YOU CAN LEARN ABOUT ELECTRODES IN BIOMEDICAL INSTRUMENTATION, TYPES OF ELECTRODES, BODY SURFACE ELECTRODES, NEEDLE ELECTRODE, MICRO ELECTRODE, APPLICATIONS OF ELECTRODES
Medical instrumentation- patient monitoring systems Poornima D
Patient monitoring systems continuously measure important physiological parameters of critically ill patients. They display this medical data to care providers to help detect medical issues. A typical patient monitoring system uses sensors to measure values like ECG, heart rate, blood pressure, temperature, and respiration rate. It then sends this data to a bedside monitor or central monitoring station for clinicians to view. Modern systems use microcomputers and touchscreens instead of traditional devices. They organize data to improve patient care, set alarms, and help ensure patients receive better treatment with fewer medical staff.
Blood flow measurement involves quantifying the factors influencing blood pressure and flow. It aids in diagnosing and managing critically ill patients. There are invasive and non-invasive methods to measure blood flow in single vessels or tissue. Common techniques include electromagnetic flow meters, ultrasonic Doppler and transit-time flow meters, which use principles like electromagnetic induction or ultrasound to determine flow rate. Precise blood flow measurement is important for understanding cardiovascular conditions.
The document discusses an electromagnetic blood flow meter. It operates based on electromagnetic induction principles, inducing an EMF in blood flowing through a vessel perpendicular to a magnetic field. Electrodes placed across the vessel measure this induced EMF, which is proportional to blood velocity. The small EMF signal is amplified for measurement and low pass filtered to determine average blood flow rate. Advantages include a linear dynamic range and no mechanical limitations for measuring high and low blood flows.
Types of Transducers
Analog and Digital Transducer
Characteristic of Transducer
Selection factor of Transducer
Measurement of Displacement
LVDT and RVDT
Different types of strain Gauges
Manometers
Pressure Measuring Elements
Hall Effect
Thermocouple
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
Biotelemetry is the measurement and transmission of biological parameters such as heart rate, blood pressure, and body temperature from a distance. It allows for monitoring of things like astronauts in space, patients during exercise or in ambulances, and collecting medical data from homes or offices. It also enables research on unrestrained animals in their natural habitats. Biotelemetry systems consist of components like amplifiers, oscillators, power supplies, analog-to-digital converters, digital-to-analog converters, transducers, and processors to adapt existing measurement methods to transmit the resulting data.
Medical instrumentation- patient monitoring systems Poornima D
Patient monitoring systems continuously measure important physiological parameters of critically ill patients. They display this medical data to care providers to help detect medical issues. A typical patient monitoring system uses sensors to measure values like ECG, heart rate, blood pressure, temperature, and respiration rate. It then sends this data to a bedside monitor or central monitoring station for clinicians to view. Modern systems use microcomputers and touchscreens instead of traditional devices. They organize data to improve patient care, set alarms, and help ensure patients receive better treatment with fewer medical staff.
Blood flow measurement involves quantifying the factors influencing blood pressure and flow. It aids in diagnosing and managing critically ill patients. There are invasive and non-invasive methods to measure blood flow in single vessels or tissue. Common techniques include electromagnetic flow meters, ultrasonic Doppler and transit-time flow meters, which use principles like electromagnetic induction or ultrasound to determine flow rate. Precise blood flow measurement is important for understanding cardiovascular conditions.
The document discusses an electromagnetic blood flow meter. It operates based on electromagnetic induction principles, inducing an EMF in blood flowing through a vessel perpendicular to a magnetic field. Electrodes placed across the vessel measure this induced EMF, which is proportional to blood velocity. The small EMF signal is amplified for measurement and low pass filtered to determine average blood flow rate. Advantages include a linear dynamic range and no mechanical limitations for measuring high and low blood flows.
