Como funciona una resistencia eléctrica ⚡ que es una resistencia eléctrica

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it is likely that they have ever seen a resistor like this in a circuit

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or even in a heater

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but how does a resistor works internally?

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first we must clarify the concept of electricity

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and for this we are going to use this piece of cable

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this cable has electrons, which are sub-atomic particles of negative charge

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and that they can move freely.

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when a potential difference or voltage is applied between the two ends of the cable

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the electrons are forced to move

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and it is to this movement that it is known as electric current.

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however, even though the electrons can move through the wire,

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not everything is so easy

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there is a resistance that Opposes the flow of electrons

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this is: the electrical resistance, and its unit of measurement is the Ohm.

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In fact, since our own body is capable of conducting electricity

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We could say that we ARE a resistor,

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and even that in these two circuits the resistance is equivalent

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but clearly one of the two options is more viable to implement.

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One of the main differences is that each one has a coefficient of resistance

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determined by the material of which they are made

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in fact, there are multiple classifications depending on this coefficient of resistance

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If a material has a low coefficient of resistance

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it is said that this is a conductor, such as copper or gold.

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On the contrary, if its coefficient is higher, it is said to be an insulating material

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such as glass or plastic

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but there are also materials with intermediate values, and these are known as semiconductors,

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which, in some cases, vary their conductivity depending on other external factors

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as we saw in the previous video about diodes.

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and finally, although they are an extreme case,

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there are also superconductor materials

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which when they are below a certain temperature

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decrease their coefficient of resistance drastically

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we now know roughly how the coefficient of resistance affects the behavior of the material

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And if one day we find two cables of exactly the same dimensions

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but made of different materials, such as: one copper and one iron.

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after having seen a table like this, we could say with complete certainty

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that the resistance of the iron cable is greater.

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but, we could not say what is the value of the resistance of any of the two cables

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because only that information is not enough to know.

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let's focus on the cable copper.

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The resistance of this cable will be equal to the coefficient of resistance

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multiplied by the length of the cable and divided by the area of ​​its cross section

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let's make some analogies to understand more easily how each variable affects.

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let's imagine that this cable is a pipe

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to which we will add two tanks, one filled with particles that represent the electrons

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and an empty one, to also represent the potential difference or voltage that will be applied to the cable,

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when we close the circuit and let the current pass

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we can see how the particles pass without problems towards the other tank

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this, because copper has a fairly low resistivity coefficient

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Now, if we change the copper for another material like iron

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the pipe will have obstacles inside, in this way, when we let the current pass,

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it will be more difficult, but not impossible it reaches the other end.

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that is, it will have a greater resistance.

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having an insulating material would be like having the pipe completely covered

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the next two variables are easier to understand

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if we have a greater distance to travel in the pipeline

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it is logical that more time and effort is required to get to the other extreme

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that is, the longer the cable, the greater the resistance.

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On the other hand, if we increase the diameter of the pipe,

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even when the resistivity coefficient continues to affect the entire volume

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There are going to be more possible ways for electrons to pass.

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in other words, the greater the cross-sectional area of ​​the cable

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there is less resistance to the passage of the current.

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Now let's go back to the real version before my computer melts by doing these simulations.

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although this formula is usually used for its simplicity

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you should know that the temperature can also affect the value of a resistance

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since the coefficient of resistivity you find in the tables like this

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specify the temperature at which that value is correct.

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although most metals increase their resistivity coefficient by increasing their temperature

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this is not true for all materials

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It's important to mention that in reality

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almost never will have only one cable between the two poles of a power source

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as this could generate a short circuit,

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that is, a sudden increase in the amount of current that passes through the conductor

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I say almost, because when you want generate heat, as for example in a heater,

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basically that is what is done.

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To this phenomenon by which a conductor emits heat when a current passes through the

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It is known as the Joule effect.

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and we can calculate the energy dissipated in the form of heat

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as the multiplication between the voltage applied to the driver

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the intensity of the electrical current that is happening

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and the time during which this occurs.

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The limitation of doing this is that the material could be melted

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or oxidize extremely fast, leaving it unusable

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That is why for such cases, alloys such as Nichrome are usually used

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which, in the first place, has a melting point of 1400 ° C

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and also has a high coefficient of resistance

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this last characteristic is precisely the reason why only that section is heated

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and not the cable that we plugged in.

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going back to the main topic.

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Now that we know how to get a quantity of Ohms to our liking

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in theory we could create our own resistance

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using an extremely thin material with a high coefficient of resistance

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but in reality they are not like that

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if they were just a wire

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It would be extremely difficult to get an accurate resistance in such a small size.

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There are different ways to create a resistance depending on how many Ohms you want to get

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and how accurate is its value.

