Rajiv Gandhi Proudyogiki Vishwavidyalaya, Bhopal
Branch- Common to All Discipline
BT301 | Energy & Environmental Engineering | 3L-1T-0P | 4 Credits |
The objective of this Course is to provide an introduction to energy systems and renewable energy resources, with a scientific examination of the energy field and an emphasis on alternative energy sources and their technology and application.
Module 1: Introduction to Energy Science:
Introduction to energy systems and resources; Introduction to Energy, sustainability & the environment; Overview of energy systems, sources, transformations, efficiency, and storage; Fossil fuels (coal, oil, oil-bearing shale and sands, coal gasification) - past, present & future, Remedies & alternatives for fossil fuels - biomass, wind, solar, nuclear, wave, tidal and hydrogen; Sustainability and environmental trade-offs of different energy systems; possibilities for energy storage or regeneration (Ex. Pumped storage hydro power projects, superconductor- based energy storages, high efficiency batteries)
Module2: Ecosystems
Concept of an ecosystem; Structure and function of an ecosystem; Producers, consumers and decomposers; Energy flow in the ecosystem; Ecological succession; Food chains, food webs and ecological pyramids; Introduction, types, characteristic features, structure and function of the following ecosystem (a.)Forest ecosystem
(b) Grassland ecosystem (c) Desert ecosystem (d) Aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries)
Module 3: Biodiversity and its conservation
Introduction – Definition: genetic, species and ecosystem diversity; Bio- geographical classification of India; Value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values; Biodiversity at global, National and local levels; India as a mega-diversity nation; Hot-sports of biodiversity; Threats to biodiversity: habitat loss, poaching of wildlife, man- wildlife conflicts; Endangered and endemic species of India; Conservation of biodiversity: In-situ and Ex-situ conservation of biodiversity.
Module 4: Environmental Pollution
Definition, Cause, effects and control measures of Air pollution, Water pollution, Soil pollution, Marine pollution, Noise pollution, Thermal pollution, Nuclear hazards; Solid waste Management: Causes, effects and control measures of urban and industrial wastes; Role of an individual in prevention of pollution; Pollution case studies; Disaster management: floods, earthquake, cyclone and landslides.
Module 5: Social Issues and the Environment
From Unsustainable to Sustainable development; Urban problems related to energy; Water conservation, rain water harvesting, watershed management; Resettlement and rehabilitation of people; its problems and concerns. Case Studies
Environmental ethics: Issues and possible solutions. Climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and holocaust. Case Studies Wasteland reclamation; Consumerism and waste products; Environment Protection Act; Air (Prevention and Control of Pollution) Act; Water (Prevention and control of Pollution) Act; Wildlife Protection Act; Forest Conservation Act; Issues involved in enforcement of environmental legislation; Public awareness.
Module 6: Field work
Visit to a local area to document environmental assets- river/forest/grassland/hill/mountain
Visit to a local polluted site-Urban/Rural/Industrial/Agricultural
Study of common plants, insects, birds.
Study of simple ecosystems-pond, river, hill slopes, etc.
Brunner R.C., 1989, Hazardous Waste Incineration, McGraw Hill Inc.
Clark R.S., Marine Pollution, Clanderson Press Oxford (TB).
Cunningham, W.P. Cooper, T.H. Gorhani, E & Hepworth, M.T. 2001, Environmental Encyclopedia, Jaico Publ. House, Mumabai,
De A.K., Environmental Chemistry, Wiley Eastern Ltd.
Trivedi R.K., Handbook of Environmental Laws, Rules Guidelines, Compliances and Standards’, Vol I and II, Enviro Media (R)
Boyle, Godfrey, Bob Everett, and Janet Ramage (Eds.) (2004), Energy Systems and Sustainability: Power for a Sustainable Future. Oxford University Press.
Schaeffer, John (2007), Real Goods Solar Living Sourcebook: The Complete Guide to Renewable Energy Technologies and Sustainable Living, Gaiam
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To understand basics of Human Anatomy and Physiology.
To study the organs and systems involved in body functions.
To apply this knowledge into biomedical engineering field.
Describe and explain specific parts and key terms applied in anatomy and physiology
Describe important physiological mechanisms involved in cell, tissue, and organ
Understand organization and functions of each organs and systems in human body and understanding of biology and physiology the capability to apply advanced mathematics science, and engineering to solve problems at the interface of engineering and biology.