Types of Transducers
Analog and Digital Transducer
Characteristic of Transducer
Selection factor of Transducer
Measurement of Displacement
LVDT and RVDT
Different types of strain Gauges
Manometers
Pressure Measuring Elements
Hall Effect
Thermocouple
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
Biotelemetry is the measurement and transmission of biological parameters such as heart rate, blood pressure, and body temperature from a distance. It allows for monitoring of things like astronauts in space, patients during exercise or in ambulances, and collecting medical data from homes or offices. It also enables research on unrestrained animals in their natural habitats. Biotelemetry systems consist of components like amplifiers, oscillators, power supplies, analog-to-digital converters, digital-to-analog converters, transducers, and processors to adapt existing measurement methods to transmit the resulting data.
This document provides an overview of transducers. It defines a transducer as a device that converts a non-electrical physical quantity into an electrical signal. Transducers contain a sensing element that produces a measurable response to physical changes and a transduction element that converts the sensor output into an electrical form. Transducers are classified based on their output signal type (analog or digital), application method (primary or secondary), energy conversion method (active or passive), and transduction principle used (resistive, capacitive, inductive, etc.). Examples of common transducers discussed include thermocouples, strain gauges, thermistors, and linear variable differential transformers. Selection factors and applications of transducers
This document discusses different types of transducers. It begins by defining a transducer as a device that converts one form of energy into another. Transducers are then classified based on the type of energy conversion and whether they require an external power source. Examples of common transducers are given, such as resistance temperature detectors, thermistors, LVDTs, and strain gauges. Criteria for selecting transducers as well as their basic construction and applications are outlined. Advantages like low power requirements and ability to remotely monitor signals are contrasted with disadvantages such as cost, measurement accuracy, and vibration.
This document discusses various medical devices and technologies that use sensors. It describes sensors that measure bioelectric signals, technologies like X-rays and ultrasounds, and how computers helped make complex medical sensors feasible. It also discusses different types of biomedical sensors and provides examples like pacemakers, ECGs, and blood glucose meters. Overall, the document outlines the important role sensors play in various medical applications and technologies that have helped improve human health and care.
This document discusses electrical safety in medical environments. It outlines several hazards posed by electricity in these settings, including fire, hazardous substances, waste products, sound, electricity, and disasters. It then examines the physiological effects of electric current on the human body, such as stimulation of nerves and muscles, heating of tissues, and electrochemical burns. Threshold currents for perception, involuntary muscle contractions, respiratory paralysis and ventricular fibrillation are provided. The document also discusses electric power distribution, isolation systems, emergency power systems, electric faults in equipment, microshocks, and conductive paths to the heart in clinical devices.
This document provides information about electroencephalography (EEG), electromyography (EMG), and patient monitoring. It discusses how EEG is used to measure brain activity through electrodes on the scalp. It describes the different frequency bands seen on EEG and how they relate to mental states. The document outlines the components of an EEG recording system and various EEG artifacts. It also discusses EMG and how it is used to measure muscle electrical activity. Finally, it covers patient monitoring systems, including bedside monitors, central monitoring stations, and the parameters that are measured like heart rate, blood pressure, respiration rate.
Telemetry involves measuring values at a remote location and transmitting the data to another location. It involves three steps - measuring a value, converting it to a signal, transmitting the signal, and reconverting it back to the original data. Factors like accuracy, whether the data is analog or digital, error detection/correction, and bandwidth influence telemetry system design. There are two main types - landline systems which use wires/cables over short distances, and radio frequency systems which use radio links from 1km to beyond 50km. Landline systems transmit current or voltage and have simple circuitry but limited range. Radio frequency systems transmit via radio links and are used for long range applications like spacecraft. Modulation schemes include amplitude modulation for
Graphic record heart sound - Phonogram.
Recording the sounds connected with the pumping action of heart.
Sound from heart – phonocardiogram
Instrument to measure this – phonocardiograph
Basic function – to pick up the different heart sound,filter the required and display.
Isolation amplifiers provide electrical isolation and safety barriers between input and output stages. They use transformer, optical, or capacitive isolation methods and isolated power supplies to break continuity while amplifying low-level signals. Common applications include medical equipment, industrial processes, and data acquisition where electrical isolation is needed to protect patients or eliminate noise.
