Really is the best in the topic. May also explain why we are treating scalars as vectors to complete the picture. Would make a bench mark on the topic.
A brit here 🇬🇧.. watching all your videos for my exam they're so helpful mate I appreciate them so much.. one question, how come E is used over V for voltage (is it EMF) ? We use V over here 👍
Great video Dave, like the rest of them. Maybe worth pointing out for some viewers that in both cases (the series RL case and parallel RL case) , the total voltage leads the total current (despite the triangles pointing in opposite directions). So the source/supply 'sees' a net load with leading power factor in both types of RL circuits (or lagging power factor depending on your convention - considering the current lags behind the voltage).
Dave mate, absolutely stellar videos. clear concise information and you fill in all of the knowledge gaps where most youtubers fall short.
These little details are very difficult to find in most videos on youtube. Very good!
Your videos are helping me study for my apprenticeship, appreciate you posting them
Sir you have done it with very easy ways thank you so much 💓 💗 💕 😊
Amazing reference to walking across a lawn at home and Pythagoras! Going to use this example 100% when explaining
This is very clear and to point superb explanation
Really is the best in the topic. May also explain why we are treating scalars as vectors to complete the picture. Would make a bench mark on the topic.
A brit here 🇬🇧.. watching all your videos for my exam they're so helpful mate I appreciate them so much.. one question, how come E is used over V for voltage (is it EMF) ? We use V over here 👍
Great video Dave, like the rest of them. Maybe worth pointing out for some viewers that in both cases (the series RL case and parallel RL case) , the total voltage leads the total current (despite the triangles pointing in opposite directions). So the source/supply 'sees' a net load with leading power factor in both types of RL circuits (or lagging power factor depending on your convention - considering the current lags behind the voltage).
Great explanation there Dave.
🙏🙏🙏🙏👏👏👏👏👏
Tremendous video
Thanks sir 👏👏👏👏👏
Well explained
thank you sir