hp calculators - HP 35s Advanced uses of logarithmic functions Log
Answer: The log to base 3 of 5 is 1.465 within the current accuracy setting of the calculator as shown by Figure 5. Calculating 3 to this power gives 5.000
Advanced Logarithms
hp calculators
logarithm of a given number is the exponent that a base number must have to equal Solution: Using the formula given above the log to base 3 of 5 can be ...
s logarithms
Logarithms – University of Plymouth
16 janv. 2001 5. Logarithm of a Power. 6. Use of the Rules of Logarithms ... (b) We can do the same calculation using instead logs to base e.
PlymouthUniversity MathsandStats logarithms
Logarithms
5. 8. The logarithm of 1 loga 1=0. 6. 9. Examples. 6. 10. Exercises. 8. 11. Standard bases 10 and e log and ln. 8. 12. Using logarithms to solve equations.
mc ty logarithms
hp calculators
Common logarithms are also called “log to base 10” and the common logarithm of a hp calculators. HP 33S Advanced uses of logarithmic functions. Figure 5.
sLog
6.2 Properties of Logarithms
Rule2 and we keep in mind that the common log is log base 10. log 3 ln(5) ln(4) . Evaluating this in the calculator gives ln(5).
S&Z . & .
Table of Contents - General Guide. - Turning on or off. Battery
Continuous calculation function. Answer function.. Scientific Calculation Logarithms and Antilogarithms. Fraction calculation. Angle units conversion.
SR N
hp calculators
hp calculators. HP 30S Logarithmic Functions Solution: Using the formula given above the log to base 3 of 5 can be calculated as.
Slogarithms
Logarithms:
Your calculator will be able to calculate logarithms to bases 10 and e (and possibly more). Usually the log button is used for base 10
logarithms
Lesson 5-2 - Using Properties and the Change of Base Formula
Common logarithin and natural logarithm functions are typically built into calculator systems. However it is possible to use a calculator to evaluate.
Logarithms
mc-TY-logarithms-2009-1 Logarithms appear in all sorts of calculations in engineering and science, business and economics. Before the days of calculators they were used to assist in theprocess of multiplication by replacing the operation of multiplication by addition. Similarly, they enabled the operation of division to be replaced by subtraction. They remain important in other ways, one of which is that they provide the underlying theory of the logarithm function. This has applications in many fields, for example, the decibel scale in acoustics.In order to master the techniques explained here it is vital that you do plenty of practice exercises
so that they become second nature. After reading this text and / or viewing the video tutorial onthis topic you should be able to:explain what is meant by a logarithm
state and use the laws of logarithms
solve simple equations requiring the use of logarithms.Contents
1.Introduction2
2.Why do we study logarithms ?2
3.What is a logarithm ? ifx=anthenlogax=n3
4.Exercises4
5.The first law of logarithmslogaxy= logax+ logay4
6.The second law of logarithmslogaxm=mlogax5
7.The third law of logarithmslogax
y= logax-logay58.The logarithm of 1loga1 = 06
9.Examples6
10.Exercises8
11.Standard bases 10 and elogandln8
12.Using logarithms to solve equations9
13.Inverse operations10
14.Exercises11
www.mathcentre.ac.uk 1c?mathcentre 20091. IntroductionIn this unit we are going to be looking at logarithms. However, before we can deal with logarithms
we need to revise indices. This is because logarithms and indices are closely related, and in order to understand logarithms a good knowledge of indices is required.We know that
16 = 2
4 Here, the number 4 is thepower. Sometimes we call it anexponent. Sometimes we call it an index. In the expression24, the number 2 is called thebase.Example
We know that64 = 82.
In this example 2 is the power, or exponent, or index. The number 8 is the base.2. Why do we study logarithms ?
In order to motivate our study of logarithms, consider the following: we know that16 = 24. We also know that8 = 23Suppose that we wanted to multiply 16 by 8.
One way is to carry out the multiplication directly using long-multiplication and obtain 128. But this could be long and tedious if the numbers were larger than 8 and 16. Can we do this calculation another way using the powers ? Note that16×8can be written24×23
This equals
2 7 using the rules of indices which tell us to add the powers4and3to give the new power, 7. What was a multiplication sum has been reduced to an addition sum.Similarly if we wanted to divide 16 by 8:
16÷8can be written24÷23
This equals
21or simply2
using the rules of indices which tell us to subtract the powers4and3to give the new power, 1. If we had a look-up table containing powers of 2, it would be straightforward to look up27and obtain27= 128as the result of finding16×8. Notice that by using the powers, we have changed a multiplication problem into one involving addition (the addition of the powers, 4 and 3). Historically, this observation led John Napier (1550-1617) and Henry Briggs (1561-1630) to developlogarithmsas a way of replacing multi- plication with addition, and also division with subtraction. www.mathcentre.ac.uk 2c?mathcentre 20093. What is a logarithm ?Consider the expression16 = 24. Remember that 2 is the base, and 4 is the power. An alternative,
yet equivalent, way of writing this expression islog216 = 4. This is stated as 'log to base 2 of 16 equals 4". We see that the logarithm is the same as the power orindex in the original expression. It is the base in the original expression which becomes the base of the logarithm.The two statements
16 = 2
4log216 = 4
are equivalent statements. If we write either of them, we areautomatically implying the other.Example
If we write down that64 = 82then the equivalent statement using logarithms islog864 = 2.Example
If we write down thatlog327 = 3then the equivalent statement using powers is33= 27. So the two sets of statements, one involving powers and one involving logarithms are equivalent.In the general case we have:
Key Point
ifx=anthen equivalentlylogax=nLet us develop this a little more.