Structure of Neurons, Synapse and neurotransmitters, Central and Peripheral nervous system, various parts of nervous system; Brain: Parts and functions; Spinal cord, CSF, Ventricles of the brain, Autonomic nervous system, Reflex action.
Eye: Anatomy of Eye & Physiology of Vision, Ear: Structure of Ear & Physiology of Hearing, Nose: Sense of Smell, Tongue: Sense of Taste.
Brief idea of location of endocrine glands, Hormones of pituitary, pineal, thyroid, parathyroid, pancreas, adrenal glands and gonads, feedback mechanism. Mechanism of hormone action effects of hypo secretion and hyper secretion of various hormones of the above mentioned glands.
Anatomy of digestive system, movement of gastrointestinal tract, mastication, deglutination, physiological activities in mouth, pharynx, esophagus, stomach, pancreas, liver, gall bladder, small and large Intestine, Digestion and absorption.
Anatomy of Urinary System and Structure of Nephron, Physiology of urine formation, physiology of micturition, Concentration and Dilution of urine, Composition of Urine. Principles of Heamodylysis
Anatomy and Physiology in Health and Illness by Ross and Wilson
Human Anatomy and Physiology by Dr. Padma Sanghani
Text book of Medical Physiology by Guyton and Hall
Human Physiology and Anatomy by Fox Staurt Ira
Human Anatomy (Volume 1,2,3) by B.D.Chaurasia
To record electrical activity of heart of a subject by Electrocardiogram (Limb leads)
To record electrical activity of heart of a subject by Electrocardiogram (Chest leads)
To record brain electrical activity of a subject by Electroencephalogram (EEG).
To record muscles electrical activity of a subject by Electromyogram (EMG).
Operation and testing of Stethoscope
To Record heart sound of a subject by Phonocardiogram (PCG).
To find blood oxygen saturation level using finger Plythesmograph.
To measure blood Pressure with Indirect Blood pressure measuring equipment.
Operation and testing of Doppler shift Blood Pressure measurement
Operation and testing of Patient monitor.
.
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To introduce the basic concepts related to the operation of electrical & electronic measuring instruments.
To understand operational and application aspects of CRO (normal and storage).
To analyze and apply various AC bridges for the measurements of various physical quantities minimizing errors by following proper precautions.
To study the principles behind various transducers and their applications in the measurement of various parameters in electrical and mechanical engineering fields.
Upon successful completion of this course, the student will be able to:
Understand the basic concepts of electrical units, measurement errors and accuracy.
Measure different physical parameters using different transducers.
Gain experience in interpreting technical specifications and selecting sensors and transducers for a given application.
Apply the principles and practice for instrument design and develop for real world problems.
Measurements & Errors: Significance of measurements, methods of measurements: Direct & indirect methods, Mechanical, Electrical, Electronic Instruments, Classification of instruments, Deflection & null type, Characteristics of instruments: accuracy, precision, drift, span & range, Significant Figures, Static Sensitivity, Linearity, hysteresis, Threshold, Dead zone, Resolution, Loading effect etc.
Error & its types: Gross systematic error: Instrumental Error, Environmental error, observational error. Random error: Arithmetic mean, Range, deviation, Average deviation, Standard deviation, variance etc.
CRO & Measurements: Basic CRO Circuit, Dual trace Oscilloscope, Dual beam Oscilloscope, Sampling Oscilloscope, Analog Storage Oscilloscope, Digital Storage Oscilloscope.
Measurement with CRO: Frequency, Voltage, Current, Phase, Dielectric, Frequency ratio etc.
Bridges: General equation for bridge balance, Measurement of inductance, Capacitance and Q of the coil, Capacitance Maxwell’s, Wiens, Schering Bridge, Wagner Earth Tester.
Signal generator, Function generator, sweep frequency generator, Pulse and square wave generator, Wave Analyzers, Harmonic Distortion Analyzer, Spectrum Analyzer, Heterodyne frequency meter, frequency counter, measurement errors, automatic and computing counter, Digital voltmeter, Ramp type DVM, Integrating DVM, successive approximation DVM.
