In this video, what is a real-time clock, how it works, the basic architecture of RTC, and its applications are explained. Along with that, the different temperature compensation techniques that are used in the RTC is also explained. The following topics are covered in the video: 0:00 What is Real Time Clock 0:57 Applications of Real Time Clock 2:47 What is inside RTC? How RTC work? 8:55 Temperature Compensation Techniques Used in RTCs 15:25 Some additional features in modern RTCs What is Real Time Clock? The Real Time Clock is an electronic circuit that keeps track of the time in human-readable format and it tracks the time even when there is a power failure or the power supply goes off. Applications of RTC: 1) Smartphones 2) Personal Computers 3) IOT devices 4) Smart Meters 5) Embedded Systems 6) Servers The link for the other useful videos: 1) How Fast Charging Works in Smartphones? https://youtu.be/dyCoYGNiQPA?si=XTLdy... 2) What is Li-Fi? How it works? https://youtu.be/Cd8G9d-Begs?si=o5eEj... 3) Image Sensors Explained: CCD vs CMOS Sensors https://youtu.be/FKJFIzDfUNE?si=4zMvq... This video will be helpful to all the students of science and engineering in understanding what is Real Time Clock, how it works, and what are the application of Real Time Clock. #ALLABOUTELECTRONICS #realtimeclock #embeddedsystem #microcontroller Support the channel through membership program: https://www.youtube.com/channel/UCBkO... -------------------------------------------------------------------------------------------------- Follow my second channel: https://www.youtube.com/channel/UCGA2... Follow me on WhatsApp channel: https://www.whatsapp.com/channel/0029... Follow me on Facebook: https://www.facebook.com/ALLABOUTELEC... Follow me on Instagram: https://www.instagram.com/all_about.e... -------------------------------------------------------------------------------------------------- Music Credit: http://www.bensound.com
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The playlist covers the following topics in the Digital Electronics. 1. Number System (Binary, Octal, Decimal, Hexadecimal Number System) 2. 1s and 2's Complement Representation 3. Binary Addition and Subtraction, Multiplication and Division 4. Logic Gates 5. Boolean Algebra 6. Adder and Subtractor 7. Binary Multiplier and Divisor Circuits 8. Parity Generator and Checker Circuits 9. K-map and Solved Examples 10. Multiplexer and Demultiplexer 11. Encoder and Decoder 12. Latch and Flip-flops 13. Analog to Digital Converter (ADC) 14. Digital to Analog Converter (DAC) 15. Shift Registers 16. Asynchronous Counters 17. Synchronous Counters 18. Finite State Machine (FSM) 19. Serial Adder, Serial Multiplier 20. Semiconductor Memories (RAM, ROM) 21. Programmable Logic Devices (PROM, PAL,PLA etc.)
This playlist covers the various topics of analog electronics and the related solved examples. The following topics are covered in this playlist. 1) PN junction diode 2) Diode based Circuits 3) Zener Diode as Voltage Regulator 4) Half wave and Full wave Rectifier 5) Clipper and Clamper Circuits 6) Varactor Diode 7) Bipolar Junction Transistor (BJT) Basics 8) Common Emitter, Common Base and Common Collector Configuration of BJT 9) Transistor Biasing 10) BJT as a Switch 11) Different Biasing Configurations of BJT (Voltage Divider, Collector Feedback, etc) 12) BJT Small Signal Analysis 13) Other BJT Circuits (Darlington Amplifier, Current Mirror, Differential Amplifier) 14) JFET and MOSFET 15) JFET and MOSFET biasing 16) MOSFET Small Signal Analysis 17) MOSFET Circuits (Current Mirror, Cascode Amplifier, Differential Amplifier) 18) Operational Amplifier (Op-Amp) 19) Op-Amp Parameters (Slew Rate, Gain Bandwidth Product, Offset Voltage etc) 20) Other Op-Amp based Circuits (Precision Rectifier, Peak Detector etc) 21) Analog Filters (Low Pass, High Pass, Band Pass Filters) 22) Oscillator and Multivibrators 23) 555 Timer and Timer based Circuits 24) Phase Lock Loop (PLL)
The Course covers the following topics on network analysis/ Network Theory 1. Basic Concept of Voltage, Current and Power 2. Basic Circuit elements (Resistor, Capacitor and Inductor) 3. Concept of Loop, Mesh, Node and Branch in the circuit analysis 4. Nodal and Mesh Analysis Techniques 5. Concept of Super node and Super mesh 7. Network Theorems (Thevenin's Theorem, Superposition Theorem, Maximum Power Transfer Theorem, Norton's Theorem etc) 8. Series and Parallel Resonance 9. Concept of Phasors and Phasor Diagram 10. Sinusoidal Steady State Analysis 11. Transient Analysis of RL, RC and RLC Circuits 12. Laplace Transform and Circuit Analysis using Laplace Transform 13. Magnetically Coupled Circuits

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