🪴 Quartz 4.0
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Bode Plot
Change Variables in an Integral ('Change of Basis')
Create Automatic Subtitles (Using 'RASMUS')
Create Automatic Subtitles (Using 'replicate')
Definition of Average in the Integral Sense
Nabla Operand • Gradient • Divergence • Curl • Laplacian
SaM - 2 Wires Measurement with Wire Resisitances
SaM - 4 Wires Measurement with Wire Resisitances
SaM - 5 Wires LVDT (Linear Variable Differential Transformer)
SaM - Absorption for Ultrasonic Beams
SaM - AC-Coupled Amplifier
SaM - Accelerometer
SaM - Accuracy of the Complete Measurement System
SaM - Accuracy or Maximum Error
SaM - Acustic Impedance • Ultrasonic Lumped Parameter System
SaM - Alternative to Piezoelectric Arrays for Ultrasonic Beams
SaM - AM (Amplitude Modulation) Based on Oscillators
SaM - AM Modulation with 2 Sensors • Carrier Amplifier
SaM - Amplifiers
SaM - Anemometry or Hot Wire
SaM - Anisotropic Magneto Resistance (AMR) • Easy Axis • Barber Pole • Honeywell
SaM - AT-Cut Quartz
SaM - Atomic Bond Types
SaM - Band Structures of Different Materials
SaM - Barkhausen Conditions
SaM - Base Knwoledge on Sensors
SaM - Behavior of the Quartz Ocillator at High Frequencies
SaM - Behaviour of Semiconductors at Different Temperatures
SaM - Bode Plot of a first order ODE
SaM - Burdón Tubes
SaM - Calendar Van Dusen Equation
SaM - Calibration
SaM - Capacitive (Ferroelectric) Temperature Sensor
SaM - Capacitive Accelerometer
SaM - Capacitive Displacement Sensors
SaM - Capacitive Humidity Sensor
SaM - Capacitive Level Sensor
SaM - Capacitive Proximity Sensors
SaM - Capacitive Sensors
SaM - Capacitive Ultrasonic Transducers • CMUT Probes
SaM - Carrier Amplifier
SaM - Characteristics of a Sensor
SaM - Characteristics of Different Kinds of LVDTs
SaM - Charge Amplifier
SaM - Charge Output Accelerometer
SaM - Chemical Resistive Sensor
SaM - Classical Band Gap Based Temperature Sensor (2 Pins)
SaM - Classical Band Gap Based Temperature Sensor (3 Pins)
SaM - CMRR (Common Mode Rejection Ratio)
SaM - CMRR • Calculation of the CMRR (Stage II) based on Resistance Tollerances
SaM - CMRR • Calculation of the CMRR for the First Stage of an Instrumentational Amplifier
SaM - CMRR • Calculation of the CMRR for the Second Stage of an Instrumentational Amplifier
SaM - CMRR • Definition of Stages of an Instrumentational Amplifier
SaM - CMRR • Design Rules for Resistance Values of an Instrumentational Amplifier
SaM - CMRR • Why We Need a Good Differential Amplifier
SaM - CMRR due to the Circuit Topology
SaM - Coarse Approximation of the Lumped Parameter Model of an Ultrasonic Transducer
SaM - Coaxial Cable
SaM - Cold Junction for Thermocouples
SaM - Collapsed Piezoresistive Coefficient Tensor for Silicon
SaM - Collapsed Stiffness Tensor for Isotropic Materials
SaM - Compact Piezoelectric Coefficient Matrix for PZT • Dependence of Piezoelectricity on Temperature • Curie Temperature
SaM - Complete AM (Amplitude Modulation) Circuit
SaM - Complete Piezoelectric Device (Actuator + Sensor)
SaM - Complex Electric Permittivity
SaM - Conductivity and Mobility of Intrisinc Silicon
SaM - Continuity Equation for Charge Carriers
SaM - Control of an Ultrasonic Beam
SaM - Coupling with the Environment (and Solution)
SaM - Crystallographic Axis
SaM - Current Amplifier
SaM - Current Mirror
SaM - Definition of a Resistive Bridge • Balanced Bridge • Thevenim Equivalent of the Resisitive Bridge
SaM - Definition of CMRR (Common Mode Rejection Ratio)
SaM - Definition of Doping
SaM - Definition of Isotropic and Anisotropic Materials
SaM - Definition of Primary Sensor
SaM - Definition of RTD Sensors • Resistive Temperatrure Detector Sensors • TCR (Temperature Coefficient of Resitance)