Transducer: Electrical transducers, classification of transducers, resistive transducer, resistance thermometers, thermistors, thermocouples, Inductive transducer, LVDT, Capacitive, piezoelectric, hall effect transducers. Measurement of non Electrical quantity: Displacement, strain, flow measurements, Rota meter, Venturi meter, Bourdon tube pressure transducer, temperature.
Sensors: Gas Sensor, NBA agent, Microbial sensor, electro analytical sensor, Enzyme based sensor-glucose sensor, Electronic nose –halitosis, breath analysis. Advances in sensor technology: lab –on –a chip, smart sensor, MEMS and Nano sensor. Radiation sensor , Thermal radiation sensor.
Electrical Electronics Measurement & Measuring Instrumentation by A.K Shawney.
Electronics & Instrumentation Measurement by J.B Gupta.
Instrumentation & Measurement by Helfrick Cooper, PHI India
Electronics Instrumentation, H.S. Kalasi, TMH India
Biomedical senses & Measurement by Wane, Pind, Liu, Sprinper.
Measurement, Instrumentation, and Sensors Handbook, Second Edition: Two- Volume Set John G. Webster, Halit Eren, CRC Press
Measurement System by Doebelin, Tata McGraw-Hill Education
Biosensors: Theory and Applications, Donald G. Buerk, by CRC Press
Fundamentals of Instrumentation 2nd Edition by NJATC, Cengage Learning; 2 edition
To measure the Amplitude, Frequency and Phase difference using Analog Dual Trace Oscilloscope.
To measure the some parameters using Digital Storage Oscilloscope (DSO).
To measure the unknown value of Inductance and Resistance using Maxwell Inductance Bridge.
To measure the unknown value of Capacitance using Schering Bridge.
To measure the unknown value of Capacitance and Frequency using Wien’s Bridge.
To measure the displacement using Light dependent Register (LDR).
To measure the temperature using Resistance Temperature Detector (RTD).
To Study the characteristics of the Linear Variable Differential Transformer (LVDT).
To measure the Intensity of Light on different distance by using Photo Transducer.
To measure Displacement using Capacitor pickup
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester BM303 Electronic Devices and Circuits
To understand the physics of semiconductor electronic devices, the characteristics their equivalent models and the characteristics and operation of the diodes.
To understand the internal working of the regulated power supply.
To understand the concept of biasing in BJT and JFET so as to able to analyze advanced electronic circuits.
After completing this course, the student will be able to:
Get clear understanding of internal physical behavior of PN junction Diode.
Understand the breakdown mechanisms in semiconductors so as to construct a Zener voltage regulator used in regulated power supplies.
Analyze various rectifiers and filter circuits used in regulated power supplies.
Understand the construction, operation and characteristics of Bipolar Junction Transistor, which can be used in the design of amplifiers.
Understand the construction, operation and characteristics of JFET and MOSFET, which can be used in the design of amplifiers.
Understand the need and requirements of biasing a transistor so that to avoid the failure of electronic circuits due to thermal effects
Physical structure and operation modes, Active region operation of transistor, D.C. analysis of transistor circuits, Transistor as an amplifier, Biasing the BJT: fixed bias, emitter feedback bias, collector feedback bias and, voltage divider bias. Basic BJT amplifier configuration: common emitter, common base and common collector amplifiers. Transistor as a switch: cut-off and saturation modes. High frequency model of BJT amplifier.
Junction Field-Effect Transistor (JFET) - Construction, Operation and Biasing, Depletion-type MOSFET, Enhancement-type MOSFET: structure and physical operation, current-voltage characteristics. D.C. operation of MOSFET circuits, MOSFET as an amplifier, Biasing in MOSFET amplifiers, Basic MOSFET amplifier configuration: common source, common gate and common drain types. High frequency Model of MOSEFT amplifier .
Amplifier configuration, Multistage or Cascade amplifier: classification of multi-stage amplifier, coupling and frequency response of cascaded systems, effect of cascading on multiuser amplifier gain, impedances bandwidth etc. Types of coupling, cascade and cascode circuits, Miller theorem, Darlington pair, bootstrap circuit.
Power amplifier: Class A large signal amplifiers, second-harmonic distortion, Transformer coupled audio power amplifier, Class B amplifier, Class AB operation push pull and Class C power amplifiers. Comparison of their efficiencies, types of distortion.
Tuned amplifier: single tuned, double tuned and stagger tuned amplifiers characteristics and their frequency response.
