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Electronics In Biomedical Engineering: Theory & Repair - AD-TEAM - 09-05-2024
![[Image: 505b5b158686b1c52134d2fe959555b5.jpg]](https://i123.fastpic.org/big/2024/0905/b5/505b5b158686b1c52134d2fe959555b5.jpg)
Electronics In Biomedical Engineering: Theory & Repair
Published 3/2024
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 10.33 GB | Duration: 21h 30m
Master Electronics & Biomed Engineering: Troubleshoot, Repair Medical Devices & Develop Solutions for Healtcare
[b]What you'll learn[/b]
Analyze and design electronic circuits for biomedical applications.
Understand the principles and operation of various biomedical instruments.
Troubleshoot and diagnose issues in electronic systems and medical devices.
Repair and maintain medical equipment while adhering to safety guidelines.
Apply digital electronics knowledge to program and control medical devices.
Process and analyze biomedical signals using appropriate techniques.
Identify and classify medical devices based on their functionalities and risks.
Integrate electronics and biomedical concepts to develop innovative solutions.
Communicate effectively with engineers and healthcare professionals in the field.
Undertake hands-on projects, applying theoretical knowledge to practical applications.
[b]Requirements[/b]
No experience is needed just some passion and determination.
To get the full benefit of the course, you will need to follow along and build the circuits. Thus, access to arduino, breadboards, power supplies, tools, parts, etc
Computer pc or mac .. any version of windows or os capable of running various design tools used in this course such as arduino
[b]Description[/b]
The course "Electronics in Biomedical Engineering: Theory & Repair" provides a comprehensive and immersive learning experience for individuals interested in the intersection of electronics and biomedical engineering. The content covers a range of essential topics, starting with the fundamentals of electronics components and circuits, ensuring students grasp the core principles.Moving forward, the course delves into the applications of electronics in biomedical instrumentation. Students will explore how various medical devices function, enabling accurate measurement and monitoring of vital signs and bioelectric signals. They will gain an understanding of sensors, transducers, and amplifiers used in medical devices and how to optimize their performance.A key focus of the course is troubleshooting methodologies. Students will learn structured approaches to diagnose and rectify malfunctions in electronic systems and medical devices. Practical skills will be honed in repairing and maintaining medical equipment, adhering to safety protocols to ensure proper functionality and patient well-being.The course also introduces students to the concept of digital electronics and microcontrollers. They will discover how these components play a vital role in medical device development, allowing for precise control and automation.Biomedical signal processing is another crucial aspect of the course, where students will learn how to analyze and process bioelectric signals. Understanding signal processing techniques will enable them to extract valuable information from biomedical signals, crucial for medical diagnosis and research.Furthermore, the course presents an overview of medical device technology and classifications. Students will become familiar with the regulatory framework and safety standards guiding the design and use of medical devices.In addition to theoretical knowledge, the course emphasizes practical application. Students will engage in hands-on projects, integrating electronics and biomedical engineering principles to create innovative solutions for healthcare challenges.In summary, "Electronics in Biomedical Engineering: Theory & Repair" equips students with a diverse skill set, empowering them to excel in biomedical electronics. Whether pursuing careers in the medical device industry, healthcare settings, or research, students will be well-prepared to make a positive impact in this rapidly evolving field.
Overview
Section 1: Introduction
Lecture 1 Introduction to the Course
Section 2: Introduction to Electronics : Basic electronics knowledge
Lecture 2 what is electricity ?