SaM - Definition of Stress and Strain • Definition of Strain and Stress • Stress Vector • Strain Vector
SaM - Definition of Thermistor
SaM - Defintion of Thermocouples • Law of Thermocouples • Types of Thermocouples • Extension Wires
SaM - Deformable Structures
SaM - Dependence of the Fermi Energy on Temperature
SaM - Dependency of the Piezoresistance Factor on the Concentration of Dopants
SaM - Design of a Resistive Bridge
SaM - Dielectric Materials
SaM - Differences Between Grounded and Un-grounded Capacitive Sensors
SaM - Different Definitions for Preassure
SaM - Different Solutions for Contactless Probes • Inductive Senors vs. Capacitive Sensors
SaM - Different Types of Temperature Sensors
SaM - Differential Amplifier
SaM - Doping of Silicon
SaM - Doppler Effect for Primary Sensors
SaM - Drift Current • Current Density Equation
SaM - Driven Shields or Tri-Axial Cable
SaM - Echo Mode • Calculation of the Dead Zone
SaM - Echo Mode for Ultrasonic Beams
SaM - Eddy Currents • Eddy Probe
SaM - Elastic Waves and Acustic Waves • Calculation of the Wave Equation
SaM - Electric Condution
SaM - Electric Permittivity • Electric Susceptibility • Electric Field
SaM - Electrical Noise
SaM - Electrostatics
SaM - End Point Linear Approximation & Linear Regression
SaM - Fan or Turbine
SaM - Fast Recap on BJT • Bipolar Junction Transistor
SaM - Fermi Dirac Distribution
SaM - Field Band of Silicon • Energy Gap, Valence Band, Conduction Band
SaM - Final Value Theorem and Steady State Response
SaM - First Order System
SaM - FM (Frequency Modulation) Based on Oscillators
SaM - FM & AM Oscillators (OLD)
SaM - Focused Transducer for Ultrasonic Beams
SaM - Front End Electronics Strategies
SaM - Front End for an Eddy Probe
SaM - Front-End Electronics • Read-Out Electronics
SaM - Full Bridge
SaM - Generic Ultrasonic Wave Function • Longitudinal and Transvers Propagation Velocities of an Ultrasonic Wave
SaM - Geometrical Magneto Resistance
SaM - Gyroscope
SaM - Half Bridge • Calculation for the Maximum Sensitivity of a Resistive Bridge
SaM - Hall Sensor
SaM - Heat Conduction • Thermal Resistance
SaM - Heat Convection • Thermal Resistance
SaM - Heat Stored in a Body • Thermal Capacitance
SaM - High Frequency (AC) Signals
SaM - High Frequency Oscillator • 3 Point Oscillator • Colpits and Hartley Oscillators
SaM - Higher Order Systems
SaM - Hole
SaM - Hooke's Law • Collapsed Yieldness Tensor for Isotropic Materials
SaM - Ideal Linear Sensor
SaM - Inductive Proximity Sensor
SaM - Inductive Sensors
SaM - Influence of the Source Geometry on the Ultrasonic Filed Shape-Type
SaM - Instrinsic Semiconductor • Density of Carriers • Energy Gap and Carriers Dependance on Temperature
SaM - Instrumentational Amplifier
SaM - Integrator Circuit
SaM - Introduction to Oscillators
SaM - Introduction to Ultrasounds
SaM - Inverting Operational Amplifier
SaM - Ivan's Notes
SaM - Lecture 0
SaM - Lecture 1
SaM - Lecture 2
SaM - Lecture 3
SaM - Lecture 4
SaM - Lecture 5
SaM - Lecture 6
SaM - Lecture 7
SaM - Lecture 8
SaM - Lecture 9
SaM - Lecture 10
SaM - Lecture 11
SaM - Lecture 12
SaM - Lecture 12_02 • CMRR • Calculations
SaM - Lecture 12_03 • CMRR • Calculations
SaM - Lecture 13
SaM - Lecture 14
SaM - Lecture 15
SaM - Lecture 16
SaM - Lecture 17
SaM - Lecture 18
SaM - Lecture 19
SaM - Lecture 20
SaM - Lecture 21
SaM - Linear Scanning for Ultrasonic Beams
SaM - Linearized Sensors for a Small Range
SaM - Liquid Columns
SaM - Load Cells or Pillar
SaM - Logarithmic Amplifier
SaM - Longitudinal Waves or Compressive Waves
SaM - Low Pass Filter
SaM - LTI System
SaM - Lumped Parameter Systems
SaM - LVDT Sensor (Linear Variable Differential Transformer) • Transformers • Magnetic Induction
SaM - Magnetic Lumped Parameter System • Electro-Motive Force • Variable Reluctance
