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My name is Sarah Wilkinson.
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This is the second of the video series
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showing how to convert VO2 values.
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In this video I am going to show you how to
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easily convert a relative VO2 value to an
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absolute VO2 value.
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Please make sure you have watched the first video
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which shows you the basic mathematical principle
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I am using to do these conversion factors.
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As a well as a little background of what VO2 is.
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In this video I am going to show you how to
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convert a relative VO2 value,
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which is measured in ml per kg body mass per minute
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to an absolute value, in litres per minute.
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I am going to set it up by putting
my relative value on the left hand side
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and on the far right hand side, I have put in
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what I am trying to convert to,
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so the absolute value of L per minute.
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Let's use a theoretical example, and say we have
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someone with a VO2max of
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45 ml of oxygen per kilogram body mass
per minute
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This is essentially 45 ml per 1kg minute.
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Normally we don't put the '1' in.
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Just to show you what should be on the denominator.
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I need to do two conversions factors.
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I need to convert millilitres to litres
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minutes will remain, but I
need to remove kilograms.
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For some people, whether to divide or multiply by 1000
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and divide or multiply the the body mass becomes
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a little confusing.
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So setting up in this manner helps you decide
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whether you need to divide or multiply.
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Again the principle I am using,
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is that if one unit is on the numerator,
for this example 'ml'
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I can multiply by a conversion factor and put
the 'ml' on the denominator in the conversion factor,
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and those two will cancel out.
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We know how how many millilitres are in 1 litre.
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That is what we are trying to convert to here.
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There is 1000 ml in 1 L.
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If I stopped at this point, by cancelling out 'ml'
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I would take 45 and divide by 1000.
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However, if I stopped at this point,
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I would end up with litres per kilogram per minute
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Remember an absolute value is measured in L/min.
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Therefore, I must also "get rid" of the kilograms.
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So I need to either divide or multiply by kg.
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For some people, what to do may be clear to you.
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For others, not so much.
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We are going to use the same principle again.
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We need to "remove" kg in the next conversion factor.
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And it is on the denominator, on the left hand side.
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In order to cancel it out, I need to put is on the numerator.
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Remember top is going to cancel out bottom.
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Let's say for this example, the person is 78 kg.
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And again that is over '1'.
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'kg' will cancel each other out.
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Top cancels out bottom.
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To finish this off, all I need to do, is multiply all
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numbers together and
divide by all the bottom numbers.
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Because anything divided or multiplied by one
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is one, I am going to worry about the numbers
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that are not one.
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I am going to take 45 and multiply it by 78
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and divide by 1000.
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This gives me the answer of 3.51 litres per 1 min.
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In this example, I have converted a relative VO2max
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of 45 ml per kg per minute and converted it
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to an absolute value of 3.51 litres per minute.
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Let's do another example now.
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I want you to convert Stanley's relative
VO2 of 30 ml per kg per minute
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to an absolute VO2 value in L/min.
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His body mass is 80 kg.
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Please pause this video now.
Try this out on your own.
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Once you have come up with the answer,
or if you get stuck, press play again.
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Again we are converting a relative value in ml per kg per min.
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to an absolute value, in L/min.
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Stanley's relative value is 30 ml per 1 kg minute
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We want to convert ml to L.
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We set it up so that the numerator
cancels out the denominator.
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We know there is 1000 ml per 1 L.
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'ml' cancel out.
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We need to multiply by kg because
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in the relative value it is on the denominator.
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We need to kg on the numerator.
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And we know Stanley is 80 kg.
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'kg' cancel out.
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In this example, I am going to take
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30 multiplied by 80 and divide by 1000
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to get my absolute value of 2.4 L/min.