Feedback Amplifiers: Concept of feedback, positive and negative feedback, voltage and current feedback, series and shunt feedback, effect of feedback on performance characteristics of an amplifier, stability criterion.
Oscillators: Condition for sustained oscillation, R-C phase shift, Hartley, Colpitts, Crystal and Wein bridge oscillators, Negative resistance Oscillator, Relaxation Oscillator.
Integrated Electronics. - Millman Halkias
Electronic Devices & circuits – Boyelstad & Neshelsky – PHI
Electronic Devices & Circuits – David A.Bell – PHI
Principles of Electronic Devices – Malvino
To design the power supply of +5V & -5V using IC regulator.
To draw the forward and reverse bias characteristics of a semiconductor PN junction diode.
To draw the characteristics of Zener diode as a voltage regulator.
To observe the waveform of Clamper circuit.
To observe the waveform of Clipper circuit.
To observe the output waveform of half wave rectifier, also calculate its parameters like PIV, Ripple Factor, Form Factor, and Efficiency.
To observe the output waveform of full wave rectifier. , also calculate its parameters like PIV, Ripple Factor, Form Factor, and Efficiency.
To plot common base input and output characteristics for PNP bipolar junction transistor.
To plot common emitter input and output characteristics for NPN bipolar junction transistor.
To draw the static characteristics of JFET and find out its parameters.
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To make the students able to identify the main circuit elements and apply kirchhoff’s laws to calculate currents, voltages and powers in typical dc electric circuits using a variety of analytical methods.
To make the students capable to reduce more complicated circuits into the thevenin’s and norton’s equivalent circuits.
Evaluate the time response of basic circuits with one energy storage element to the sudden application of dc voltage or current as well as to the sudden change in the circuit configuration.
To make the students capable to define basic parameters describing a sine wave and evaluate the steady state time response of R, L and C elements supplied by sinusoidal voltage or current sources.
After successful completion of the course, student will be able to-
Apply the fundamental concepts in solving and analyzing different electrical networks
Ability to design the circuit for all theorems.
To solve all the algorithm of network analysis.
Able to find out the Y and Z parameters.
Introduction to LLBP circuit elements R,L,C and their characteristics in terms of Linearity & time dependent nature, KCL and KVL analysis dual networks analysis of magnetically coupled circuits Dot convention, coupling co-efficient, Tuned circuits. Series & parallel resonance voltage & current sources, controlled sources.
Network topology, concept of Network graph, Tree, Tree branch & link, Incidence matrix, cut set and tie set matrices.
Network Theorems – Thevenins & Norton’s theorem, superposition, reciprocity, compensation, maximum power transfer and Millman’s theorem, problems with controlled sources.
Transient analysis Transients in RL, RC & RLC Circuits initial conditions, time constants. Network driven by constant driving sources & their solutions.
Steady state analysis - Concept of phasor & vector, impedance & admittance. Node & mesh analysis of RL,RC and RLC networks with sinusoidal and other driving sources.
Frequency domain analysis – Laplace transform solution of Integro differential equations. Transform of Waveform – synthesized with step ramp, Gate and sinusoidal functions. Initial & final value theorem. Network Theorems in transform domain.
Concept of signal spectra, Fourier series co-efficient of a periodic waveform. Waveform symmetries. Trigonometric and Exponential form of Fourier series, steady state response to periodic signals.
Network function & Two port networks – concept of complex frequency, port. Network functions of one port & two ports, poles and zeros network of different kinds.
Two port parameters – Z,Y, chain parameters relationship between parameters. Interconnection of two ports. Terminated two port network.
M.E. Van Valkenburg, Network Analysis, PHI Publication.
F.F.Kuo, Network Analysis, TMH Publication
Sudhakar, Circuits & Systems, TMH Publication.
Chakrabarti, Circuit Theory, Dhanpat Rai & Co.
To verify Thevenin theorem.
To verify superposition theorem.
To verify reciprocity theorem.
To verify maximum power transfer theorem.
To verify Millman’s theorem.
To determine open circuit parameters of a two port network.
To determine short circuit parameters of a two port network.
To determine A, B, C, D parameters of a two port network
To determine h parameters of a two port network
To find frequency response of RLC series circuit.
To find frequency response of RLC parallel circuit.