SaM - Magnetic Permeability • Magnetic Susceptibility • Magnetic Field
SaM - Magnetism
SaM - Magneto Resitances
SaM - Mass Action Law
SaM - Matching Layer for Acustic Impedance
SaM - Math Recap
SaM - Measurements & Measurement Types for Ultrasonic Beams
SaM - Mechanical Lumped Parameter System
SaM - MEMORIZE (Amplifiers)
SaM - MEMORIZE (Base Knwoledge on Sensors)
SaM - MEMORIZE (Capacitive Sensors)
SaM - MEMORIZE (CMRR)
SaM - MEMORIZE (Electrostatics)
SaM - MEMORIZE (Front-End Electronics • Read-Out Electronics)
SaM - MEMORIZE (Inductive Sensors)
SaM - MEMORIZE (Lumped Parameter Systems)
SaM - MEMORIZE (Magnetism)
SaM - MEMORIZE (Oscillators)
SaM - MEMORIZE (Piezoelectricity)
SaM - MEMORIZE (Piezoresisitivity)
SaM - MEMORIZE (Primary Sensors)
SaM - MEMORIZE (Problems and Possible Solutions)
SaM - MEMORIZE (Resistive Bridge • Wheatstone)
SaM - MEMORIZE (Resistive Sensors)
SaM - MEMORIZE (RTD Sensor)
SaM - MEMORIZE (Stress and Strain • Strain and Stress)
SaM - MEMORIZE (Temperature Sensors)
SaM - MEMORIZE (Thermistor)
SaM - MEMORIZE (Thermocouple)
SaM - MEMORIZE (Ultrasonic Beams)
SaM - MEMORIZE (Ultrasonic Waves)
SaM - MEMS Cantilever
SaM - MEMS Capacitive Pressure Sensor
SaM - MEMS Membranes
SaM - Metal Strain Gauge • Passive Strain Sensor
SaM - Microstructure of Solids
SaM - Modes Related to Conjugate Poles
SaM - MOSFET
SaM - No Distortion Conditions
SaM - Non-Ideal Operational Amplifier • Input and Output Resistances
SaM - Non-Ideal Operational Amplifier • OZE (Out of Zero Error) • Special Kinds of Operational Amplifiers • Precision Amplifier • Low Noise • Low Input Bias Current • Zero Drift • Low Noise Operational Amplifier
SaM - Non-Idealities of an Accelerometer
SaM - Non-Inverting Operational Amplifier
SaM - Non-Linearity Error
SaM - ODE (Ordinary Differential Equation)
SaM - Ohm's Law
SaM - Operational Amplifier
SaM - Operational Amplifier as a Voltage Comparator
SaM - Orifices
SaM - Oscillators
SaM - Oscillators based on Wien Bridge
SaM - Passive Sensor
SaM - Pauli Principle
SaM - Phase Shift Oscillator
SaM - Photoresistance
SaM - Physical Dependencies of a Sensor
SaM - Physics and Chemistry Recap
SaM - Piezoelectric Accelerometer
SaM - Piezoelectric Coefficient Matrix for PZT
SaM - Piezoelectric Devices
SaM - Piezoelectric Effect
SaM - Piezoelectric Effect in Details • Direct and Inverse Piezoelectric Effect
SaM - Piezoelectricity
SaM - Piezoresistance of Doped Silicon • Doped Silicon as a Strain Gauge
SaM - Piezoresistivity
SaM - Piezoresistivity Effect
SaM - Piezoresistivity Effect in Details
SaM - Pitot Tube
SaM - Planar Waves or Plane Waves
SaM - Poles with Multiplicity Higher than 1
SaM - Potentiometer
SaM - Primary Sensor for Temperature
SaM - Primary Sensors
SaM - Printable Memory Cards - ZIP Folder
SaM - Problems and Possible Solutions
SaM - Pyroelectric Effect
SaM - Quartz as a Sensor • QCM (Quartz Crystal Microbalance)
SaM - Quartz in a 3 Point Oscillator
SaM - Quartz Oscillator
SaM - Readout Electronics for Capacitive Sensors (FM & AM Oscillators)
SaM - Recap of Basic Components • Resistance, Capacitance, Inductance • Resistivity, Permittivity, Permeability
SaM - Reduce the Effect of Self-Heating
SaM - Reflection of an Ultrasonic Wave
SaM - Remove the Offset in the Measurement System
SaM - Resistive Bridge • Wheatstone
SaM - Resistive Sensors
SaM - Resolution
SaM - Rise Time
SaM - RTD Example • Linearized Uncertainty
SaM - RTD Sensor
SaM - Scattering and Diffuse Reflection of an Ultrasonic Wave
SaM - Second Order System
SaM - Second Order System (OLD)
SaM - Self-Heating
SaM - Sensitivity
SaM - Sensor Linearization
SaM - Sensors Based on Silicon Junctions (BJT and Integrated Circuits)
SaM - Shields
SaM - Sigma-Delta Converter (AD Converter)
SaM - Simple Differential Amplifier (Made from an O.A.)