Because10 = 101we can write the equivalent logarithmic formlog1010 = 1. Similarly, the logarithmic form of the statement21= 2islog22 = 1.In general, for any basea,a=a1and sologaa= 1.
Key Point
log aa= 1 www.mathcentre.ac.uk 3c?mathcentre 2009 We can see from the Examples above that indices and logarithms are very closely related. In the same way that we have rules or laws of indices, we havelaws of logarithms. These are developed in the following sections.4. Exercises
1. Write the following using logarithms instead of powers
a)82= 64b)35= 243c)210= 1024d)53= 125 e)106= 1000000f)10-3= 0.001g)3-2=19h)60= 1
i)5-1=15j)⎷49 = 7k)272/3= 9l)32-2/5=14
2. Determine the value of the following logarithms
a)log39b)log232c)log5125d)log1010000 e)log464f)log255g)log82h)log813 i)log3?127?j)log71k)log8?18?l)log48
m)logaa5n)logc⎷ co)logssp)loge?1e3?5. The first law of logarithms
Suppose
x=anandy=am then the equivalent logarithmic forms are log ax=nandlogay=m(1)Using the first rule of indices
xy=an×am=an+m Now the logarithmic form of the statementxy=an+mislogaxy=n+m. Butn= logaxand m= logayfrom (1) and so putting these results together we have log axy= logax+ logay So, if we want to multiply two numbers together and find the logarithm of the result, we can do this by adding together the logarithms of the two numbers. This is thefirst law.Key Point
log axy= logax+ logay www.mathcentre.ac.uk 4c?mathcentre 20096. The second law of logarithmsSupposex=an, or equivalentlylogax=n. Suppose we raise both sides ofx=anto the power
m: x m= (an)mUsing the rules of indices we can write this as
x m=anm Thinking of the quantityxmas a single term, the logarithmic form is log axm=nm=mlogax This is thesecond law. It states that when finding the logarithm of a power of a number, this can be evaluated by multiplying the logarithm of the number by that power.Key Point
log axm=mlogax7. The third law of logarithms
As before, suppose
x=anandy=am with equivalent logarithmic forms log ax=nandlogay=m(2)Considerx÷y.
x y=an÷am =an-m using the rules of indices.In logarithmic form
log ax y=n-m which from (2) can be written log ax y= logax-logayThis is thethird law.
www.mathcentre.ac.uk 5c?mathcentre 2009Key Point
log ax y= logax-logay8. The logarithm of 1
Recall that any number raised to the power zero is 1:a0= 1. The logarithmic form of this is log a1 = 0Key Point
log a1 = 0The logarithm of 1 in any base is 0.
9. Examples
Example
Suppose we wish to findlog2512.
This is the same as being asked 'what is 512 expressed as a power of 2 ?"Logarithms
mc-TY-logarithms-2009-1 Logarithms appear in all sorts of calculations in engineering and science, business and economics. Before the days of calculators they were used to assist in theprocess of multiplication by replacing the operation of multiplication by addition. Similarly, they enabled the operation of division to be replaced by subtraction. They remain important in other ways, one of which is that they provide the underlying theory of the logarithm function. This has applications in many fields, for example, the decibel scale in acoustics.In order to master the techniques explained here it is vital that you do plenty of practice exercises
so that they become second nature. After reading this text and / or viewing the video tutorial onthis topic you should be able to:explain what is meant by a logarithm
state and use the laws of logarithms
solve simple equations requiring the use of logarithms.Contents
1.Introduction2
2.Why do we study logarithms ?2
3.What is a logarithm ? ifx=anthenlogax=n3
4.Exercises4
5.The first law of logarithmslogaxy= logax+ logay4
6.The second law of logarithmslogaxm=mlogax5
7.The third law of logarithmslogax
y= logax-logay58.The logarithm of 1loga1 = 06
9.Examples6
10.Exercises8
11.Standard bases 10 and elogandln8
12.Using logarithms to solve equations9
13.Inverse operations10
14.Exercises11
www.mathcentre.ac.uk 1c?mathcentre 20091. IntroductionIn this unit we are going to be looking at logarithms. However, before we can deal with logarithms
we need to revise indices. This is because logarithms and indices are closely related, and in order to understand logarithms a good knowledge of indices is required.We know that
16 = 2
4 Here, the number 4 is thepower. Sometimes we call it anexponent. Sometimes we call it an index. In the expression24, the number 2 is called thebase.Example
We know that64 = 82.