Rajiv Gandhi Proudyogiki Vishwavidyalaya, Bhopal
Branch- Common to All Discipline
BT301 | Energy & Environmental Engineering | 3L-1T-0P | 4 Credits |
The objective of this Course is to provide an introduction to energy systems and renewable energy resources, with a scientific examination of the energy field and an emphasis on alternative energy sources and their technology and application.
Module 1: Introduction to Energy Science:
Introduction to energy systems and resources; Introduction to Energy, sustainability & the environment; Overview of energy systems, sources, transformations, efficiency, and storage; Fossil fuels (coal, oil, oil-bearing shale and sands, coal gasification) - past, present & future, Remedies & alternatives for fossil fuels - biomass, wind, solar, nuclear, wave, tidal and hydrogen; Sustainability and environmental trade-offs of different energy systems; possibilities for energy storage or regeneration (Ex. Pumped storage hydro power projects, superconductor- based energy storages, high efficiency batteries)
Module2: Ecosystems
Concept of an ecosystem; Structure and function of an ecosystem; Producers, consumers and decomposers; Energy flow in the ecosystem; Ecological succession; Food chains, food webs and ecological pyramids; Introduction, types, characteristic features, structure and function of the following ecosystem (a.)Forest ecosystem
(b) Grassland ecosystem (c) Desert ecosystem (d) Aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries)
Module 3: Biodiversity and its conservation
Introduction – Definition: genetic, species and ecosystem diversity; Bio- geographical classification of India; Value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values; Biodiversity at global, National and local levels; India as a mega-diversity nation; Hot-sports of biodiversity; Threats to biodiversity: habitat loss, poaching of wildlife, man- wildlife conflicts; Endangered and endemic species of India; Conservation of biodiversity: In-situ and Ex-situ conservation of biodiversity.
Module 4: Environmental Pollution
Definition, Cause, effects and control measures of Air pollution, Water pollution, Soil pollution, Marine pollution, Noise pollution, Thermal pollution, Nuclear hazards; Solid waste Management: Causes, effects and control measures of urban and industrial wastes; Role of an individual in prevention of pollution; Pollution case studies; Disaster management: floods, earthquake, cyclone and landslides.
Module 5: Social Issues and the Environment
From Unsustainable to Sustainable development; Urban problems related to energy; Water conservation, rain water harvesting, watershed management; Resettlement and rehabilitation of people; its problems and concerns. Case Studies
Environmental ethics: Issues and possible solutions. Climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and holocaust. Case Studies Wasteland reclamation; Consumerism and waste products; Environment Protection Act; Air (Prevention and Control of Pollution) Act; Water (Prevention and control of Pollution) Act; Wildlife Protection Act; Forest Conservation Act; Issues involved in enforcement of environmental legislation; Public awareness.
Module 6: Field work
Visit to a local area to document environmental assets- river/forest/grassland/hill/mountain
Visit to a local polluted site-Urban/Rural/Industrial/Agricultural
Study of common plants, insects, birds.
Study of simple ecosystems-pond, river, hill slopes, etc.
Brunner R.C., 1989, Hazardous Waste Incineration, McGraw Hill Inc.
Clark R.S., Marine Pollution, Clanderson Press Oxford (TB).
Cunningham, W.P. Cooper, T.H. Gorhani, E & Hepworth, M.T. 2001, Environmental Encyclopedia, Jaico Publ. House, Mumabai,
De A.K., Environmental Chemistry, Wiley Eastern Ltd.
Trivedi R.K., Handbook of Environmental Laws, Rules Guidelines, Compliances and Standards’, Vol I and II, Enviro Media (R)
Boyle, Godfrey, Bob Everett, and Janet Ramage (Eds.) (2004), Energy Systems and Sustainability: Power for a Sustainable Future. Oxford University Press.
Schaeffer, John (2007), Real Goods Solar Living Sourcebook: The Complete Guide to Renewable Energy Technologies and Sustainable Living, Gaiam
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To understand basics of Human Anatomy and Physiology.
To study the organs and systems involved in body functions.
To apply this knowledge into biomedical engineering field.
Describe and explain specific parts and key terms applied in anatomy and physiology
Describe important physiological mechanisms involved in cell, tissue, and organ
Understand organization and functions of each organs and systems in human body and understanding of biology and physiology the capability to apply advanced mathematics science, and engineering to solve problems at the interface of engineering and biology.