SaM - Single Input Amplifier
SaM - Slides on IC and MEMS
SaM - Special Materials for the Electric Permittivity • Paraelectric, Piezoelectric, Ferroelectric
SaM - Square Wave Oscillator
SaM - Stable Poles
SaM - Standing Waves
SaM - Steinhart-Hart Relashionship and Different Standard of Thermistor
SaM - Stress and Strain • Strain and Stress
SaM - Summary of the Calculation of CMRR for an Instrumentational Amplifier
SaM - Surface Defects & Grain Boundary Barriers
SaM - Switched Capacitors
SaM - Temperature Sensors
SaM - Thermal Activated Conductivity • Dependence of Conductivity on Temperature
SaM - Thermal Lumped Parameter System
SaM - Thermal Representation of a Thermocouple
SaM - Thermistor
SaM - Thermocouples
SaM - Thermocouples (Class I & II)
SaM - Thermopiles
SaM - Thevenim and Norton Equivalent
SaM - Time of Flight Principle for Primary Sensors
SaM - Traditional Sensors vs. MEMS • MEMS Technology
SaM - Transfer Funtion of a Mounted Accelerometer
SaM - Transmission Mode for Ultrasonic Beams • C-Mode Image
SaM - Transverse Waves or Shear Waves
SaM - Tri-axial Cable + Tri-axial Sensor
SaM - Triboelectric Noise
SaM - Types of Active Sensors
SaM - Types of Capacitive Sensors
SaM - Types of Cut Quartzes
SaM - Types of Magnetic Materials (Diamagnetic, Paramagnetic and Ferromagnetic Material)
SaM - Types of Magneto Resistances
SaM - Types of Primary Sensors
SaM - Types of Resistive Bridge Recap
SaM - Types of Sensor
SaM - Ultrasonic Beam Stearing
SaM - Ultrasonic Beams
SaM - Ultrasonic Transducers (Piezoelectric Device)
SaM - Ultrasonic Waves
SaM - Variable Transformers
SaM - Voltage Amplifier
SaM - Voltage Supply vs. Current Supply
SaM - VRS (Variable Reluctance Sensors)
SaM - Wavelength
SaM - Wire Resistance in a Resistive Bridge (2 and 3 Wires Layout)
SaM - Working Conditions of a Strain Gauge
SaM - Working Range & Safe Range
SaM - Young and Poisson Modulus
SaM ~ CMRR of a Simple Differential Amplifier
SaM ~ Complete Sensor • Accelerometer with a Resistive Bridge
SaM ~ Complete Sensor • Load Cell with a Resistive Bridge
SaM ~ Ex. Electro-Neutrality of an n-type Doped Silicon
SaM ~ Example of a Real Instrumentational Amplifier • INA128
SaM ~ Example of an Ultrasonic Wave Function • Sine Plane Wave
SaM ~ Example of Ultrasonic Beams
SaM ~ Examples of Capacitive Sensors
SaM ~ Half Bridge Example • Two Strain Gauges
SaM ~ Real World Example • Propagation of an Ultrasonic Wave in Different Materials
SaM ~ Real World Example • Standard RTD Sensor • PT100 Sensor
SaM ~ Real World Example • Ultrasonic Sensors
SaM ~ Real World Example of a Classical Band Gap Based Temperature Sensor
SaM ~ Real Worlds Example • Table of Piezoresistive Coefficients Values
SaM ~ Resistive Bridge Example • Strain Gauge
SaM ~ Solution Based on a Resistive Bridge and an RTD
SaM ~ Vibration Measurement Based on Strain Gauge
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SaM - Pyroelectric Effect
SaM - Pyroelectric Effect
Jul 31, 2024
0 min read
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Backlinks
SaM - Electrostatics
SaM - Lecture 8
SaM - Special Materials for the Electric Permittivity • Paraelectric, Piezoelectric, Ferroelectric
