Math Antics - Scientific Notation
Summary
TLDRIn this Math Antics video, Rob celebrates reaching one million subscribers and introduces viewers to Scientific Notation. He explains how this notation simplifies the representation of very large or small numbers by using a shorter number multiplied by a power of ten. Rob demonstrates the process of converting numbers to and from Scientific Notation, emphasizing the importance of exponents for quickly determining a number's order of magnitude. The video is both educational and engaging, making complex mathematical concepts accessible to viewers.
Takeaways
- đ Rob from Math Antics thanks viewers for subscribing, mentioning their milestone of 1 million YouTube subscribers.
- đą The video is about Scientific Notation, a method to write large or small numbers in a compact form.
- 𧏠Scientific Notation is useful for representing big numbers, like the number of cells in the human body (35 trillion), or small numbers, like the size of a cell (0.0000005 meters).
- đ In Scientific Notation, a number is written as 'some number times 10 to the power of some exponent'.
- đĄ Moving the decimal point to the left makes a number smaller, and to keep the value the same, it must be multiplied by 10.
- đ Exponents are used to simplify repeated multiplication, with '10 to the 2nd' meaning '10 times 10', and so on.
- đ The process of shifting the decimal point continues until there is only one digit left to the left of the decimal point, achieving Scientific Notation.
- đ A numberâs 'order of magnitude' represents how many 10s are multiplied together, which helps in quickly understanding a number's size.
- đ Negative exponents in Scientific Notation indicate repeated division, useful for representing very small numbers.
- đ Converting between regular numbers and Scientific Notation involves counting how many places the decimal point needs to move and adjusting the exponent accordingly.
Q & A
What is Scientific Notation?
-Scientific Notation is a way of writing numbers that are too big or too small to be conveniently written in decimal form. It uses a shorter number multiplied by a power of 10, always in the form of 'some number times 10 to the exponent'.
Why is Scientific Notation useful?
-Scientific Notation is useful because it simplifies the writing of very large or very small numbers by eliminating the need to write many zeros. It also makes it easier to compare and evaluate such numbers quickly.
What does the exponent in Scientific Notation represent?
-The exponent in Scientific Notation represents the number of places the decimal point has been moved. A positive exponent indicates the decimal point has been moved to the right, while a negative exponent indicates it has been moved to the left.
How do you convert a large number to Scientific Notation?
-To convert a large number to Scientific Notation, you move the decimal point to the right so that there is only one non-zero digit to the left of it. The number of places moved is the exponent, which is positive in this case.
How do you convert a small number to Scientific Notation?
-To convert a small number to Scientific Notation, you move the decimal point to the right until you have one non-zero digit to the left of it. The number of places moved is the negative exponent.
What is the 'order of magnitude' in the context of Scientific Notation?
-The 'order of magnitude' in Scientific Notation refers to the exponent of the number when written in this form. It tells you how many 10s you would multiply together to get the original number.
How does shifting the decimal point to the left affect the value of a number?
-Shifting the decimal point to the left makes the number smaller by a factor of 10 for each place the decimal is moved. To keep the value the same, you must multiply by a power of 10.
How does shifting the decimal point to the right affect the value of a number?
-Shifting the decimal point to the right makes the number larger by a factor of 10 for each place the decimal is moved. To compensate and keep the value the same, you would multiply by a negative power of 10.
What is the proper form for a number in Scientific Notation?
-In proper Scientific Notation, a number should have only one non-zero digit to the left of the decimal point, followed by any necessary digits to the right, multiplied by 10 raised to the appropriate exponent.
How can you quickly identify if a number in Scientific Notation is large or small?
-You can quickly identify if a number in Scientific Notation is large or small by looking at the sign of the exponent. A positive exponent indicates a large number, while a negative exponent indicates a small number.
Why might someone use Scientific Notation instead of writing out a very large number with all its zeros?
-Someone might use Scientific Notation instead of writing out a very large number with all its zeros to save time and space, and to make the number easier to read and compare with other numbers.