Structure of Neurons, Synapse and neurotransmitters, Central and Peripheral nervous system, various parts of nervous system; Brain: Parts and functions; Spinal cord, CSF, Ventricles of the brain, Autonomic nervous system, Reflex action.
Eye: Anatomy of Eye & Physiology of Vision, Ear: Structure of Ear & Physiology of Hearing, Nose: Sense of Smell, Tongue: Sense of Taste.
Brief idea of location of endocrine glands, Hormones of pituitary, pineal, thyroid, parathyroid, pancreas, adrenal glands and gonads, feedback mechanism. Mechanism of hormone action effects of hypo secretion and hyper secretion of various hormones of the above mentioned glands.
Anatomy of digestive system, movement of gastrointestinal tract, mastication, deglutination, physiological activities in mouth, pharynx, esophagus, stomach, pancreas, liver, gall bladder, small and large Intestine, Digestion and absorption.
Anatomy of Urinary System and Structure of Nephron, Physiology of urine formation, physiology of micturition, Concentration and Dilution of urine, Composition of Urine. Principles of Heamodylysis
Anatomy and Physiology in Health and Illness by Ross and Wilson
Human Anatomy and Physiology by Dr. Padma Sanghani
Text book of Medical Physiology by Guyton and Hall
Human Physiology and Anatomy by Fox Staurt Ira
Human Anatomy (Volume 1,2,3) by B.D.Chaurasia
To record electrical activity of heart of a subject by Electrocardiogram (Limb leads)
To record electrical activity of heart of a subject by Electrocardiogram (Chest leads)
To record brain electrical activity of a subject by Electroencephalogram (EEG).
To record muscles electrical activity of a subject by Electromyogram (EMG).
Operation and testing of Stethoscope
To Record heart sound of a subject by Phonocardiogram (PCG).
To find blood oxygen saturation level using finger Plythesmograph.
To measure blood Pressure with Indirect Blood pressure measuring equipment.
Operation and testing of Doppler shift Blood Pressure measurement
Operation and testing of Patient monitor.
.
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To introduce the basic concepts related to the operation of electrical & electronic measuring instruments.
To understand operational and application aspects of CRO (normal and storage).
To analyze and apply various AC bridges for the measurements of various physical quantities minimizing errors by following proper precautions.
To study the principles behind various transducers and their applications in the measurement of various parameters in electrical and mechanical engineering fields.
Upon successful completion of this course, the student will be able to:
Understand the basic concepts of electrical units, measurement errors and accuracy.
Measure different physical parameters using different transducers.
Gain experience in interpreting technical specifications and selecting sensors and transducers for a given application.
Apply the principles and practice for instrument design and develop for real world problems.
Measurements & Errors: Significance of measurements, methods of measurements: Direct & indirect methods, Mechanical, Electrical, Electronic Instruments, Classification of instruments, Deflection & null type, Characteristics of instruments: accuracy, precision, drift, span & range, Significant Figures, Static Sensitivity, Linearity, hysteresis, Threshold, Dead zone, Resolution, Loading effect etc.
Error & its types: Gross systematic error: Instrumental Error, Environmental error, observational error. Random error: Arithmetic mean, Range, deviation, Average deviation, Standard deviation, variance etc.
CRO & Measurements: Basic CRO Circuit, Dual trace Oscilloscope, Dual beam Oscilloscope, Sampling Oscilloscope, Analog Storage Oscilloscope, Digital Storage Oscilloscope.
Measurement with CRO: Frequency, Voltage, Current, Phase, Dielectric, Frequency ratio etc.
Bridges: General equation for bridge balance, Measurement of inductance, Capacitance and Q of the coil, Capacitance Maxwell’s, Wiens, Schering Bridge, Wagner Earth Tester.
Signal generator, Function generator, sweep frequency generator, Pulse and square wave generator, Wave Analyzers, Harmonic Distortion Analyzer, Spectrum Analyzer, Heterodyne frequency meter, frequency counter, measurement errors, automatic and computing counter, Digital voltmeter, Ramp type DVM, Integrating DVM, successive approximation DVM.
Transducer: Electrical transducers, classification of transducers, resistive transducer, resistance thermometers, thermistors, thermocouples, Inductive transducer, LVDT, Capacitive, piezoelectric, hall effect transducers. Measurement of non Electrical quantity: Displacement, strain, flow measurements, Rota meter, Venturi meter, Bourdon tube pressure transducer, temperature.
