For beginners, the easiest way to understand is to begin with simple explanations and pictures of basic parts like resistors, capacitors, diodes, and transistors.
Even though it might seem hard at first, once you understand how they work and what they're used for, it becomes easier to understand.
How can beginners quickly understand the basics of electronic components?
Start learning from the basics of the basics learn about leds, resistors capacitors and transistors, some YouTube tutorials like electroboom or via using picture tutorials and learning websites which gives you 3d animations.
In the beginning it may look difficult but if you have interest then it becomes easy and fun as you get used to the fun procces
In the beginning it may look difficult but if you have interest then it becomes easy and fun as you get used to the fun procces
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napesanerd
- Posts: 3
- Joined: Mon Jul 01, 2024 10:00 pm
Have Some Interest: Start with a genuine curiosity about how things work and a passion for tinkering.
Dream About Some Projects: Let your imagination run wild. Think about cool projects you could build, like *insert complex project*.
Think About the Hardest Thing You Can Make: Challenge yourself by imagining the most complex project you can think of.
Understand You Can't Make That (Yet): Accept that your skills and knowledge might not be at the level required for such ambitious projects just yet.
Think of a Simpler Thing: Scale back your ambitions and choose a more manageable project to start with.
TRY to Make It: Dive in and start building. This is how the journey begins. You'll learn a lot by doing, even if it doesn't work perfectly the first time.
Dive Deeper into Learning: As electronics captivate your interest, dedicate time to learning the basics. Read foundational books like "The Basics of Electronics" and move on to more advanced ones like "The Art of Electronics."
Start with Specialized Books: Once you're comfortable with the basics, explore more specialized topics in electronics.
Feel Like You Can Make Anything: With time and practice, you'll gain the confidence to tackle more complex projects. You'll reach a point where you feel capable of building anything you set your mind to.
These steps are structured this way because most hobbyists didn't begin their journey due to school curriculums. Instead, their passion was ignited by random sparks, like their dad's job, a random bird, or a cool YouTube video. These sparks can quickly burn out, so the first steps are about maintaining a stable flame of passion. This initial interest helps build a foundation, making it easier to dive deeper and tackle more complex projects over time.
Dream About Some Projects: Let your imagination run wild. Think about cool projects you could build, like *insert complex project*.
Think About the Hardest Thing You Can Make: Challenge yourself by imagining the most complex project you can think of.
Understand You Can't Make That (Yet): Accept that your skills and knowledge might not be at the level required for such ambitious projects just yet.
Think of a Simpler Thing: Scale back your ambitions and choose a more manageable project to start with.
TRY to Make It: Dive in and start building. This is how the journey begins. You'll learn a lot by doing, even if it doesn't work perfectly the first time.
Dive Deeper into Learning: As electronics captivate your interest, dedicate time to learning the basics. Read foundational books like "The Basics of Electronics" and move on to more advanced ones like "The Art of Electronics."
Start with Specialized Books: Once you're comfortable with the basics, explore more specialized topics in electronics.
Feel Like You Can Make Anything: With time and practice, you'll gain the confidence to tackle more complex projects. You'll reach a point where you feel capable of building anything you set your mind to.
These steps are structured this way because most hobbyists didn't begin their journey due to school curriculums. Instead, their passion was ignited by random sparks, like their dad's job, a random bird, or a cool YouTube video. These sparks can quickly burn out, so the first steps are about maintaining a stable flame of passion. This initial interest helps build a foundation, making it easier to dive deeper and tackle more complex projects over time.
For beginners, the easiest way to understand basic electronic components is with Arduino!
Ever wanted to bring your electronic ideas to life? Then Arduino is for you! Here's how to get started:
Dive into Arduino: First, head to Google and search for "Arduino board." This open-source platform makes electronics accessible to everyone. it's totally worth the investment.
Explore Project Ideas: Once you have your Arduino, browse online for "Arduino projects." Start with something simple, like a push-button LED circuit that turns the light on and off. This will help you get familiar with the basic functionalities.
Follow Your Passions: Now that you've gotten your feet wet, let your interests guide you! Do you dream of building an RC car? Research the components you'll need and don't hesitate to search online for anything you're unsure about. There are tons of resources available!
Plan and Build: The key to success is planning your project step-by-step. What exactly do you want to create with electronics? Sketch out a plan and gather your materials.
Embrace the Journey: The beauty of Arduino is that it fuels creativity. By following your interests and passions, you'll unlock a world of possibilities. Remember, there's no shame in getting stuck. The online Arduino community is vast and supportive, so don't be afraid to ask questions! you can also ask any questions here.
Bonus Tip: There are also starter kits available that include an Arduino board, various electronic components, and a project guide. This can be a great way to get started quickly! also check out the website "robu.in"
Ever wanted to bring your electronic ideas to life? Then Arduino is for you! Here's how to get started:
Dive into Arduino: First, head to Google and search for "Arduino board." This open-source platform makes electronics accessible to everyone. it's totally worth the investment.
Explore Project Ideas: Once you have your Arduino, browse online for "Arduino projects." Start with something simple, like a push-button LED circuit that turns the light on and off. This will help you get familiar with the basic functionalities.
Follow Your Passions: Now that you've gotten your feet wet, let your interests guide you! Do you dream of building an RC car? Research the components you'll need and don't hesitate to search online for anything you're unsure about. There are tons of resources available!
Plan and Build: The key to success is planning your project step-by-step. What exactly do you want to create with electronics? Sketch out a plan and gather your materials.
Embrace the Journey: The beauty of Arduino is that it fuels creativity. By following your interests and passions, you'll unlock a world of possibilities. Remember, there's no shame in getting stuck. The online Arduino community is vast and supportive, so don't be afraid to ask questions! you can also ask any questions here.