Outlines
đ Introduction to Scientific Notation
Rob from Math Antics greets viewers and celebrates reaching one million subscribers. He introduces the concept of Scientific Notation, explaining how it simplifies the representation of very large or very small numbers by using a shorter number multiplied by a power of 10. Rob illustrates this with the example of 125,000,000, which in Scientific Notation is written as 1.25 times 10 to the 8th. He emphasizes the practicality of Scientific Notation for quickly evaluating and comparing numbers, and clarifies the process of shifting the decimal point and using exponents to maintain the value of the number.
đ Deep Dive into Scientific Notation
The script explains that for a number to be in proper Scientific Notation, it should have only one non-zero digit to the left of the decimal point. This standardization allows for easy determination of a number's 'order of magnitude,' which is the count of how many 10s are multiplied together to reach that number. Rob demonstrates how to convert a large number into Scientific Notation by shifting the decimal point and adjusting the exponent accordingly. He also shows the conversion of a small number, highlighting the use of negative exponents to represent repeated division by 10.
đ Converting Between Regular and Scientific Notation
The final paragraph outlines the procedure for converting numbers from regular form to Scientific Notation and vice versa. For converting to Scientific Notation, one must determine the number of places the decimal point needs to be shifted to have one non-zero digit to the left of it, which determines the exponent. The sign of the exponent indicates the direction of the shift (positive for left, negative for right). To convert from Scientific Notation to regular form, one uses the exponent to shift the decimal point in the opposite direction: right for positive exponents and left for negative exponents. Rob encourages practice for proficiency in handling Scientific Notation.
Mindmap
Keywords
đĄScientific Notation
đĄExponent
đĄOrder of Magnitude
đĄDecimal Point
đĄPositive Exponent
đĄNegative Exponent
đĄMultiplier
đĄPower of 10
đĄZero Suppression
đĄConversion
Highlights
We have one times ten to the six YouTube subscribers! Thatâs crazy! Thatâs awesome!
Have you ever heard people use numbers like 1 times 10 to the 6th or maybe 3.4 times 10 to the negative 8th? Those are examples of Scientific Notation.
Numbers can be really big or really small. For example, the number of cells in your body is about 35 trillion, while the diameter of a cell is something like 0.0000005 meters.
Scientific Notation uses a shorter number multiplied by a power of 10, which simplifies representing very large or small numbers.
For a number to be in âproperâ Scientific Notation, it should have only one digit to the left of the decimal point.
Order of magnitude refers to how many 10s you need to multiply to get a certain number. The exponent in Scientific Notation shows the order of magnitude.
Shifting the decimal point left makes the number smaller by a factor of 10, while multiplying by 10 compensates to keep the value the same.
Exponents simplify repeated multiplication. For example, instead of writing 10 x 10 x 10, we can write 10 to the 3rd power.
To convert large numbers to Scientific Notation, shift the decimal point until thereâs only one digit left of the decimal, then multiply by a power of 10.
Negative exponents show repeated division. For instance, multiplying by 10 to the negative 1 is the same as dividing by 10.
Scientific Notation makes comparing very large or very small numbers easier by focusing on their order of magnitude.
Scientific Notation helps save space when writing large numbers. For example, 125,000,000 can be written as 1.25 times 10 to the 8th.
Numbers with large positive exponents represent really big numbers, while numbers with large negative exponents represent really small ones.
Converting from Scientific Notation to regular form involves shifting the decimal point based on the exponent, adding zeros as needed.
Practice converting numbers back and forth between Scientific Notation and regular form to become more familiar with the process.
Transcripts
Hi âŠRob here with Math Antics.
âŠjust wanted to say âhiâ to all the people who watch our videos,
and say thank you so much for watching and liking and subscribing.
I know we usually donât do milestone videos,
but this seemed like a pretty cool milestone that we just had to mention it.
We have one times ten to the six YouTube subscribers!
Thatâs crazy! Thatâs awesome!
Thank you SO much!
Oh waitâŠ
You donât know what numbers like one times ten to the six even mean?
Well youâre in luck!