Sensors: Gas Sensor, NBA agent, Microbial sensor, electro analytical sensor, Enzyme based sensor-glucose sensor, Electronic nose –halitosis, breath analysis. Advances in sensor technology: lab –on –a chip, smart sensor, MEMS and Nano sensor. Radiation sensor , Thermal radiation sensor.
Electrical Electronics Measurement & Measuring Instrumentation by A.K Shawney.
Electronics & Instrumentation Measurement by J.B Gupta.
Instrumentation & Measurement by Helfrick Cooper, PHI India
Electronics Instrumentation, H.S. Kalasi, TMH India
Biomedical senses & Measurement by Wane, Pind, Liu, Sprinper.
Measurement, Instrumentation, and Sensors Handbook, Second Edition: Two- Volume Set John G. Webster, Halit Eren, CRC Press
Measurement System by Doebelin, Tata McGraw-Hill Education
Biosensors: Theory and Applications, Donald G. Buerk, by CRC Press
Fundamentals of Instrumentation 2nd Edition by NJATC, Cengage Learning; 2 edition
To measure the Amplitude, Frequency and Phase difference using Analog Dual Trace Oscilloscope.
To measure the some parameters using Digital Storage Oscilloscope (DSO).
To measure the unknown value of Inductance and Resistance using Maxwell Inductance Bridge.
To measure the unknown value of Capacitance using Schering Bridge.
To measure the unknown value of Capacitance and Frequency using Wien’s Bridge.
To measure the displacement using Light dependent Register (LDR).
To measure the temperature using Resistance Temperature Detector (RTD).
To Study the characteristics of the Linear Variable Differential Transformer (LVDT).
To measure the Intensity of Light on different distance by using Photo Transducer.
To measure Displacement using Capacitor pickup
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester BM303 Electronic Devices and Circuits
To understand the physics of semiconductor electronic devices, the characteristics their equivalent models and the characteristics and operation of the diodes.
To understand the internal working of the regulated power supply.
To understand the concept of biasing in BJT and JFET so as to able to analyze advanced electronic circuits.
After completing this course, the student will be able to:
Get clear understanding of internal physical behavior of PN junction Diode.
Understand the breakdown mechanisms in semiconductors so as to construct a Zener voltage regulator used in regulated power supplies.
Analyze various rectifiers and filter circuits used in regulated power supplies.
Understand the construction, operation and characteristics of Bipolar Junction Transistor, which can be used in the design of amplifiers.
Understand the construction, operation and characteristics of JFET and MOSFET, which can be used in the design of amplifiers.
Understand the need and requirements of biasing a transistor so that to avoid the failure of electronic circuits due to thermal effects
Physical structure and operation modes, Active region operation of transistor, D.C. analysis of transistor circuits, Transistor as an amplifier, Biasing the BJT: fixed bias, emitter feedback bias, collector feedback bias and, voltage divider bias. Basic BJT amplifier configuration: common emitter, common base and common collector amplifiers. Transistor as a switch: cut-off and saturation modes. High frequency model of BJT amplifier.
Junction Field-Effect Transistor (JFET) - Construction, Operation and Biasing, Depletion-type MOSFET, Enhancement-type MOSFET: structure and physical operation, current-voltage characteristics. D.C. operation of MOSFET circuits, MOSFET as an amplifier, Biasing in MOSFET amplifiers, Basic MOSFET amplifier configuration: common source, common gate and common drain types. High frequency Model of MOSEFT amplifier .
Amplifier configuration, Multistage or Cascade amplifier: classification of multi-stage amplifier, coupling and frequency response of cascaded systems, effect of cascading on multiuser amplifier gain, impedances bandwidth etc. Types of coupling, cascade and cascode circuits, Miller theorem, Darlington pair, bootstrap circuit.
Power amplifier: Class A large signal amplifiers, second-harmonic distortion, Transformer coupled audio power amplifier, Class B amplifier, Class AB operation push pull and Class C power amplifiers. Comparison of their efficiencies, types of distortion.
Tuned amplifier: single tuned, double tuned and stagger tuned amplifiers characteristics and their frequency response.
