentals of the modern theory of physics related to Heisenberg uncertainty principle, wavefunction, concepts of potential well etc.

Quantum mechanics for Engineering Students from Praveen Vaidya

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0 Introduction to Elasticity of materials /slideshow/introduction-to-elasticity-of-materials/124472463 elasticity2018odd-181130090527
The PPT gives insight into the fundamentals of elastic properties materials. Hook's law, stress strain graph, torsional pendulum, bending of beam etc.]]>
The PPT gives insight into the fundamentals of elastic properties materials. Hook's law, stress strain graph, torsional pendulum, bending of beam etc.]]> Fri, 30 Nov 2018 09:05:27 GMT /slideshow/introduction-to-elasticity-of-materials/124472463 PraveenVaidya1@slideshare.net(PraveenVaidya1) Introduction to Elasticity of materials PraveenVaidya1 The PPT gives insight into the fundamentals of elastic properties materials. Hook's law, stress strain graph, torsional pendulum, bending of beam etc. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/elasticity2018odd-181130090527-thumbnail.jpg?width=120&height=120&fit=bounds" /> The PPT gives insight into the fundamentals of elastic properties materials. Hook's law, stress strain graph, torsional pendulum, bending of beam etc.

Introduction to Elasticity of materials from Praveen Vaidya

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0 Optical fibers Theory and applications /PraveenVaidya1/optical-fibers-theory-and-applications opticalfibersnew-181012073450
The chapter gives knowledge about the fundamentals, theory and applications of optical fiber for the first year Engineering level students. The material is most suitable for the students of first year B.E. and B.Tech.]]>
The chapter gives knowledge about the fundamentals, theory and applications of optical fiber for the first year Engineering level students. The material is most suitable for the students of first year B.E. and B.Tech.]]> Fri, 12 Oct 2018 07:34:50 GMT /PraveenVaidya1/optical-fibers-theory-and-applications PraveenVaidya1@slideshare.net(PraveenVaidya1) Optical fibers Theory and applications PraveenVaidya1 The chapter gives knowledge about the fundamentals, theory and applications of optical fiber for the first year Engineering level students. The material is most suitable for the students of first year B.E. and B.Tech. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/opticalfibersnew-181012073450-thumbnail.jpg?width=120&height=120&fit=bounds" /> The chapter gives knowledge about the fundamentals, theory and applications of optical fiber for the first year Engineering level students. The material is most suitable for the students of first year B.E. and B.Tech.

Optical fibers Theory and applications from Praveen Vaidya

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0 Fundamentals of modern physics /slideshow/fundamentals-of-modern-physics/111686394 modernphysics-180827040839
The chapter contains fundamentals of Modern physics, the Quantumtheory explanation of Black body radiation photoelectric effect and Compton effect, and the beginning of the de-Broglie hypothesis, wave-like properties of matter, and its proof explained in detail. It is highly useful for first-year B.Tech and BE students.]]>
The chapter contains fundamentals of Modern physics, the Quantumtheory explanation of Black body radiation photoelectric effect and Compton effect, and the beginning of the de-Broglie hypothesis, wave-like properties of matter, and its proof explained in detail. It is highly useful for first-year B.Tech and BE students.]]> Mon, 27 Aug 2018 04:08:39 GMT /slideshow/fundamentals-of-modern-physics/111686394 PraveenVaidya1@slideshare.net(PraveenVaidya1) Fundamentals of modern physics PraveenVaidya1 The chapter contains fundamentals of Modern physics, the Quantumtheory explanation of Black body radiation photoelectric effect and Compton effect, and the beginning of the de-Broglie hypothesis, wave-like properties of matter, and its proof explained in detail. It is highly useful for first-year B.Tech and BE students. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/modernphysics-180827040839-thumbnail.jpg?width=120&height=120&fit=bounds" /> The chapter contains fundamentals of Modern physics, the Quantumtheory explanation of Black body radiation photoelectric effect and Compton effect, and the beginning of the de-Broglie hypothesis, wave-like properties of matter, and its proof explained in detail. It is highly useful for first-year B.Tech and BE students.