Transducers,Active Transducers and Passive TransducersAL- AMIN
Transducers are devices that convert one form of energy into another. They are used in a variety of applications like detecting muscle movement, measuring engine loads and knocks, converting temperature, pressure, and sound into electrical signals. Transducers are also used in antennas to convert electromagnetic waves to electrical signals. There are two main types: active transducers like thermocouples and photovoltaic cells convert non-electrical energy into electrical energy themselves, while passive transducers like strain gauges and differential transformers require an external force and convert non-electrical energy into electrical energy with help.
This document discusses patient monitoring systems and biotelemetry. It describes electrocardiogram (ECG) and blood pressure monitoring in hospitals. Intensive care unit (ICU) monitoring instruments that continuously measure vital signs are discussed. Biotelemetry systems that remotely transmit physiological data via radio frequency are then outlined, including the components of transmitters and receivers. Design considerations for biotelemetry systems using amplitude or frequency modulation are presented. Finally, both single-channel and multichannel biotelemetry systems are described.
The document discusses phonocardiography, which is the study of heart sounds using a phonocardiograph. A phonocardiograph is an instrument that picks up heart sounds, filters them, and displays the phonocardiogram, which is the graphic recording of heart sounds. There are two main types of heart sounds - normal sounds due to valve openings and closings, and abnormal murmurs due to turbulent blood flow. The document outlines the history and development of phonocardiography and the stethoscope, describes heart sound characteristics, and discusses the components of a phonocardiogram recording system.
A Bioamplifier is an electrophysiological device, a variation of the instrumentation amplifier, used to gather and increase the signal integrity of physiologic electrical activity for output to various sources. It may be an independent unit, or integrated into the electrodes.
Electrical safety in biophysical measurementsJaya Yadav
This document discusses various methods for protecting patients, visitors, and staff from electrical hazards in healthcare facilities, including macro-shocks and micro-shocks. It outlines the importance of grounding systems, isolation transformers, ground fault circuit interrupters (GFCIs), leakage current reduction, insulation standards for medical equipment classes, isolation amplifiers, and periodic safety testing using electrical safety analyzers. The overall goal is to eliminate electric connections to the heart and minimize hazards through grounding, insulation, and monitoring of leakage currents and voltages.
Biopotentials are ionic voltages produced by electrochemical activity in cells. Certain cells like nerve and muscle cells are encased in a semi-permeable membrane that allows some substances to pass through while keeping others out. These membranes maintain a resting potential of -60 to -100 mV by allowing potassium and chloride ions into the cell while blocking sodium ions. When the membrane allows sodium ions to pass through, the cell's potential becomes slightly positive in what is called an action potential, changing the cell from its resting state. Transducers are used to convert these ionic potentials into electrical signals that can be measured and analyzed.
Biomedical Instrumentation and its Fundamentals,Bio electric Signals(ECG, EMG ,EEG)and its Electrodes ,Physiological Transducers,Blood Pressure ,Blood Flow,Cardiac Output ,Patient Safety,Physiological Effects of Electric current on human body etc...
You can learn about ECG AMPLIFIER, INSTRUMENTATION AMPLIFIER, ECG AMPLIFIER DIAGRAM, VALUE OF RC TIME CONSTANT ?, DRIVEN-RIGHT-LEG SYSTEM, EQUIVALENT CIRCUIT FOR THE INPUT OF AN ECG AMPLIFIER, Method to increase input impedance, Active filters, FREQUENCY RESPONSE, LOW PASS FILTER, HIGH PASS FILTER, BAND PASS FILTER, Resonant frequency, Quality factor or Q factor
VIDEO LINK: https://youtu.be/sBG17ffSh40
Refer this link to get idea about instrumentation amplifier
https://youtu.be/-j8ePvHOuGk
You can learn about ARTIFACTS, BASIC ELECTRONIC RECORDING SYSTEM, EFFECTS OF ARTIFACTS ON ECG RECORDINGS, POWER LINE INTERFERENCE, SHIFTING OF THE BASELINE, MUSCLE TREMOR, PROBLEM SOLVING METHOD, MOTIVATIONAL TOPIC ABOUT LEADERSHIP QUALITIES
This document provides an overview of transducers. It defines a transducer as a device that converts a non-electrical physical quantity into an electrical signal. Transducers contain a sensing element that produces a measurable response to physical changes and a transduction element that converts the sensor output into an electrical form. Transducers are classified based on their output signal type (analog or digital), application method (primary or secondary), energy conversion method (active or passive), and transduction principle used (resistive, capacitive, inductive, etc.). Examples of common transducers discussed include thermocouples, strain gauges, thermistors, and linear variable differential transformers. Selection factors and applications of transducers
This document discusses different types of transducers. It begins by defining a transducer as a device that converts one form of energy into another. Transducers are then classified based on the type of energy conversion and whether they require an external power source. Examples of common transducers are given, such as resistance temperature detectors, thermistors, LVDTs, and strain gauges. Criteria for selecting transducers as well as their basic construction and applications are outlined. Advantages like low power requirements and ability to remotely monitor signals are contrasted with disadvantages such as cost, measurement accuracy, and vibration.