Lecture 3 Voltage, current and resistance
Lecture 4 AC wave, DC wave and the frequency
Section 3: Introduction to Electronics : Basic electronic components and their properties
Lecture 5 Resistor
Lecture 6 Voltage divider (UPDATED LECTURE)
Lecture 7 LDR
Lecture 8 Diode
Lecture 9 Zener diode
Lecture 10 LED
Lecture 11 LED-current limitting resistor (UPDATED LECTURE)
Lecture 12 7 segment display (UPDATED LECTURE)
Lecture 13 IR LED
Lecture 14 Capacitor
Lecture 15 Bypass Capacitor (UPDATED LECTURE)
Lecture 16 Transistor as a switch
Lecture 17 IC chips
Lecture 18 Relay
Lecture 19 Transformer
Section 4: Introduction to Electronics: Circuit analysis techniques
Lecture 20 Circuit analysis techniques content
Lecture 21 Circuit analysis techniques
Section 5: Digital Electronics: Analog to Digital Converters
Lecture 22 Digital Vs. Analog Signals
Lecture 23 The Duty cycle
Lecture 24 ADC (analog to digital converter)
Lecture 25 1) Staircase ADC
Lecture 26 2) Flash ADC
Lecture 27 3) Pipeline ADC
Lecture 28 4) SAR ADC
Lecture 29 5) Delta-Sigma ADC
Section 6: Digital Electronics: Microprocessors and microcontrollers (Arduino)
Lecture 30 What are Microprocessors and microcontrollers ??
Lecture 31 What is arduino ??
Lecture 32 Types of Arduino boards
Lecture 33 Sitting up and start programming ( blink project )
Lecture 34 Using variables
Lecture 35 Using digital pins
Lecture 36 Using analog pins
Lecture 37 Serial monitor
Lecture 38 If statement
Lecture 39 For loop
Lecture 40 Dimmable LED
Lecture 41 ECG explaination
Lecture 42 ECG (Electrocardiogragh) a biomedical project using arduino
Section 7: Circuit Design and Analysis: Operational amplifiers and their applications
Lecture 43 Op amp introduction
Lecture 44 The characteristics of operational amplifier
Lecture 45 OP-AMP GAIN
Lecture 46 The Bandwidth of Operational Amplifier
Lecture 47 The Effect of Input-Offset Voltage on Output Voltage of Operational Amplifiers
Lecture 48 Feedback Equation and stability
Lecture 49 Cascade circuit of operational amplifier
Lecture 50 Some Examples on Op-Amp
Lecture 51 Introduction to Operational Amplifier Applications
Lecture 52 Understanding Comparators: Operation and Examples
Lecture 53 Summing Amplifiers: Combining Signals with Precision
Lecture 54 Summing amplifier (Digital to Analog Converter)
Lecture 55 Differential amplifier
Lecture 56 Low Pass Filters with Integrating Op-Amp: Signal Smoothing and Integration
Lecture 57 High Pass Filters with Differentiating Op-Amp: Signal Edge Detection and Differe
Section 8: Circuit Design and Analysis: Filters and their design
Lecture 58 what are filters ? and there types
Lecture 59 Low-Pass Filters
Lecture 60 High-Pass Filters
Lecture 61 Band-Pass Filters
Lecture 62 Band-Stop Filters (Notch Filters)
Section 9: Simple Biomedical project based on previous lectures
Lecture 63 Understanding working principles of heartbeat Sensor for the project
Lecture 64 Using proteus 8 pro in simulating and designing the circuits
Lecture 65 Designing the project and simulate it using proteus
Lecture 66 Using Breadboard in connecting the circuit
Section 10: Circuit Design and Analysis: Advanced circuit analysis techniques
Lecture 67 AC Analysis
Lecture 68 Transient Analysis
Lecture 69 AC Power Analysis
Lecture 70 Frequency Response
Section 11: Applications of Advanced Circuit Analysis in Biomedical Engineering
Lecture 71 Some Examples of Applications of Circuit Analysis in Biomedical Engineering
Section 12: Circuit Design and Analysis: Power supplies and voltage regulation
Lecture 72 Introduction to Power Supplies
Lecture 73 Types of Power Supplies
Lecture 74 Designing Simple Linear Power Supply Circuit
Lecture 75 Voltage Regulators and Their Types
Lecture 76 Designing the circuit of the switching regulator
Lecture 77 Medical Device Power Requirements & Considerations
Section 13: Biomedical Instrumentation
Lecture 78 Introduction to Biomedical Instrumentation
Lecture 79 Sensors and transducers used in medical devices
Lecture 80 Applications of Transducers in Biomedical Engineering
Lecture 81 Amplifiers and signal conditioning techniques for biomedical signals
Section 14: Electrodes and bioelectric signals (ECG, EEG, EMG, etc.)
