please explain and include Lenz's ,Maxwell's , and Faraday's laws so that i can link the whole idea;
i really appreciate any help.
i really appreciate any help.
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Now that you know these laws as you stated, it is best to study these sets of equations:particularly the 'quad' of Maxwell's Equations. What everyone who comes across them, does it by looking at them repeatedly, contemplating& savouring them. Every time a new insight is brought out. these are broughtout clearer applying them to problems repeatedly. I can only write down the equations and state in so many English words. Depending upon the receptivity (that can't be ensured however sincere one is) the success of conveying knowledge is tramelled. Best is (like all of us did) to study them for one self. In that quest you might discover that you are weak in some other aspect (like inability to apply rules of integration; then build up that aspect, complete it & move on).
The scheme goes on somewhat like this, building up the conceptual base and parameters that are intermediaries. Electric field (E) and magnetic field (H) are interdependent. One can't have one only, without the other. Yet people fail to read this.It is so because, what one seemingly sees as Electric field alone obscures a very weak magnetic field. After a three decade rubbing with the subject it sat in my conscience as 'Impedance' that though started off as a routine, practical, workmen-like definition; is the ratio, E/H. A high impedance circuit is high in E while a low impedance one (most electric wires are)kicks off a kind of magnetic disturbance, though it may not administer much of an electric shock to you. In practical terms it is the ratio, √[V/I] or square root of voltage(Volts) to current in Amperes. In microwave circuits one can't use a Voltmeter or Ammeter to read off Volts or Amperes. So we change the strategy, parameters and geometry to impedance. I found that the concept of Impedance works well and is an aid in kindred fields like Optics. With my grounding in Maxwell's equations, I found that I have a better understanding of Optical phenomena that otherwise was unexplainable (I dabbled for a considerable length of time in Acousto-Optic linkage & devices).
The scheme goes on somewhat like this, building up the conceptual base and parameters that are intermediaries. Electric field (E) and magnetic field (H) are interdependent. One can't have one only, without the other. Yet people fail to read this.It is so because, what one seemingly sees as Electric field alone obscures a very weak magnetic field. After a three decade rubbing with the subject it sat in my conscience as 'Impedance' that though started off as a routine, practical, workmen-like definition; is the ratio, E/H. A high impedance circuit is high in E while a low impedance one (most electric wires are)kicks off a kind of magnetic disturbance, though it may not administer much of an electric shock to you. In practical terms it is the ratio, √[V/I] or square root of voltage(Volts) to current in Amperes. In microwave circuits one can't use a Voltmeter or Ammeter to read off Volts or Amperes. So we change the strategy, parameters and geometry to impedance. I found that the concept of Impedance works well and is an aid in kindred fields like Optics. With my grounding in Maxwell's equations, I found that I have a better understanding of Optical phenomena that otherwise was unexplainable (I dabbled for a considerable length of time in Acousto-Optic linkage & devices).
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