This document discusses various medical devices and technologies that use sensors. It describes sensors that measure bioelectric signals, technologies like X-rays and ultrasounds, and how computers helped make complex medical sensors feasible. It also discusses different types of biomedical sensors and provides examples like pacemakers, ECGs, and blood glucose meters. Overall, the document outlines the important role sensors play in various medical applications and technologies that have helped improve human health and care.
This document discusses electrical safety in medical environments. It outlines several hazards posed by electricity in these settings, including fire, hazardous substances, waste products, sound, electricity, and disasters. It then examines the physiological effects of electric current on the human body, such as stimulation of nerves and muscles, heating of tissues, and electrochemical burns. Threshold currents for perception, involuntary muscle contractions, respiratory paralysis and ventricular fibrillation are provided. The document also discusses electric power distribution, isolation systems, emergency power systems, electric faults in equipment, microshocks, and conductive paths to the heart in clinical devices.
This document provides information about electroencephalography (EEG), electromyography (EMG), and patient monitoring. It discusses how EEG is used to measure brain activity through electrodes on the scalp. It describes the different frequency bands seen on EEG and how they relate to mental states. The document outlines the components of an EEG recording system and various EEG artifacts. It also discusses EMG and how it is used to measure muscle electrical activity. Finally, it covers patient monitoring systems, including bedside monitors, central monitoring stations, and the parameters that are measured like heart rate, blood pressure, respiration rate.
Telemetry involves measuring values at a remote location and transmitting the data to another location. It involves three steps - measuring a value, converting it to a signal, transmitting the signal, and reconverting it back to the original data. Factors like accuracy, whether the data is analog or digital, error detection/correction, and bandwidth influence telemetry system design. There are two main types - landline systems which use wires/cables over short distances, and radio frequency systems which use radio links from 1km to beyond 50km. Landline systems transmit current or voltage and have simple circuitry but limited range. Radio frequency systems transmit via radio links and are used for long range applications like spacecraft. Modulation schemes include amplitude modulation for
Graphic record heart sound - Phonogram.
Recording the sounds connected with the pumping action of heart.
Sound from heart – phonocardiogram
Instrument to measure this – phonocardiograph
Basic function – to pick up the different heart sound,filter the required and display.
Isolation amplifiers provide electrical isolation and safety barriers between input and output stages. They use transformer, optical, or capacitive isolation methods and isolated power supplies to break continuity while amplifying low-level signals. Common applications include medical equipment, industrial processes, and data acquisition where electrical isolation is needed to protect patients or eliminate noise.
Transducers,Active Transducers and Passive TransducersAL- AMIN
Transducers are devices that convert one form of energy into another. They are used in a variety of applications like detecting muscle movement, measuring engine loads and knocks, converting temperature, pressure, and sound into electrical signals. Transducers are also used in antennas to convert electromagnetic waves to electrical signals. There are two main types: active transducers like thermocouples and photovoltaic cells convert non-electrical energy into electrical energy themselves, while passive transducers like strain gauges and differential transformers require an external force and convert non-electrical energy into electrical energy with help.
This document discusses patient monitoring systems and biotelemetry. It describes electrocardiogram (ECG) and blood pressure monitoring in hospitals. Intensive care unit (ICU) monitoring instruments that continuously measure vital signs are discussed. Biotelemetry systems that remotely transmit physiological data via radio frequency are then outlined, including the components of transmitters and receivers. Design considerations for biotelemetry systems using amplitude or frequency modulation are presented. Finally, both single-channel and multichannel biotelemetry systems are described.
