2.3
Logarithms:
In 2.2 we learnt exponents and several laws.
To recollect, some numbers can be represented as:
Base Exponent = Number
This method of representation is called ‘exponential form’.
Ex: 23 = 8
This relationship can be represented in a different format:
log base Number
= Exponent
EX : log2 8 = 3 ( Equivalent to saying 8 = 23)
The ‘logarithm’ (log)
of any number to a given base is the value of
the index to which the base must be raised
to get the given number
The above method of representation is called ‘logarithmic form’.
We have seen that
1) x0 =1
Hence logx1 = 0
2) x1 =x
Hence logxx = 1
From laws of exponents we can derive the following laws of
logarithms:
1. Product law: loga(mn)
= loga m+ loga n (By
xm.xn= xm+n property)
2. Quotient law: loga(m/n) = loga m
- loga n(By xm/xn=
xm-n property)
3. Power law: logamn
= nloga m(By (xm)n= xmn property)
4. logam1/n = (1/n) logam ( By Power law)
2.3
Problem 1: Find x
if log9 243=x
Solution:
This is equivalent to saying 9x= 243 = 3*3*3*3*3
= 35
But 9x=32x
32x= 35
2x =5
x =5/2
Logarithms to the base 10 are
called ‘common logarithms’
Convention: If base is not given, then the base is assumed to
be 10 (log20 implies log1020).
We have seen that log1=0 and log10=1.
2.3
Problem 2: Given
log x = m+n and log y = m-n. Express log (10x/y2) in terms of m and
n.
Solution:
log (10x/y2) = log 10x – log y2 (quotient
law)
= log 10 + log x – 2 log y( product law, power law)
= 1 + (m+n) – 2(m-n) (substitution, log 10 = 1)
= 1-m+3n
2.3
Problem 3: Given
2log x+1 = log 250 find x, log 2x
Solution:
Since base is not given, it is
assumed to be 10.
log 250 = log (10*25) = log 10 + log 25 = 1 + log 25 (log
10 = 1)
2log x + 1 = 1 + log 25
i.e. 2log x = log 25
But 2log x = log x2(Power law)
log x2 = log 25
x2=25
i.e. x=5
log 2x = log 10 = 1
2.3
Problem 4: If 2log
y – log x – 3 = 0 express x in terms of y
Solution:
Since 2log y – log x – 3 = 0
log x = 2log y - 3 = 2log y – 3log 10
= log y2- log 103
= log (y2/103)
Thus
log x = log (y2/103)
x = y2/103 = y2/1000
2.3
Problem 5: If log
2 = 0.3010 and log 3 = 0.4771 find value of log 
Solution:
= 
= (30/4)1/2
log = (1/2)log(30/4) =
1/2(log30-log4)
= ˝(log 10 + log 3 - 2log 2)
= ˝(1+0.4771-0.6020)
=˝(0.8751)
= 0.43755
We have seen that log 1 = 0, log 10 = 1(
logx x = 1 and logx 1 = 0)
Thus log x for any value of x (1
x 10) has to be in between 0 and 1.
In fact log 2 = 0.3010 and log 3 =
0.4771 (We get these values from log tables discussed later)
Also note
log 100 = log(10*10)=log10+log10=2log10=2
log 1000 = log(103) = 3log10=3*1=3 and so on….
log value of a number has two
parts: an integer part and decimal part.
The integral
part of the logarithm is called ‘characteristic’
and the decimal part of the logarithm is
called ‘mantissa’.
In case of log 2 = 0.3010, 0 is characteristic and .3010
is mantissa.
We use a table called ‘logarithmic table’ to find the values of numbers
to the base 10.
A section of the table is given
below:
|
As we observe from adjacent figure, the table has three
parts. 1. First part is the left most column (Blue box)
which contains numbers from 1.0 to
1.5(The adjacent figure only has a part of the table
from 1.0 to 1.5 but the full table has values from 1.0 to 9.9). 2. Second part contains 10 columns (red box) 3. Third part contains 9 columns (pink box) (with Mean
differences as the heading) Against each number in the first column there are 10
columns in 2nd part, having decimal
values corresponding to digits from 0 to 9. Against each number in the first column there are 9
columns in 3rd part, having decimal values corresponding to digits from 1 to
9. |
|
|
If we look at the full logarithmic table we notice the values are from 0.0000 to 1.0
(0.9996+.0004) The table represents values from 0 to 1 correspondingly
from log1 to log10 (log 1 = 0, log 10 = 1) |
|
Observe the following:
|
Number |
=(Equivalent) |
log of number |
= |
=(Expansion) |
=(Simplification) |
|
3257 = |
3.257*103 |
log(3257) = |
Log(3.257*103) |
= 3log10 +log(3.257) |
= 3+ log(3.257) |
|
325.7 = |
3.257*102 |
log(325.7) = |
Log(3.257*102) |
= 2log10 +log(3.257) |
= 2+ log(3.257) |
|
32.57 = |
3.257*101 |
log(32.57) = |
Log(3.257*101) |
= 1log10 +log(3.257) |
= 1+ log(3.257) |
|
3.257= |
3.257 |
log(3.257)= |
Log(3.257) |
= 0log10 + log(3.257) |
= log(3.257) |
|
0.3257 = |
3.257*10-1 |
log(0.3257) = |
Log(3.257*10-1) |
= -1log10 +log(3.257) |
= |
|
0.03257 = |
3.257*10-2 |
log(0.03257) = |
Log(3.257*10-2) |
= -2log10+log(3.257) |
= |
|
0.003257 = |
3.257*10-3 |
log(0.003257) = |
Log(3.257*10-3) |
= -3log10+log(3.257) |
= |
|
0.0003257 = |
3.257*10-4 |
log(0.0003257) = |
Log(3.257*10-4) |
= -4log10+log(3.257) |
= |
Note: –log10 is not written as –1 but as
Thus if we know the logarithmic
value of a number having one integer digit, then by using product and power laws
of logarithm we can find the values of any given number which is 
multiple of the given
number.
