A transformer is basically a primary inductor connected to a voltage $U_P$ which you want to transform. You also have an iron rod and a secondary inductor. So when there is a current $I_P$ the iron rods becomes magnetic. When you connect the primary inductor to AC, that means that you'll have a changing current, which causes a change in flux which causes induction. My question is, is $U_S$ just the induction voltage created by the iron rod?
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It's always handy to have some background information: In Europe the mains voltage is 230 Volts, which is too much for a lamp for example, so it needs to be lowered to for example 12 Volts. This is done by using a transformer. The primary winding is connected to the mains voltage of 230 Volts. The AC in this primary winding causes a varying magnetic flux in the iron rod (core) which on its turn creates a varying magnetic flux through the secondary winding. Because of electromagnetic induction a voltage is induced in the secondary winding. The primary winding has more turns than the secondary winding which causes the secondary voltage to be lower than the primary voltage: $$ \dfrac{N_P}{N_S} = \dfrac{U_P}{U_S} = \dfrac {I_S}{I_P}$$ You can see that be decreasing/increasing the number of turns in the windings you can control the voltage created by electromagnetic induction. Here is an illustration with an example ($U_S = 220V, U_P = 110 V$)
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You can see how simple it really is. 
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According to ATL Transformers Ltd:
The referenced article discusses Faraday's law The Wikipedia article on magnetic core says
(my emphasis) There's a useful looking article on this subject by a Dr A.M. Etamaly |
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