The document discusses phonocardiography, which is the study of heart sounds using a phonocardiograph. A phonocardiograph is an instrument that picks up heart sounds, filters them, and displays the phonocardiogram, which is the graphic recording of heart sounds. There are two main types of heart sounds - normal sounds due to valve openings and closings, and abnormal murmurs due to turbulent blood flow. The document outlines the history and development of phonocardiography and the stethoscope, describes heart sound characteristics, and discusses the components of a phonocardiogram recording system.
A Bioamplifier is an electrophysiological device, a variation of the instrumentation amplifier, used to gather and increase the signal integrity of physiologic electrical activity for output to various sources. It may be an independent unit, or integrated into the electrodes.
Electrical safety in biophysical measurementsJaya Yadav
This document discusses various methods for protecting patients, visitors, and staff from electrical hazards in healthcare facilities, including macro-shocks and micro-shocks. It outlines the importance of grounding systems, isolation transformers, ground fault circuit interrupters (GFCIs), leakage current reduction, insulation standards for medical equipment classes, isolation amplifiers, and periodic safety testing using electrical safety analyzers. The overall goal is to eliminate electric connections to the heart and minimize hazards through grounding, insulation, and monitoring of leakage currents and voltages.
Biopotentials are ionic voltages produced by electrochemical activity in cells. Certain cells like nerve and muscle cells are encased in a semi-permeable membrane that allows some substances to pass through while keeping others out. These membranes maintain a resting potential of -60 to -100 mV by allowing potassium and chloride ions into the cell while blocking sodium ions. When the membrane allows sodium ions to pass through, the cell's potential becomes slightly positive in what is called an action potential, changing the cell from its resting state. Transducers are used to convert these ionic potentials into electrical signals that can be measured and analyzed.
Biomedical Instrumentation and its Fundamentals,Bio electric Signals(ECG, EMG ,EEG)and its Electrodes ,Physiological Transducers,Blood Pressure ,Blood Flow,Cardiac Output ,Patient Safety,Physiological Effects of Electric current on human body etc...
You can learn about ECG AMPLIFIER, INSTRUMENTATION AMPLIFIER, ECG AMPLIFIER DIAGRAM, VALUE OF RC TIME CONSTANT ?, DRIVEN-RIGHT-LEG SYSTEM, EQUIVALENT CIRCUIT FOR THE INPUT OF AN ECG AMPLIFIER, Method to increase input impedance, Active filters, FREQUENCY RESPONSE, LOW PASS FILTER, HIGH PASS FILTER, BAND PASS FILTER, Resonant frequency, Quality factor or Q factor
VIDEO LINK: https://youtu.be/sBG17ffSh40
Refer this link to get idea about instrumentation amplifier
https://youtu.be/-j8ePvHOuGk
You can learn about ARTIFACTS, BASIC ELECTRONIC RECORDING SYSTEM, EFFECTS OF ARTIFACTS ON ECG RECORDINGS, POWER LINE INTERFERENCE, SHIFTING OF THE BASELINE, MUSCLE TREMOR, PROBLEM SOLVING METHOD, MOTIVATIONAL TOPIC ABOUT LEADERSHIP QUALITIES
The document discusses pulse rate measurement and factors that affect pulse. It describes how the pulse is the pressure wave felt when the heart contracts and can be measured at various points like the wrist. The pulse rate is affected by age, gender, exercise, medications, stress, fever, blood loss, and certain diseases. It also discusses different methods of measuring pulse like using a photoresistor over the finger in transmittance and reflectance methods.