We have a video that explains it.
In fact, itâs this video that youâre watching right now!
Hi Iâm Rob. Welcome to Math Antics.
Have you ever heard people use numbers like that?âŠ
1 times 10 to the 6th or maybe 3.4 times 10 to the negative 8th?
Well⊠those are examples of a way of writing numbers called Scientific Notation.
Huh⊠that didnât sound quite right, let me try that again.
âŠScientific NotationâŠ
Ah yes⊠thatâs better.
Numbers can be really big or really small, right?
Like, if you wanted to count up all the cells that make up your body,
it would be a really big number.
âŠsomething like 35 trillion cells!
But if you wanted to measure the diameter of one of those cells using meters,
youâd get a really small number.
âŠsomething like 0.0000005 meters.
Not only are really big or small numbers a lot of work to write down because of all the zeros,
theyâre hard to quickly evaluate and compare.
At a glance, itâs not easy to tell just how many number places there are
in these really big or small numbers.
And thatâs where Scientific Notation can really help us out!
Instead of using a long sequence of decimal digits to represent numbers,
Scientific Notation uses a shorter number multiplied by a power of 10.
And itâs always in that form: some number ââŠtimes 10 to theâŠâ some exponent.
Hereâs an example of a really long number: One-hundred, twenty-five million.
And hereâs the equivalent number written in Scientific Notation: 1.25 times 10 to the 8th
Wanna see how these two numbers are just different ways of writing the same thing?
Letâs start by making a copy of our big number and messing with its decimal point a bit.
Whereâs the decimal point you ask?
Remember that itâs always here, immediately to the right of the ones-place.
We just donât need to show it if there arenât any decimal digits.
Okay, so what would happen if we shift the decimal point one place to the left?
Well, doing that would change the number, right?
By definition, the decimal point is always immediately to the right of the ones-place,
so shifting the decimal point shifts the ones-place and all the other number places too.
And if we line up the ones-place of our new number with the ones-place of the original number,
you see that the new number is 10 times smaller.
That means shifting the decimal point one place to the left is equivalent to dividing a number by 10.
But, do we want a number thatâs 10 times smaller than before?
WellâŠno. We donât want to change the value of the number at all.
We just want to write it in a different way.
Since shifting the decimal resulted in a number thatâs 10 times smaller than before,
to compensate and keep the value the same, we need to multiply the new number by 10.
Making the number smaller and then compensating for that might seem like a weird thing to do,
but it will make more sense in a minute.
Letâs do that process again.
Letâs make a copy of the new number and shift the decimal point to the left again.
Since that shifts all the number places, we can align the ones-places and see that the same thing happened.
The new number is 10 times smaller than before.
So to keep it the same value as the original number, we need to compensate by making it 10 times bigger.
We need to multiply by another 10.
And if we repeat that process againâŠ
if we make another copy and shift the decimal point again,
weâll see that the number gets 10 times smaller,
so we need to compensate by multiplying by another 10.
Alright, time out! We seem to have a little problem here.
Each time we shift the decimal point to the left, our number gets smaller.
But since we have to compensate with a factor of 10 each time, itâs making kind of a mess!
This part is getting shorter, but this part is getting longer!
No problem⊠Exponents can fix that!
Do you remember that exponents are a way of writing repeated multiplication?
If you donât, then be sure to watch our videos about them before moving on.
Instead of writing 10 times 10, we can write 10 to the 2nd power,
and instead of writing 10 x 10 x 10, we can write 10 to the 3rd power.
Thatâs much better! Now we can continue on.
Weâll shift the decimal point again and multiplying by 10 again.
But this time, instead of writing another âtimes 10â,
we can just increase the exponent by 1 since there would be
a total of four 10s being multiplied together.
Letâs keep going with this process of shifting the decimal point to the left
and multiplying by 10 for each number place we shift.
And weâll stop when thereâs only one digit remaining to the left of the decimal point.
Wow! Thatâs quite a pattern.
Each time we shifted the decimal, the number got 10 times smaller.