Note that the logarithmic table given
in the adjacent figure
is for values from log 1.0 to
log(3.5)
(Note: log 1 = 0)
How to use the log table?
|
Let us find the value of log 32.57 1)First convert the given number
into a decimal such that there is only one digit in the integer part and
there are not more than three digits in the decimal part. Thus 32.57 = 3.257*101 2)Split the given four digit
number into 3 parts (first part with two digits, then two parts of one digit
each).In this example 32.57 is split into three parts (3.2, 5 and 7). 3)Identify the row corresponding
to first part of 2 numbers (In this example 3.2). 4)In this row find the value under
the number which corresponds to the second part(in this example under
5). The value is 0.5119 5)To the above value, add the
value under the
number which corresponds to the third part (in this example under 7).
The value is 0.0009 6)Sum of values of steps 4 and 5
is the log value of 1/10th of the given
number(32.57)(0.5128
= 0.5119 + 0.0009)
is the log value of 3.257
Similarly log (2.223) = 0.3464+0.006 = 0.3470 and hence
log(22.23) = 1.3470, log(222.3) = 2.3470,…… |
|
2.3 Problem 6: Find a, b and c If log(a) = 1.7782, log(b)= 
.7782 and log(c)=1.5564 and log6=0.7782
Solution:
Log(a)=1.7782 = 1+0.7782 = log10+log6 = log60
a=60
log(b)= .7782 = log(10-2)+0.7782 = log10-2+log6
= log(6/100)
b=0.06
log(c)=1.5564 = 2 (0.7782) {By intuition} =
2 log6 = log 62
c=62=36
If log3257 = 3.5128, then 3257 is
called ‘antilogarithm’ of 3.5128 and we
write antilog3.5128 = 3257 or log-1 (3.5128) = 3257.
Like logarithmic tables we also
have antilog tables, a section of which is given below. The usage of antilog
table is similar to log table.
If log table has values
corresponding to 1.00 – 9.9, antilog table has values corresponding to 0.00 to
.99
Change of base of
logarithm:
logx y= logx a/ logy a
Proof:
Let logx a = p,
xp=a ----ŕ(1)
Let logy a=q
yq=a ----ŕ(2)
logx y = r
And Let logx y =r
xr=y ----ŕ(3)
From (2) a = yq ( by substituting from (3) for y) we get
a=( xr)q= xrq (By law of
exponents)
But from (1) a = xp
Hence xp= xrq
p = qr
By substituting values for p, q and r.
logx a = logy a * logx y
i.e. logx y = logx a/ logy a
Similarly we can prove that
logx y = loga y/ loga x
2.3
Problem 7: If x =
1+logabc, y= 1+logbca , z = 1+logcab, show
that xy+yz+zx= xyz
Solution:
Since x = 1+logabc,
logabc =x-1
bc = ax-1
= ax/a
abc = ax
(abc)1/x =
a
Similarly
(abc)1/y =b and (abc)1/z
=c
(abc)1/x(abc)1/y (abc)1/z=
abc (By multiplying individual terms)
But
(abc)1/x(abc)1/y
(abc)1/z = (abc)(1/x+1/y+1/z)
abc = (abc)(1/x+1/y+1/z)
1 =
[(1/x)+(1/y)+(1/z)] ( By equating exponents)
= (yz/xyz)+(xz/xyz)+(xy/xyz)
= (xy+yz+zx)/xyz
xyz = xy+yz+zx
Why use Logarithmic and antilogarithmic tables?
2.3 Summary of learning
|
No |
Points to remember |
|
1 |
loga(mn)
= loga m+ loga n |
|
2 |
loga(m/n)
= loga m – loga n |
|
3 |
logamn
= nloga m |
|
4 |
logam1/n
= (1/n) logam |
|
5 |
logx
y= logx a/ logy a |
|
6 |
logx
y = loga y/ loga x |