You can learn about Pressure, Blood Pressure, Types of Pressure, Types of Blood Pressure, Systolic and Diastolic Pressure, Blood Pressure Measurement Methods, Indirect method of Blood pressure Measurement/Auscultator Method/Oscillometric Method, Sphymomanometer, Direct Method, Probes used in Direct BP Measurement, Measurement of systolic and diastolic Blood pressure
You can learn about Function of Respiratoray System, Types of Respiration Rate Measurement Methods, Displacement Method, Thermistor Method, Impedance Pneumography, CO2 Method, Apnoea Detector, Block Diagram of Apnoea Detecto
You can learn about Vital Signs of Patient,Types of Temperature measurement, Systematic body temperature measurement, Mercury Thermometer, Thermometer, Thermocouple, Thermistor, Resistance calculation formula, Surface Temperature / Skin Temperature measurement, Infrared Thermometer, Thermovision, Thermograph, Thermogram, Coding Task
This document discusses different types of bio amplifiers including operational amplifiers, differential amplifiers, instrumentation amplifiers, isolation amplifiers, and carrier amplifiers. Instrumentation amplifiers are used to measure physical conditions like temperature and humidity inside plants, and require high common-mode rejection ratio to reject noise. Isolation amplifiers provide electrical isolation and safety barriers, and can use transformer, optical, or capacitive isolation methods. Transformer isolation uses frequency modulation to transmit signals across an isolation barrier, while optical isolation converts signals to light and back. Capacitive isolation uses digital encoding and frequency modulation across a capacitive barrier.
Bio signal characteristics and recording modesBharathasreejaG
YOU CAN LEARN ABOUT BIO ELECTRIC SIGNAL CHARACTERISTICS # RECORDING MODES # BASICS OF BIOMEDICAL INSTRUMENTATION UNIT II CONTENTS # MEDICAL ELECTRONICS BIO ELECTRIC SIGNAL CHARACTERISTICS
MEASUREMENT OF BIO POTENTIAL USING TWO ELECTRODES AND RECORDING PROBLEMSBharathasreejaG
YOU CAN LEARN ABOUT MEASUREMENT USING TWO ELECTRODES & RECORDING PROBLEMS# NEED OF MEDICAL RECORDING # ELECTRODE TO SKIN INTERFACE # NERNST EQUATION # NOISE DURING RECORDING# MOTION ARTIFACT# ELECTRODE TO ELECTROLYTE NOISE # ELECTROLYTE TO SKIN NOISE# THERMAL NOISE# AMPLIFICATION NOISE# CABLE MOVEMENT# OTHER NOISES # CODING FOR GENERATING NOISE
YOU CAN LEARN ABOUT INTRODUCTION TO BASICS OF BIOMEDICAL INSTRUMENTATION, WHAT IS INSTRUMENTATION, MEASUREMENT AND CONTROL#INSTRUMENTATION AND AUTOMATION, EXAMPLES FOR INSTRUMENTATION AND AUTOMATION, INSTRUMENTATION IN MEDICAL FIELD, COMPONENTS IN INSTRUMENTATION SYSTEM, INSTRUMENTS IN MEDICAL FIELD
This document provides an overview of wound healing, its functions, stages, mechanisms, factors affecting it, and complications.
A wound is a break in the integrity of the skin or tissues, which may be associated with disruption of the structure and function.
Healing is the body’s response to injury in an attempt to restore normal structure and functions.
Healing can occur in two ways: Regeneration and Repair
There are 4 phases of wound healing: hemostasis, inflammation, proliferation, and remodeling. This document also describes the mechanism of wound healing. Factors that affect healing include infection, uncontrolled diabetes, poor nutrition, age, anemia, the presence of foreign bodies, etc.
Complications of wound healing like infection, hyperpigmentation of scar, contractures, and keloid formation.
How to Make a Field Mandatory in Odoo 17Celine George
In Odoo, making a field required can be done through both Python code and XML views. When you set the required attribute to True in Python code, it makes the field required across all views where it's used. Conversely, when you set the required attribute in XML views, it makes the field required only in the context of that particular view.
Chapter wise All Notes of First year Basic Civil Engineering.pptxDenish Jangid
Chapter wise All Notes of First year Basic Civil Engineering
Syllabus
Chapter-1
Introduction to objective, scope and outcome the subject
Chapter 2
Introduction: Scope and Specialization of Civil Engineering, Role of civil Engineer in Society, Impact of infrastructural development on economy of country.
Chapter 3
Surveying: Object Principles & Types of Surveying; Site Plans, Plans & Maps; Scales & Unit of different Measurements.