So, each time we had to multiply by another 10 to keep the value the same.
And because we did that, each one of these lines represents the same value.
So even though it looks a lot different, this last line has the exact same value as the first one.
In fact, itâs just the original number written in Scientific Notation.
But, why is it only this last line, and not any of the others?
I mean⊠they all look pretty scientific to me!
Ah⊠thatâs a good question.
For a number to be in âproperâ Scientific Notation,
itâs supposed to have only 1 digit to the left of the decimal.
There can be more than one digit to the right of the decimal, depending on the accuracy of the number,
but just 1 digit to the left.
But why? I mean⊠that rule sounds kinda arbitrary.
Itâs not arbitrary at all!
If there's more than one digit to the left of the decimal point,
that would mean that we didnât get out all of the factors of 10 that we could have.
And factoring out ALL of the 10s helps us quickly determine a numberâs âorder of magnitudeâ.
Order of magnitude!?
What in the world is that? That sounds kinda scary!
Order of magnitude is basically just how many 10s you need to multiply to get a certain number.
And when a number is in Scientific Notation, the order of magnitude is just the exponent,
because thatâs telling us how many 10s to multiply together.
In this example, the Scientific Notation says that if we take this small decimal
and multiply it by eight 10s, weâll get our original number.
So Scientific Notation is a way of taking a really big number
and reducing it down to a value thatâs less than 10,
but keeping track of how many 10s we would need to multiply together to get the full number.
You can think of it as basically just extracting its âorder of magnitudeâ and storing it in exponent form.
But why would we want to do that? I mean⊠it seems kinda complicated.
Well⊠yeah, but⊠did you see how much writing it saved us?
When we wrote out 125,000,000 we had to write ELEVEN characters, including commas.
But when we wrote the same number in Scientific Notation, we only had to write EIGHT characters.
What? âŠnot convinced that itâs worth the savings?
Well how about this number?âŠ
Thatâs a LOT of zeros to write, isnât it?!
But in Scientific Notation, this number is just 8.4 times 10 to the 31st power.
Thatâs much better!
So Scientific Notation is very useful when it comes to writing down really large numbersâŠ
or really small ones.
For example, this number is really small: 0.00000095
Itâs much less than 1, but itâs not zero.
And hereâs the same number written in Scientific Notation.
Again, it consists of a number that has only one digit to the left of the decimal point
which is being multiplied by 10 to a certain power.
But do you notice anything different about the exponent?
Yep⊠itâs negative! So what does that mean?
Well, the short answer is that positive exponents show repeated multiplication
while negative exponents show repeated division.
And since this is a negative exponent with 10 as the base,
it means to repeatedly divide by 10.
To see how that works,
letâs copy our original number and do that decimal-point-shift-thing again.
Only this time, weâre gonna shift the decimal point to the right.
What happens if we shift it one place to the right?
It makes the number 10 times bigger than it was before.
There used to be 6 zeros between the decimal point and the '9', but now thereâs only 5.
Again, we donât want to change the value,
so what can we do to compensate for shifting the decimal point?
In this case, since shifting one place to the right made the number 10 times bigger,
we need to compensate by dividing the number by 10.
And because of the way multiplication and division are related,
dividing by 10 is the same as multiplying by 1 over 10 (or one-tenth)
so we can just multiply by one-tenth.
OR⊠we can multiply by 10 to the negative 1,
because 10 to the negative1 is just another way of writing one-tenth.
That may seem odd if you havenât learned about negative exponents before,
and we explain it in more detail in our video about the Laws of Exponents.
For now, all you really need to know is that
multiplying by 10 to the negative 1 is the same as dividing by 10,
so it compensated for shifting the decimal point one place to the right.
Continuing on, if we shift the decimal point another place to the right, the same thing happensâŠ
we make the number 10 times bigger.
So to keep the value the same, we have to multiply by another factor of 10 to the negative 1.
And it youâre wondering whether we can combine these exponents, youâre on the right track!