Fundamentals of modern physics from Praveen Vaidya

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0 fundamentals of optical fiber /slideshow/optical-fiber-basics-109054486/109054486 opticalfiberbasics-180808091928
The optical fibers are the hair thin fibers made of ultra transparent glass or plastic material. The optical fiber flexible and it is used to transmit the light. The presentation here mainly focused on the brief explanation of principle, theory, characteristics, losses in fibers and applications.]]>
The optical fibers are the hair thin fibers made of ultra transparent glass or plastic material. The optical fiber flexible and it is used to transmit the light. The presentation here mainly focused on the brief explanation of principle, theory, characteristics, losses in fibers and applications.]]> Wed, 08 Aug 2018 09:19:28 GMT /slideshow/optical-fiber-basics-109054486/109054486 PraveenVaidya1@slideshare.net(PraveenVaidya1) fundamentals of optical fiber PraveenVaidya1 The optical fibers are the hair thin fibers made of ultra transparent glass or plastic material. The optical fiber flexible and it is used to transmit the light. The presentation here mainly focused on the brief explanation of principle, theory, characteristics, losses in fibers and applications. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/opticalfiberbasics-180808091928-thumbnail.jpg?width=120&height=120&fit=bounds" /> The optical fibers are the hair thin fibers made of ultra transparent glass or plastic material. The optical fiber flexible and it is used to transmit the light. The presentation here mainly focused on the brief explanation of principle, theory, characteristics, losses in fibers and applications.

fundamentals of optical fiber from Praveen Vaidya

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0 degradation of pollution and photocatalysis /slideshow/photocatalysis-107581331/107581331 photofinalconference-180726085926
The presentation deals with the use of conduction of photocatalytic reaction using the transition metal doped transparent semiconducting thinfilms. The precursor to film is prepared by the SILAR method, which is a chemical method.]]>
The presentation deals with the use of conduction of photocatalytic reaction using the transition metal doped transparent semiconducting thinfilms. The precursor to film is prepared by the SILAR method, which is a chemical method.]]> Thu, 26 Jul 2018 08:59:26 GMT /slideshow/photocatalysis-107581331/107581331 PraveenVaidya1@slideshare.net(PraveenVaidya1) degradation of pollution and photocatalysis PraveenVaidya1 The presentation deals with the use of conduction of photocatalytic reaction using the transition metal doped transparent semiconducting thinfilms. The precursor to film is prepared by the SILAR method, which is a chemical method. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/photofinalconference-180726085926-thumbnail.jpg?width=120&height=120&fit=bounds" /> The presentation deals with the use of conduction of photocatalytic reaction using the transition metal doped transparent semiconducting thinfilms. The precursor to film is prepared by the SILAR method, which is a chemical method.

degradation of pollution and photocatalysis from Praveen Vaidya

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0 Energy bands and electrical properties of metals new /slideshow/energy-bands-and-electrical-properties-of-metals-new/102481521 energybandsandelectricalpropertiesofmetalsnew-180615045915
The chapter gives brief knowledge about formation of bands in solids. What are free electrons how they contribute for conductivity in conductors, but can be extended to semiconductors also.]]>
The chapter gives brief knowledge about formation of bands in solids. What are free electrons how they contribute for conductivity in conductors, but can be extended to semiconductors also.]]> Fri, 15 Jun 2018 04:59:15 GMT /slideshow/energy-bands-and-electrical-properties-of-metals-new/102481521 PraveenVaidya1@slideshare.net(PraveenVaidya1) Energy bands and electrical properties of metals new PraveenVaidya1 The chapter gives brief knowledge about formation of bands in solids. What are free electrons how they contribute for conductivity in conductors, but can be extended to semiconductors also. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/energybandsandelectricalpropertiesofmetalsnew-180615045915-thumbnail.jpg?width=120&height=120&fit=bounds" /> The chapter gives brief knowledge about formation of bands in solids. What are free electrons how they contribute for conductivity in conductors, but can be extended to semiconductors also.

Energy bands and electrical properties of metals new from Praveen Vaidya

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0 https://cdn.slidesharecdn.com/profile-photo-PraveenVaidya1-48x48.jpg?cb=1726032672 A HOD of science at RNS Polytechnic, Incharge Principal at Vishwamangal Pre-University college, BOS member of HRM subject at The National College Bangalore In addition to 19 years of teaching Physics for all categories PUC, Diploma, B.Sc. and B.E. At present teaching at SDMCET, Dharwad. Specialties: Conducting Quiz compititions Arranging workshops etc. https://cdn.slidesharecdn.com/ss_thumbnails/superconductivity2022-240410084750-6a9a51c1-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/fundamentals-of-superconductivity-and-its-applications/267192435 Fundamentals of Superc... https://cdn.slidesharecdn.com/ss_thumbnails/torsinalpendulum-231122070741-5e23ac2a-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/torsinal-pendulumdocx/263753153 torsinal pendulum.docx https://cdn.slidesharecdn.com/ss_thumbnails/relativity-231108044921-c6820688-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/relativitypdf/263179270 relativity.pdf