Feedback Amplifiers: Concept of feedback, positive and negative feedback, voltage and current feedback, series and shunt feedback, effect of feedback on performance characteristics of an amplifier, stability criterion.
Oscillators: Condition for sustained oscillation, R-C phase shift, Hartley, Colpitts, Crystal and Wein bridge oscillators, Negative resistance Oscillator, Relaxation Oscillator.
Integrated Electronics. - Millman Halkias
Electronic Devices & circuits – Boyelstad & Neshelsky – PHI
Electronic Devices & Circuits – David A.Bell – PHI
Principles of Electronic Devices – Malvino
To design the power supply of +5V & -5V using IC regulator.
To draw the forward and reverse bias characteristics of a semiconductor PN junction diode.
To draw the characteristics of Zener diode as a voltage regulator.
To observe the waveform of Clamper circuit.
To observe the waveform of Clipper circuit.
To observe the output waveform of half wave rectifier, also calculate its parameters like PIV, Ripple Factor, Form Factor, and Efficiency.
To observe the output waveform of full wave rectifier. , also calculate its parameters like PIV, Ripple Factor, Form Factor, and Efficiency.
To plot common base input and output characteristics for PNP bipolar junction transistor.
To plot common emitter input and output characteristics for NPN bipolar junction transistor.
To draw the static characteristics of JFET and find out its parameters.
New Scheme Based On AICTE Flexible Curricula Biomedical Engineering, III-Semester
To make the students able to identify the main circuit elements and apply kirchhoff’s laws to calculate currents, voltages and powers in typical dc electric circuits using a variety of analytical methods.
To make the students capable to reduce more complicated circuits into the thevenin’s and norton’s equivalent circuits.
Evaluate the time response of basic circuits with one energy storage element to the sudden application of dc voltage or current as well as to the sudden change in the circuit configuration.
To make the students capable to define basic parameters describing a sine wave and evaluate the steady state time response of R, L and C elements supplied by sinusoidal voltage or current sources.
After successful completion of the course, student will be able to-
Apply the fundamental concepts in solving and analyzing different electrical networks
Ability to design the circuit for all theorems.
To solve all the algorithm of network analysis.
Able to find out the Y and Z parameters.
Introduction to LLBP circuit elements R,L,C and their characteristics in terms of Linearity & time dependent nature, KCL and KVL analysis dual networks analysis of magnetically coupled circuits Dot convention, coupling co-efficient, Tuned circuits. Series & parallel resonance voltage & current sources, controlled sources.
Network topology, concept of Network graph, Tree, Tree branch & link, Incidence matrix, cut set and tie set matrices.
Network Theorems – Thevenins & Norton’s theorem, superposition, reciprocity, compensation, maximum power transfer and Millman’s theorem, problems with controlled sources.
Transient analysis Transients in RL, RC & RLC Circuits initial conditions, time constants. Network driven by constant driving sources & their solutions.
Steady state analysis - Concept of phasor & vector, impedance & admittance. Node & mesh analysis of RL,RC and RLC networks with sinusoidal and other driving sources.
Frequency domain analysis – Laplace transform solution of Integro differential equations. Transform of Waveform – synthesized with step ramp, Gate and sinusoidal functions. Initial & final value theorem. Network Theorems in transform domain.
Concept of signal spectra, Fourier series co-efficient of a periodic waveform. Waveform symmetries. Trigonometric and Exponential form of Fourier series, steady state response to periodic signals.
Network function & Two port networks – concept of complex frequency, port. Network functions of one port & two ports, poles and zeros network of different kinds.
Two port parameters – Z,Y, chain parameters relationship between parameters. Interconnection of two ports. Terminated two port network.
M.E. Van Valkenburg, Network Analysis, PHI Publication.
F.F.Kuo, Network Analysis, TMH Publication
Sudhakar, Circuits & Systems, TMH Publication.
Chakrabarti, Circuit Theory, Dhanpat Rai & Co.
To verify Thevenin theorem.
To verify superposition theorem.
To verify reciprocity theorem.
To verify maximum power transfer theorem.
To verify Millman’s theorem.
To determine open circuit parameters of a two port network.
To determine short circuit parameters of a two port network.
To determine A, B, C, D parameters of a two port network
To determine h parameters of a two port network
To find frequency response of RLC series circuit.
To find frequency response of RLC parallel circuit.