Bonus Tip: There are also starter kits available that include an Arduino board, various electronic components, and a project guide. This can be a great way to get started quickly! also check out the website "robu.in"
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awesumtech
- Posts: 2
- Joined: Tue Jul 09, 2024 12:58 am
The best books for electronics, I found, are those by Albert Paul Malvino. "Semiconductor circuits approximations" is one of his finest. After learning the basics, I believe Arduino is the best platform to experiment on. Being old school, I learned from books but today I believe, there are tons of online videos to learn from. Best Wishes.
Regards,
Sunil Gokhale
Regards,
Sunil Gokhale
If you want to persue a career in electronics, one should have basic knowledge of how the energy actually works, overall he/should be very familiar with the fundamental laws, these laws will not only help you but also provide you a wide vision, which other engineers are wont able to think off, Here are some concepts which you must know conservation laws.
Kirchoff’s two laws are really just practical examples of the conservation of energy. The current must be the same in a series loop because it can’t leak out or get in from elsewhere. Because of conservation. Voltages have to sum to the external total, because where else can they come from? Thermodynamics prevents the universe topping things up from behind your back.
The shaft output of a motor, in kW will always be less than the electrical input - because of the 2nd law of thermodynamics. Similarly the electrical output of a generator must be less than the mechanical input. Because of conservation.
Then you need to remember Joule Heating.
You pass a current through something, it creates heat ignore superconductors - they are so far from “basic” as to be almost non-existent.). You will spend 90% of your life as an engineer trying to minimise the waste heat.
Then basic maths. The triangle functions, simple integration and differentiation.
Sines and cosines crop up all the time, because AC circuits are all some sort of offspring of something going round in a circle while you look at it side on. Tangents are just the ratio between the sine and the cosine, so they pop up from time to time.
Energy is power integrated over time. It is the area under a graph of energy consumption. If the power is constant, that simplifies to Joules = Watts x Seconds. Integrals are everywhere.
edge detection = differentiation. Smoothing = integration.
Get as far as Fourier Transforms. every periodic waveform is the sum of a fundamental (sine wave) and a number of harmonics (sine waves) of varying relative amplitude and phase. An impulse is a Dirac spike. a collection of high frequency signals going to infinity.
Learn about transfer functions.
How the input and output voltages and currents of things are related. Load lines, gain-bandwidth products, phase shifts, linearity and non linearity.
Read all of the definitions of things.
Ohms law, for example says the the slope of the voltage/current relationship is constant. Yes? this is our famous formula R=V/I, yes? No. It says that the slope of the voltage current relationship in a metallic conductor is constant at constant temperature. The relationship of V/I in a cold tungsten light bulb appears very different from that when it is hot, so teachers tell us that tungsten light bulbs are non-ohmic. The slope varies. That’s bollocks. Complete nonsense. At any particular temperature, tungsten has a very nice flat slope, and Ohm’s law works perfectly well. So for a hot one, if you make the change in voltage small enough that the change in current won’t affect the temperature - it is Ohmic.
Continue if I have left something.
Kirchoff’s two laws are really just practical examples of the conservation of energy. The current must be the same in a series loop because it can’t leak out or get in from elsewhere. Because of conservation. Voltages have to sum to the external total, because where else can they come from? Thermodynamics prevents the universe topping things up from behind your back.
The shaft output of a motor, in kW will always be less than the electrical input - because of the 2nd law of thermodynamics. Similarly the electrical output of a generator must be less than the mechanical input. Because of conservation.
Then you need to remember Joule Heating.
You pass a current through something, it creates heat ignore superconductors - they are so far from “basic” as to be almost non-existent.). You will spend 90% of your life as an engineer trying to minimise the waste heat.
Then basic maths. The triangle functions, simple integration and differentiation.
Sines and cosines crop up all the time, because AC circuits are all some sort of offspring of something going round in a circle while you look at it side on. Tangents are just the ratio between the sine and the cosine, so they pop up from time to time.
Energy is power integrated over time. It is the area under a graph of energy consumption. If the power is constant, that simplifies to Joules = Watts x Seconds. Integrals are everywhere.
edge detection = differentiation. Smoothing = integration.
Get as far as Fourier Transforms. every periodic waveform is the sum of a fundamental (sine wave) and a number of harmonics (sine waves) of varying relative amplitude and phase. An impulse is a Dirac spike. a collection of high frequency signals going to infinity.
Learn about transfer functions.
How the input and output voltages and currents of things are related. Load lines, gain-bandwidth products, phase shifts, linearity and non linearity.
Read all of the definitions of things.
Ohms law, for example says the the slope of the voltage/current relationship is constant. Yes? this is our famous formula R=V/I, yes? No. It says that the slope of the voltage current relationship in a metallic conductor is constant at constant temperature. The relationship of V/I in a cold tungsten light bulb appears very different from that when it is hot, so teachers tell us that tungsten light bulbs are non-ohmic. The slope varies. That’s bollocks. Complete nonsense. At any particular temperature, tungsten has a very nice flat slope, and Ohm’s law works perfectly well. So for a hot one, if you make the change in voltage small enough that the change in current won’t affect the temperature - it is Ohmic.
Continue if I have left something.
Hey! For beginners, the best way to understand the basics of electronic components is to start with simple educational materials. I recommend starting with LEDs, resistors, and capacitors. You can also use YouTube videos that show how these components work in practice.
Additionally, getting an Arduino starter kit is a great way to learn through fun while immediately implementing your ideas. The more you experiment, the better you'll understand how different components work!
Additionally, getting an Arduino starter kit is a great way to learn through fun while immediately implementing your ideas. The more you experiment, the better you'll understand how different components work!