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The first way is using a nickel wire wound in a ceramic tube

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which by the way is an insulator

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in this way, you can control the total resistance

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modifying the length of the cable, but maintaining a compact size.

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the second option is using a composite material in a defined volume

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but that by varying the elements that make it up

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you can vary its coefficient of resistance and therefore the resistance of the resistor.

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and the third option, is by means of a ceramic cylinder covered by a carbon film,

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which is cut in a spiral until obtaining the desired resistance.

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in other words

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a carbon wire is gradually created to increase the resistance to the desired value

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Aa generally these resistances are so small

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It would be quite difficult to print what their value is,

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that's why was invented a code of colors

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by which we can know its value in Ohms, even without numbers

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for example, this is a resistor of 200 kilo Ohms,

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The way to read its value is as follows:

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the first and second bands correspond to digits from 0 to 9

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in this case red is 2 and the black is 0

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then, the third band corresponds to a multiplier

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to avoid the need to put many black bands when representing large values

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in this case, the yellow band means that you have to multiply by 10000

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so

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2 0 per 10000 gives us 200000 ohms or 200 Kilo omhs.

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and the last band that is left corresponds to the tolerance of this value

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Well, as we saw earlier, a lot of precision is required to generate an exact value.

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in this case, gold means that the tolerance of the value is ± 5% of the defined value.

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may happen that at some point you will find a resistor with more bands

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and its reading will vary slightly, but the logic is the same

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If you search for "color resistance code" on Google you will find many options to download.

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but I also wanted to make one for you and you can download it for free on my Patreon page

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As you can imagine, it is unlikely that there are resistors of all values,

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so there are different ways to mix known resistors to get a desired value

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the first way is connecting resistors in series

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whereby the value of the equivalent resistance is equal to the sum of the connected resistors.

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this is very easy to remember if we think about the formula that we saw at the beginning

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by connecting two equal resistors in series

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the only thing we are doing is multiplying the length of the cable by two

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and therefore its value will be double

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On the other hand, if we want to reduce the total resistance of a set of resistances

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what we can do is connect them in parallel.

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if we connect two equal resistances in parallel and think again in the formula,

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we will realize that what we are doing now

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is simply multiplying the cross-sectional area by two

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that is, we are going to have half the resistance.

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for more complex systems the way to calculate it is something like this

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but the important thing is that you understand why it is like that.

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At this point I think you are ready to start talking about what a resistance is for.

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the use of a resistance with a static value in a circuit

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allows us to regulate the voltage that will be generated in different components

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suppose we have a battery of 12 Volts and an LED that works at a maximum of 3 Volts

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If it exceeds this value, it will burn.

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in this extremely simple circuit

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just by putting a resistance of the right value we can make exactly 3V pass through the LED

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In this video I do not want to go into much detail about how to calculate the value of the resistance that we would need

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but, if you want to continue on your own, I summarize 3 extremely important laws

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the first is Kirchhoff's voltage law,

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which tells us: that if we add all the voltages following a closed path in a circuit

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the value must be zero

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or in other words, the sum of the voltage in each of the components in this trajectory

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must be equal to the voltage in the power source that is supplying them.

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the second, is the current Kirchhoff law,

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which tells us that in each node, that is, where there is more than one possible path for the current

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the current that enters must be equal to the one that comes out.

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and finally the third law is Ohm's Law

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which tells us that the voltage in a component is equal to the current that passes through the

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multiplied by its resistance

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which by the wayz allows us to calculate any of the three variables

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as long as we have the other two.

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as I said, a resistance allows us to control the voltage that passes through other components,

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and there will be times when we want to modify that voltage during the use of the circuit,

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not only during the design stage.

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and this is where the Potentiometer appears.

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the way a potentiometer works is using an arc-shaped resistor

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which, by adding a point of contact with another terminal right between its ends,

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act as if they had two resistors in series.

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in this way, if we measure the resistance between the first terminal and the intermediate one, we will obtain a value,

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whereas if we measure the third terminal and the intermediate we will obtain another value.

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however, by measuring the resistance between the first terminal and the last

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This will always be the same, since being in series must be added.

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this feature allows us to generate circuits like this

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in which when changing the potentiometer we vary the voltage that passes through the LED

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This video had a lot of information, so congratulations if they got here

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Take it easy and everything is going to make sense

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make a video like this equals about 30 or 40 hours of work

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including research, script, animation and editing, among other things

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so, if you think what I'm doing is worth it, you could consider supporting me through Patreon

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as always, thanks to facebook pages

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Mecatronica, We are mecatronica and the electrician's blog, for always sharing my content

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That's all for now and I'll see you in the next chapter