10 to the negative 1 times 10 to the negative 1 combine to become 10 to the negative 2,
which makes sense because we shifted the decimal point a total of two places to the right.
And if we shift the decimal point 3 places to the right,
we need to multiply by 10 to the negative 3 to compensate.
And if we shift 4 places, then we need 10 to the negative 4 to compensate. âŠget the idea?
And if we continue doing that until the decimal point is
positioned so that thereâs only 1 digit to the left of it,
that gives us the number in Scientific Notation: 9.5 times 10 to the -7
And can you figure out what the order of magnitude of this number is?
Yep⊠just like before, the exponent tells us.
Itâs negative 7.
Being able to quickly identify a numberâs order of magnitude is pretty handy.
For example, if the order of magnitude is a big positive exponent,
then you know right away that youâre dealing with a really big number.
But if itâs a big NEGATIVE exponent,
then you know youâre dealing with a really small number.
And if youâre comparing two really big number like these two,
or two really small numbers like these two,
itâs hard to tell at a glance which is actually bigger or smaller.
But if you see them in Scientific Notation,
itâs easy to see that this numberâs order of magnitude is bigger than the otherâs,
which means that itâs bigger,
and this numberâs order of magnitude is less that the otherâs
which means that itâs smaller.
So now that youâve seen how Scientific Notation works,
and you realize that itâs just a short-hand way of writing really big or really small numbers,
letâs break down the procedure for converting back and forth
between numbers written in regular form and Scientific Notation.
Starting with these two examples in regular formâŠ
First, count how many number places you would need to shift the decimal point
for there to be only 1 digit to the left of it.
For this number weâd need to shift 8 places,
and for this number; 6 places.
The number of places you need to shift will be the exponent in the Scientific Notation form,
but the sign of that exponent is determined by the direction you shifted.
If you shifted to the left (because you started with a big number) then the exponent will be positive.
But if you shifted to the right (because you started with a small number) then the exponent will be negative.
So that gives you the âtimes 10 to the somethingâ part of the Scientific Notation
and to get the number thatâs multiplied by that power of 10,
you just take the shifted decimal number and remove any zeros that donât really need to be shown.
There⊠that wasnât too hard, was it?
But what if we start out with numbers in Scientific Notation and want to convert them into regular form?
Letâs do that with these two examples.
The first step is to look at the exponent which is the order of magnitude of the number.
It tells you how many 10s you'll need to multiply or divide by to get the number in regular form.
If the exponent is positive, it means that youâll need to multiply by that many 10s.
In this example, that means that we would need to
multiply by a total of seven 10s to get the number in regular form.
That would be a lot of work, but we can also just shift the decimal point that number of places.
Which direction do we need to shift it?
Well⊠since weâre multiplying by factors of 10,
we need to shift it in the direction that will make the number bigger.
That is, we need to shift it to the right.
So, weâll just shift the decimal point 7 places to the right.
But as you can see, thereâs arenât 7 digits after the decimal,
so any places that donât have a digit will just be filled with a zero.
There⊠Our number is regular form is 41,650,000
In this second example, the exponent is negative,
which means that weâll need to divide by that number of 10s to get the number in regular form.
Again, we could just do that division, or we can shift the decimal point to save time.
Since dividing by factors of 10 make a number smaller,
weâll need to shift the decimal point in the direction that results in a smaller number⊠that is, to the left.
Since our exponent is negative 5, weâll shift the decimal point 5 places to the left.
And any places that we shift past that donât already have a digit in them will get filled with a zero.
Weâll also put a zero in the ones-place since thatâs always good form for decimal numbers.
There⊠Our number in regular form is 0.0000109
Alright⊠thatâs the basics of Scientific Notation.
Itâs may seem a little confusing at first, but as you get more experience with it, it makes a lot of sense.
And when it comes to writing really big or really small numbers, itâs totally worth it.
And even if you understand how Scientific Notation works,
it may take some practice to get good at converting back and forth between it and regular form,
so be sure to practice on your own.
As always, thanks for watching Math Antics, and Iâll see ya next time.
Learn more at www.mathantics.com
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