Lecture 82 Sources of Biomedical Signals and Origin of Bioelectric Signals
Lecture 83 ECG & EEG
Lecture 84 EMG, EOG & ERG
Lecture 85 Electrode-Tissue Interface and Motion Artifacts in Biopotential Measurements
Lecture 86 Exploring Electrode Types and Innovations in ECG Monitoring
Lecture 87 Electrodes in Electrophysiological Recordings
Section 15: Medical Device Technology
Lecture 88 Overview of medical devices and their classifications
Lecture 89 Safety regulations and standards in medical device design
Lecture 90 A medical device design and development guide by Mindsailors
Section 16: Working principles of commonly used elecronic medical equipment
Lecture 91 ECG (Electrocardiogragh)
Lecture 92 Physiological Background about the heart
Lecture 93 Pulse Oximeter
Lecture 94 More about pulse oximetry
Lecture 95 Sphygmomanometer
Lecture 96 More about Sphygmomanometer
Lecture 97 Endoscope
Lecture 98 Defibrillator
Section 17: Introduction to electronic measurement tools
Lecture 99 Digital Multimeter (DMM)
Lecture 100 Oscilloscope
Lecture 101 Function Generator
Lecture 102 Logic Analyzer
Lecture 103 Spectrum Analyzer
Lecture 104 LCR Meter
Section 18: Troubleshooting and Repairing Medical Devices
Lecture 105 Introduction to troubleshooting methodologies
Lecture 106 Common issues in medical devices and their diagnosis
Lecture 107 Intro to PCB (Printed Circuit Board)
Lecture 108 What are PCBs ?? (Documentary)
Lecture 109 PCB ( Printed Circuit Board ) Explained
Lecture 110 Repairing techniques for electronic components and circuit boards
Section 19: Project Work
Lecture 111 Working Principle Of EMG
Lecture 112 The Circuit and the designing of the EMG
Electronics and Biomedical Engineering Students,Electronics Technicians,Innovators and Entrepreneurs,Electronics Enthusiasts,Anyone who has a passion for this field or wants to start working in this field of work,Beginner at electronic engineering want to combin electronics with biomedicine to develop new medical technologies.
![[Image: hdz1g82f_o.jpg]](https://images2.imgbox.com/a4/a4/hdz1g82f_o.jpg)
[b]What you'll learn[/b]
Analyze and design electronic circuits for biomedical applications.
Understand the principles and operation of various biomedical instruments.
Troubleshoot and diagnose issues in electronic systems and medical devices.
Repair and maintain medical equipment while adhering to safety guidelines.
Apply digital electronics knowledge to program and control medical devices.
Process and analyze biomedical signals using appropriate techniques.
Identify and classify medical devices based on their functionalities and risks.
Integrate electronics and biomedical concepts to develop innovative solutions.
Communicate effectively with engineers and healthcare professionals in the field.
Undertake hands-on projects, applying theoretical knowledge to practical applications.
[b]Requirements[/b]
No experience is needed just some passion and determination.
