WEBVTT

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The system that we're going to implement is the binary to the seven segment equal right to what we let

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Zouma's from an on ongoing basis.

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We will be considering three switches, OK, which would serve as input to our system.

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So depending on the value that we feed, OK, the equivalent decimal number will be displaying on it.

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Seven segment display, right?

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So we'll just be going through a fundamental of a seven segment display before we actually proceed to

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equal weight.

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So if you consider the seven segment display, so we have a seven included, right, so each LCD have

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a unique name, for example, if you consider this as a seven segment display.

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So we have this LCD, which is named as any.

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This allele, which is named as b c d e f g h if you count one two three four, five six and seven eight

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two.

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We have a seven alleles right now.

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We have a two configuration for a seven segment display.

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So OK, so it could either be a common A. or a common category.

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So when we see our common A..

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OK, so each allele will have a two term right to A. and cattle.

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So if you connect all the A. All finally this together, so that is referred to as common A. seven segment

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display, right?

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Whereas if you connect all the cattle off and they do this together, OK, then that kind of the seven

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segment displays referred to as the common cattle seven segment right now.

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Here you could see the.

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Onboard 716 display that we have on hand based distributors of common and great so valued of all their

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lives are connected together.

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Whereas for a cattle, we will be applying the signal from our SPG, right?

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So you could clearly see for each rate.

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So to turn on.

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Since we have a cattle terminal which is connected to an object, we need to apply as a so to turn on

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any one of this and we just need to apply zero rate.

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And if we considered an annual rate.

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So we have a full seven segment display rate.

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So to enable the seven to display rate.

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So this is a common and open rate.

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This makes sense, though this is a common annual thing that we have over here, right?

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But this is connected to the BNP transistor rate and to turn on a P and B transmit transistor.

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OK, so even though it is the common A. Right.

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But still, we need to apply zero.

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OK, so when we apply it, zero from this state right to this will turn on the transistor.

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And then finally, we will be getting colour that is flowing through this seven segment display, right?

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So even though our display is of when I know, right, due to our presence over time this year, we

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still need to apply it here.

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This makes sense.

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So you could see, for example, OK, this is our.

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Any rate, so this will be coming from this spin rate so that W7 W6, you wait dissolve Pinto on an

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FPGA chip, right?

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So we will be applying a signal to this to turn on the specific segment, right?

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So this represents our cattle.

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And then we have an, I know, lower rate.

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And this is connected to.

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To the CC, right?

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And this is BNP transistor.

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So this again, will be coming from Fiji, right, so this will be and enable pin that will be used

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to enable the specific seven segment display out of this war seven segment display that we have on hand,

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right?

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So this will be again coming from in Fiji.

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The cattle signal will also be coming from an FPGA now to have a positive signal at an alert rate.

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So we need to make sure that we close our transistor right dad since our transistor is the input transistor,

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so we need to apply a seat over here and when we apply zero.

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OK, so this will basically be here as it switch, right?

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So when this behave as a close switch, this will basically connect the V60 to the North Bay, not far

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LCD, OK, and then depending on the signal that we apply on and cathode, then we will be turning on

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and off.

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This makes sense.

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So this is the fundamental operation.

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Now the takeaway from this entire thing is to enable any of the seven segment display that we have right

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out of this seven segment display.

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We just need to apply zero at this point, OK, which are the common and open and to doing on this specific

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segment, often single seven segment display.

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We are going to need to apply it right so that let's considered the first case when we used only a single

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seven segment display, right?

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So we'll just apply that zero over here that is basically connected to W4.

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OK, so we will be applying the zero.

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This will enable this seven segment display and will be simply applying one to the rest of the common

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and open.

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So this will automatically disable this three seven segment display, right?

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This makes sense now to display a zero rate of zero will be something like this, right?

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So we have zero something like this.

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So this is referred to as the B C D E F, and then we have g over here right now.

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You could clearly see we want to turn on E B, C D e f, right, and we want to turn off G.

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So if we consider zero zero zero combinations, so E will be applied a logic C2 OK.

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So this will basically turn on this allele segment.

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If we apply zero to a B, this will turn on the B allele segment.

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Similarly, when we apply zero to a c d e f OK.

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So this will basically turn on C, D E and right.

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Whereas if we're going to GDP ratio for a G, we are applying what right?

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So this will be automatically turning off.

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I d seven g.

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Right.

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Whereas DP is also one, so this will also turn off.

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The right time to be able to get to you.

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So likewise, you could find out the combination of value for A B, C, D, E, F G and B, depending

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on the value that you one percent rate.

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So I have already created a table of it and we have already found out an equal integrated serial number,

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right?

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So if you just convert this to exactly single digit rate, so this for zero will be giving a zero and

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then zero zero one one will be giving us three, right?

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So we have a zero 393 submit form.

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Likewise, I've calculated all the values for all the three possible combination that we could have

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within binary number, right?

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So what we're going to do is this B to B will be zero will be connecting to the three slates, which

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is OK.

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And there's a b c, d, e f g and B will be connecting to the seven segment, OK?

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And as we change the speed of light switches, we will see that to be able to find out and equally decimal

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representation on this seven segment display right now.

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What are we going to do?

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It will be going to a vital where we will start developing the system.

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We'll get out of this deep.