{"id":170109,"date":"2024-04-02T11:46:51","date_gmt":"2024-04-02T06:16:51","guid":{"rendered":"https:\/\/www.aplustopper.com\/?p=170109"},"modified":"2024-04-02T11:50:49","modified_gmt":"2024-04-02T06:20:49","slug":"ph3255-physics-for-instrumentation-engineering-syllabus","status":"publish","type":"post","link":"https:\/\/www.aplustopper.com\/ph3255-physics-for-instrumentation-engineering-syllabus\/","title":{"rendered":"PH3255 – Physics For Instrumentation Engineering Syllabus Regulation 2021 Anna University"},"content":{"rendered":"
Physics For Instrumentation Engineering Subject from the Semester II B.E Electrical and Instrumentation Of Anna University syllabus. In this article, we aim to provide the unit-wise topics in a detailed manner.<\/p>\n
We added the required textbooks and references from the faculty. It will assist you in making preparation strategies for the examination. Having a grip on every topic of the unit you can able to finish the syllabus before everyone else. Hope this information is useful. If you have any queries about the syllabus of PH3255 – Physics For Instrumentation Engineering<\/a>. Comment below on this article.<\/p>\n If you want to know more about the B.E Electrical and Instrumentation syllabus connected to an affiliated institution\u2019s four-year undergraduate degree program. We provide you with a detailed Year-wise, semester-wise, and Subject-wise syllabus in the following link B.E Electrical and Instrumentation\u00a0Syllabus Regulation 2021 Anna University.<\/a><\/p>\n Aim Of Concept:<\/strong><\/p>\n PH3255 – Physics For Instrumentation Engineering Syllabus<\/strong><\/p>\n Unit I:<\/strong> Electricity And Magnetism<\/p>\n Coulomb\u2019s law, electric field intensity, electric flux density, Gauss\u2019 law, divergence, electric field and potential due to point, line, plane, and spherical charge distributions, effect of the dielectric medium, capacitance of simple configurations, Biot-Savart\u2019s law, Ampere\u2019s law, curl, Faraday\u2019s law, Lorentz force, Inductance, Magneto motive force, reluctance, magnetic circuits, self and mutual inductance of simple configurations.<\/p>\n Unit II:<\/strong> Electrical And Magnetic Properties Of Materials<\/p>\n Classical free electron theory – Expression for electrical conductivity \u2013 Thermal conductivity, expression Quantum free electron theory: Tunneling \u2013 degenerate states \u2013 Fermi- Dirac statistics \u2013 Density of energy states \u2013 Electron in periodic potential \u2013 Energy bands in solids \u2013 tight binding approximation Electron effective mass \u2013 concept of hole. Magnetic materials: Dia, para, and ferromagnetic effects \u2013 paramagnetism in the conduction electrons in metals \u2013 exchange interaction and ferromagnetism \u2013 quantum interference devices \u2013 GMR devices.<\/p>\n Unit III:<\/strong> Semiconductors And Transport Physics<\/p>\n Intrinsic Semiconductors \u2013 Energy band diagram \u2013 direct and indirect band gap semiconductors \u2013 Carrier concentration in intrinsic semiconductors \u2013 extrinsic semiconductors – Carrier concentration in N-type & P-type semiconductors \u2013 Variation of carrier concentration with temperature \u2013 Carrier transport in Semiconductors: Drift, mobility and diffusion \u2013 Hall effect and devices \u2013 Ohmic contacts \u2013 Schottky diode.<\/p>\n Unit IV:<\/strong> Optical Properties Of Materials<\/p>\n Classification of optical materials \u2013 Optical processes in semiconductors: optical absorption and emission, charge injection and recombination, optical absorption, loss and gain. Optical processes in quantum wells \u2013 Optoelectronic devices: light detectors and solar cells \u2013 light emitting diode \u2013 laser diode – optical processes in organic semiconductor devices \u2013excitonic state \u2013 Electro-optics and nonlinear optics: Modulators and switching devices \u2013 plasmonics.<\/p>\n <\/p>\n Unit V:<\/strong> Nanodevices And Quantum Computing<\/p>\n Introduction – quantum confinement \u2013 quantum structures: quantum wells, wires and dots \u2013\u2013 band gap of nanomaterials. Tunneling \u2013 Single electron phenomena: Coulomb blockade – resonant-tunneling diode \u2013 single electron transistor \u2013 quantum cellular automata – Quantum system for information processing – quantum states \u2013 classical bits \u2013 quantum bits or qubits \u2013CNOT gate – multiple qubits \u2013 Bloch sphere \u2013 quantum gates \u2013 advantage of quantum computing over classical computing.<\/p>\n Text Books:<\/strong><\/p>\n References:<\/strong><\/p>\n Related Posts On Semester \u2013 II:<\/strong><\/p>\n\n
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