To get the full benefit of the course, you will need to follow along and build the circuits. Thus, access to arduino, breadboards, power supplies, tools, parts, etc
Computer pc or mac .. any version of windows or os capable of running various design tools used in this course such as arduino
[b]Description[/b]
The course "Electronics in Biomedical Engineering: Theory & Repair" provides a comprehensive and immersive learning experience for individuals interested in the intersection of electronics and biomedical engineering. The content covers a range of essential topics, starting with the fundamentals of electronics components and circuits, ensuring students grasp the core principles.Moving forward, the course delves into the applications of electronics in biomedical instrumentation. Students will explore how various medical devices function, enabling accurate measurement and monitoring of vital signs and bioelectric signals. They will gain an understanding of sensors, transducers, and amplifiers used in medical devices and how to optimize their performance.A key focus of the course is troubleshooting methodologies. Students will learn structured approaches to diagnose and rectify malfunctions in electronic systems and medical devices. Practical skills will be honed in repairing and maintaining medical equipment, adhering to safety protocols to ensure proper functionality and patient well-being.The course also introduces students to the concept of digital electronics and microcontrollers. They will discover how these components play a vital role in medical device development, allowing for precise control and automation.Biomedical signal processing is another crucial aspect of the course, where students will learn how to analyze and process bioelectric signals. Understanding signal processing techniques will enable them to extract valuable information from biomedical signals, crucial for medical diagnosis and research.Furthermore, the course presents an overview of medical device technology and classifications. Students will become familiar with the regulatory framework and safety standards guiding the design and use of medical devices.In addition to theoretical knowledge, the course emphasizes practical application. Students will engage in hands-on projects, integrating electronics and biomedical engineering principles to create innovative solutions for healthcare challenges.In summary, "Electronics in Biomedical Engineering: Theory & Repair" equips students with a diverse skill set, empowering them to excel in biomedical electronics. Whether pursuing careers in the medical device industry, healthcare settings, or research, students will be well-prepared to make a positive impact in this rapidly evolving field.
Overview
Section 1: Introduction
Lecture 1 Introduction to the Course
Section 2: Introduction to Electronics : Basic electronics knowledge
Lecture 2 what is electricity ?
Lecture 3 Voltage, current and resistance
Lecture 4 AC wave, DC wave and the frequency
Section 3: Introduction to Electronics : Basic electronic components and their properties
Lecture 5 Resistor
Lecture 6 Voltage divider (UPDATED LECTURE)
Lecture 7 LDR
Lecture 8 Diode
Lecture 9 Zener diode
Lecture 10 LED
Lecture 11 LED-current limitting resistor (UPDATED LECTURE)
Lecture 12 7 segment display (UPDATED LECTURE)
Lecture 13 IR LED
Lecture 14 Capacitor
Lecture 15 Bypass Capacitor (UPDATED LECTURE)
Lecture 16 Transistor as a switch
Lecture 17 IC chips
Lecture 18 Relay
Lecture 19 Transformer
Section 4: Introduction to Electronics: Circuit analysis techniques
Lecture 20 Circuit analysis techniques content
Lecture 21 Circuit analysis techniques
Section 5: Digital Electronics: Analog to Digital Converters
Lecture 22 Digital Vs. Analog Signals
Lecture 23 The Duty cycle
Lecture 24 ADC (analog to digital converter)
Lecture 25 1) Staircase ADC
Lecture 26 2) Flash ADC
Lecture 27 3) Pipeline ADC
Lecture 28 4) SAR ADC
Lecture 29 5) Delta-Sigma ADC
Section 6: Digital Electronics: Microprocessors and microcontrollers (Arduino)
Lecture 30 What are Microprocessors and microcontrollers ??
Lecture 31 What is arduino ??
Lecture 32 Types of Arduino boards
Lecture 33 Sitting up and start programming ( blink project )
Lecture 34 Using variables
Lecture 35 Using digital pins
Lecture 36 Using analog pins
Lecture 37 Serial monitor
Lecture 38 If statement
Lecture 39 For loop
Lecture 40 Dimmable LED
Lecture 41 ECG explaination
Lecture 42 ECG (Electrocardiogragh) a biomedical project using arduino