In this example 2 is the power, or exponent, or index. The number 8 is the base.2. Why do we study logarithms ?
In order to motivate our study of logarithms, consider the following: we know that16 = 24. We also know that8 = 23Suppose that we wanted to multiply 16 by 8.
One way is to carry out the multiplication directly using long-multiplication and obtain 128. But this could be long and tedious if the numbers were larger than 8 and 16. Can we do this calculation another way using the powers ? Note that16×8can be written24×23
This equals
2 7 using the rules of indices which tell us to add the powers4and3to give the new power, 7. What was a multiplication sum has been reduced to an addition sum.Similarly if we wanted to divide 16 by 8:
16÷8can be written24÷23
This equals
21or simply2
using the rules of indices which tell us to subtract the powers4and3to give the new power, 1. If we had a look-up table containing powers of 2, it would be straightforward to look up27and obtain27= 128as the result of finding16×8. Notice that by using the powers, we have changed a multiplication problem into one involving addition (the addition of the powers, 4 and 3). Historically, this observation led John Napier (1550-1617) and Henry Briggs (1561-1630) to developlogarithmsas a way of replacing multi- plication with addition, and also division with subtraction. www.mathcentre.ac.uk 2c?mathcentre 20093. What is a logarithm ?Consider the expression16 = 24. Remember that 2 is the base, and 4 is the power. An alternative,
yet equivalent, way of writing this expression islog216 = 4. This is stated as 'log to base 2 of 16 equals 4". We see that the logarithm is the same as the power orindex in the original expression. It is the base in the original expression which becomes the base of the logarithm.The two statements
16 = 2
4log216 = 4
are equivalent statements. If we write either of them, we areautomatically implying the other.Example
If we write down that64 = 82then the equivalent statement using logarithms islog864 = 2.Example
If we write down thatlog327 = 3then the equivalent statement using powers is33= 27. So the two sets of statements, one involving powers and one involving logarithms are equivalent.In the general case we have:
Key Point
ifx=anthen equivalentlylogax=nLet us develop this a little more.
Because10 = 101we can write the equivalent logarithmic formlog1010 = 1. Similarly, the logarithmic form of the statement21= 2islog22 = 1.In general, for any basea,a=a1and sologaa= 1.
Key Point
log aa= 1 www.mathcentre.ac.uk 3c?mathcentre 2009 We can see from the Examples above that indices and logarithms are very closely related. In the same way that we have rules or laws of indices, we havelaws of logarithms. These are developed in the following sections.4. Exercises
1. Write the following using logarithms instead of powers
a)82= 64b)35= 243c)210= 1024d)53= 125 e)106= 1000000f)10-3= 0.001g)3-2=19h)60= 1
i)5-1=15j)⎷49 = 7k)272/3= 9l)32-2/5=14
2. Determine the value of the following logarithms
a)log39b)log232c)log5125d)log1010000 e)log464f)log255g)log82h)log813 i)log3?127?j)log71k)log8?18?l)log48
m)logaa5n)logc⎷ co)logssp)loge?1e3?5. The first law of logarithms
Suppose
x=anandy=am then the equivalent logarithmic forms are log ax=nandlogay=m(1)Using the first rule of indices
xy=an×am=an+m Now the logarithmic form of the statementxy=an+mislogaxy=n+m. Butn= logaxand m= logayfrom (1) and so putting these results together we have log axy= logax+ logay So, if we want to multiply two numbers together and find the logarithm of the result, we can do this by adding together the logarithms of the two numbers. This is thefirst law.Key Point
log axy= logax+ logay www.mathcentre.ac.uk 4c?mathcentre 20096. The second law of logarithmsSupposex=an, or equivalentlylogax=n. Suppose we raise both sides ofx=anto the power
m: x m= (an)mUsing the rules of indices we can write this as
x m=anm Thinking of the quantityxmas a single term, the logarithmic form is log axm=nm=mlogax This is thesecond law. It states that when finding the logarithm of a power of a number, this can be evaluated by multiplying the logarithm of the number by that power.Key Point
log axm=mlogax7. The third law of logarithms
As before, suppose
x=anandy=am with equivalent logarithmic forms log ax=nandlogay=m(2)Considerx÷y.
x y=an÷am =an-m using the rules of indices.In logarithmic form
log ax y=n-m which from (2) can be written log ax y= logax-logayThis is thethird law.
www.mathcentre.ac.uk 5c?mathcentre 2009Key Point
log ax y= logax-logay8. The logarithm of 1
Recall that any number raised to the power zero is 1:a0= 1. The logarithmic form of this is log a1 = 0Key Point
log a1 = 0The logarithm of 1 in any base is 0.
9. Examples
Example
Suppose we wish to findlog2512.
This is the same as being asked 'what is 512 expressed as a power of 2 ?"- log calculator base 5