Linear Measurements: Instruments used. Linear Measurement by Tape, Ranging out Survey Lines and overcoming Obstructions; Measurements on sloping ground; Tape corrections, conventional symbols. Angular Measurements: Instruments used; Introduction to Compass Surveying, Bearings and Longitude & Latitude of a Line, Introduction to total station.
Levelling: Instrument used Object of levelling, Methods of levelling in brief, and Contour maps.
Chapter 4
Buildings: Selection of site for Buildings, Layout of Building Plan, Types of buildings, Plinth area, carpet area, floor space index, Introduction to building byelaws, concept of sun light & ventilation. Components of Buildings & their functions, Basic concept of R.C.C., Introduction to types of foundation
Chapter 5
Transportation: Introduction to Transportation Engineering; Traffic and Road Safety: Types and Characteristics of Various Modes of Transportation; Various Road Traffic Signs, Causes of Accidents and Road Safety Measures.
Chapter 6
Environmental Engineering: Environmental Pollution, Environmental Acts and Regulations, Functional Concepts of Ecology, Basics of Species, Biodiversity, Ecosystem, Hydrological Cycle; Chemical Cycles: Carbon, Nitrogen & Phosphorus; Energy Flow in Ecosystems.
Water Pollution: Water Quality standards, Introduction to Treatment & Disposal of Waste Water. Reuse and Saving of Water, Rain Water Harvesting. Solid Waste Management: Classification of Solid Waste, Collection, Transportation and Disposal of Solid. Recycling of Solid Waste: Energy Recovery, Sanitary Landfill, On-Site Sanitation. Air & Noise Pollution: Primary and Secondary air pollutants, Harmful effects of Air Pollution, Control of Air Pollution. . Noise Pollution Harmful Effects of noise pollution, control of noise pollution, Global warming & Climate Change, Ozone depletion, Greenhouse effect
Text Books:
1. Palancharmy, Basic Civil Engineering, McGraw Hill publishers.
2. Satheesh Gopi, Basic Civil Engineering, Pearson Publishers.
3. Ketki Rangwala Dalal, Essentials of Civil Engineering, Charotar Publishing House.
4. BCP, Surveying volume 1
How to Build a Module in Odoo 17 Using the Scaffold MethodCeline George
Odoo provides an option for creating a module by using a single line command. By using this command the user can make a whole structure of a module. It is very easy for a beginner to make a module. There is no need to make each file manually. This slide will show how to create a module using the scaffold method.
How to Add Chatter in the odoo 17 ERP ModuleCeline George
In Odoo, the chatter is like a chat tool that helps you work together on records. You can leave notes and track things, making it easier to talk with your team and partners. Inside chatter, all communication history, activity, and changes will be displayed.
How to Setup Warehouse & Location in Odoo 17 InventoryCeline George
In this slide, we'll explore how to set up warehouses and locations in Odoo 17 Inventory. This will help us manage our stock effectively, track inventory levels, and streamline warehouse operations.
A workshop hosted by the South African Journal of Science aimed at postgraduate students and early career researchers with little or no experience in writing and publishing journal articles.
This presentation includes basic of PCOS their pathology and treatment and also Ayurveda correlation of PCOS and Ayurvedic line of treatment mentioned in classics.
Strategies for Effective Upskilling is a presentation by Chinwendu Peace in a Your Skill Boost Masterclass organisation by the Excellence Foundation for South Sudan on 08th and 09th June 2024 from 1 PM to 3 PM on each day.
A review of the growth of the Israel Genealogy Research Association Database Collection for the last 12 months. Our collection is now passed the 3 million mark and still growing. See which archives have contributed the most. See the different types of records we have, and which years have had records added. You can also see what we have for the future.
Main Java[All of the Base Concepts}.docxadhitya5119
This is part 1 of my Java Learning Journey. This Contains Custom methods, classes, constructors, packages, multithreading , try- catch block, finally block and more.
it describes the bony anatomy including the femoral head , acetabulum, labrum . also discusses the capsule , ligaments . muscle that act on the hip joint and the range of motion are outlined. factors affecting hip joint stability and weight transmission through the joint are summarized.