Section 7: Circuit Design and Analysis: Operational amplifiers and their applications
Lecture 43 Op amp introduction
Lecture 44 The characteristics of operational amplifier
Lecture 45 OP-AMP GAIN
Lecture 46 The Bandwidth of Operational Amplifier
Lecture 47 The Effect of Input-Offset Voltage on Output Voltage of Operational Amplifiers
Lecture 48 Feedback Equation and stability
Lecture 49 Cascade circuit of operational amplifier
Lecture 50 Some Examples on Op-Amp
Lecture 51 Introduction to Operational Amplifier Applications
Lecture 52 Understanding Comparators: Operation and Examples
Lecture 53 Summing Amplifiers: Combining Signals with Precision
Lecture 54 Summing amplifier (Digital to Analog Converter)
Lecture 55 Differential amplifier
Lecture 56 Low Pass Filters with Integrating Op-Amp: Signal Smoothing and Integration
Lecture 57 High Pass Filters with Differentiating Op-Amp: Signal Edge Detection and Differe
Section 8: Circuit Design and Analysis: Filters and their design
Lecture 58 what are filters ? and there types
Lecture 59 Low-Pass Filters
Lecture 60 High-Pass Filters
Lecture 61 Band-Pass Filters
Lecture 62 Band-Stop Filters (Notch Filters)
Section 9: Simple Biomedical project based on previous lectures
Lecture 63 Understanding working principles of heartbeat Sensor for the project
Lecture 64 Using proteus 8 pro in simulating and designing the circuits
Lecture 65 Designing the project and simulate it using proteus
Lecture 66 Using Breadboard in connecting the circuit
Section 10: Circuit Design and Analysis: Advanced circuit analysis techniques
Lecture 67 AC Analysis
Lecture 68 Transient Analysis
Lecture 69 AC Power Analysis
Lecture 70 Frequency Response
Section 11: Applications of Advanced Circuit Analysis in Biomedical Engineering
Lecture 71 Some Examples of Applications of Circuit Analysis in Biomedical Engineering
Section 12: Circuit Design and Analysis: Power supplies and voltage regulation
Lecture 72 Introduction to Power Supplies
Lecture 73 Types of Power Supplies
Lecture 74 Designing Simple Linear Power Supply Circuit
Lecture 75 Voltage Regulators and Their Types
Lecture 76 Designing the circuit of the switching regulator
Lecture 77 Medical Device Power Requirements & Considerations
Section 13: Biomedical Instrumentation
Lecture 78 Introduction to Biomedical Instrumentation
Lecture 79 Sensors and transducers used in medical devices
Lecture 80 Applications of Transducers in Biomedical Engineering
Lecture 81 Amplifiers and signal conditioning techniques for biomedical signals
Section 14: Electrodes and bioelectric signals (ECG, EEG, EMG, etc.)
Lecture 82 Sources of Biomedical Signals and Origin of Bioelectric Signals
Lecture 83 ECG & EEG
Lecture 84 EMG, EOG & ERG
Lecture 85 Electrode-Tissue Interface and Motion Artifacts in Biopotential Measurements
Lecture 86 Exploring Electrode Types and Innovations in ECG Monitoring
Lecture 87 Electrodes in Electrophysiological Recordings
Section 15: Medical Device Technology
Lecture 88 Overview of medical devices and their classifications
Lecture 89 Safety regulations and standards in medical device design
Lecture 90 A medical device design and development guide by Mindsailors
Section 16: Working principles of commonly used elecronic medical equipment
Lecture 91 ECG (Electrocardiogragh)
Lecture 92 Physiological Background about the heart
Lecture 93 Pulse Oximeter
Lecture 94 More about pulse oximetry
Lecture 95 Sphygmomanometer
Lecture 96 More about Sphygmomanometer
Lecture 97 Endoscope
Lecture 98 Defibrillator
Section 17: Introduction to electronic measurement tools
Lecture 99 Digital Multimeter (DMM)
Lecture 100 Oscilloscope
Lecture 101 Function Generator
Lecture 102 Logic Analyzer
Lecture 103 Spectrum Analyzer
Lecture 104 LCR Meter
Section 18: Troubleshooting and Repairing Medical Devices
Lecture 105 Introduction to troubleshooting methodologies
Lecture 106 Common issues in medical devices and their diagnosis
Lecture 107 Intro to PCB (Printed Circuit Board)
Lecture 108 What are PCBs ?? (Documentary)
Lecture 109 PCB ( Printed Circuit Board ) Explained
Lecture 110 Repairing techniques for electronic components and circuit boards
Section 19: Project Work
Lecture 111 Working Principle Of EMG
Lecture 112 The Circuit and the designing of the EMG
Electronics and Biomedical Engineering Students,Electronics Technicians,Innovators and Entrepreneurs,Electronics Enthusiasts,Anyone who has a passion for this field or wants to start working in this field of work,Beginner at electronic engineering want to combin electronics with biomedicine to develop new medical technologies.