$${\log_{a}{b}} = \dfrac{\log_{c}{b}}{\log_{c}{a}}$$
$${\log_{a}{b}}*{\log_{b}{a}}= 1$
$$log_a(x) = 1/log_x(a)$$
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Check Now$${\log_{a}{b}} = \dfrac{\log_{c}{b}}{\log_{c}{a}}$$
$${\log_{a}{b}}*{\log_{b}{a}}= 1$
$$log_a(x) = 1/log_x(a)$$
For a real number a, if $$\frac{\log_{15}{a}+\log_{32}{a}}{(\log_{15}{a})(\log_{32}{a})}=4$$ then a must lie in the range
We have :$$\frac{\log_{15}{a}+\log_{32}{a}}{(\log_{15}{a})(\log_{32}{a})}=4$$
We get $$\frac{\left(\frac{\log a}{\log\ 15}+\frac{\log a}{\log32}\right)}{\frac{\log a}{\log\ 15}\times\ \frac{\log a}{\log32}\ \ }=4$$
we get $$\log a\left(\log32\ +\log\ 15\right)=4\left(\log\ a\right)^2$$
we get $$\left(\log32\ +\log\ 15\right)=4\log a$$
=$$\log480=\log a^4$$
=$$a^4\ =480$$
so we can say a is between 4 and 5 .
For some positive real number x, if $$\log_{\sqrt{3}}{(x)}+\frac{\log_{x}{(25)}}{\log_{x}{(0.008)}}=\frac{16}{3}$$, then the value of $$\log_{3}({3x^{2}})$$ is
Correct Answer: 7
It is given that $$\log_{\sqrt{3}}{(x)}+\frac{\log_{x}{(25)}}{\log_{x}{(0.008)}}=\frac{16}{3}$$, which can be written as:
=> $$2\log_3x+\log_{0.008}25\ =\ \frac{16}{3}$$
=> $$2\log_3x+\log_{\frac{8}{1000}}25\ =\ \frac{16}{3}$$
=> $$2\log_3x+\log_{\frac{1}{125}}25\ =\ \frac{16}{3}$$
=> $$2\log_3x+\log_{5^{-3}}\left(5\right)^2\ =\ \frac{16}{3}$$
=> $$2\log_3x-\frac{2}{3}=\ \frac{16}{3}$$
=> $$2\log_3x=\frac{16}{3}+\frac{2}{3}$$
=> $$2\log_3x=6$$
=> $$\log_3x^2=6\ =>\ x^2\ =\ 3^6$$
Hence, $$\log_3\left(3\cdot x^2\right)\ =\ \log_3\left(3\cdot3^6\right)\ =\log_33^7\ =\ 7$$
If a, b and c are positive real numbers such that $$a > 10 \geq b \geq c$$ and $$\cfrac{\log_8 (a + b)}{\log_2c} + \cfrac{\log_{27} (a - b)}{\log_3c} = \cfrac{2}{3}$$, then the greatest possible integer value of a is
Correct Answer: 14
The first term of the expression can be rewritten as $$\frac{\frac{1}{3}\log_2\left(a+b\right)}{\log_2c}$$
Using the property $$\frac{m}{n}\log_ab=\log_ab^{\frac{m}{n}}$$ this can be rewritten as
$$\frac{\log_2\left(a+b\right)^{\frac{1}{3}}}{\log_2c}$$
And finally using the property $$\frac{\log_ba}{\log_bc}=\log_ca$$, we can rewrite the expression as
$$\log_c\left(a+b\right)^{\frac{1}{3}}$$
Doing identical operations in the second term, we get the entire left-hand side to be:
$$\log_c\left(a+b\right)^{\frac{1}{3}}+\log_c\left(a-b\right)^{\frac{1}{3}}$$
Using property $$\log_ca+\log_cb=\log_c\left(ab\right)$$ we get
$$\log_c\left[\left(a+b\right)^{\frac{1}{3}}\left(a-b\right)^{\frac{1}{3}}\right]$$
$$\log_c\left[\left(a+b\right)\left(a-b\right)\right]^{\frac{1}{3}}$$
$$\log_c\left[\left(a^2-b^2\right)\right]^{\frac{1}{3}}$$
This expression is given to be equal to 2/3
Using the definition of log: $$\log_cN=a\ $$ which is $$c^a=N$$
we get:$$c^{\frac{2}{3}}=\left(a^2-b^2\right)^{\frac{1}{3}}$$
Cubing both sides:
$$c^2=a^2-b^2$$
Finally giving $$a^2=b^2+c^2$$
We have upper limits on b and c as 10, and we want to maximize the value of a squared.
This can be thought of as a right-angled triangle, and the value of a will be maximum when both b and c are equal to 10, giving $$a^2=200$$, but this would not give an integer value of a
We need to adjust $$a^2$$ to the biggest square less than 200, which is 196
Giving the value of $$a$$ as 14.
Therefore, 14 is the correct answer.
If $$3^a = 4, 4^b = 5, 5^c = 6, 6^d = 7, 7^e = 8$$ and $$8^f = 9$$, then the value of the product abcdef is
Correct Answer: 2
Taking a log for each of the expressions, we get the following:
$$\log_34=a,\ \log_45=b,\ \log_56=c,\ \log_67=d,\ \log_78=e,\ \log_89=f$$
The expression $$abcef$$ would then be: $$\log_34\times\ \log_45\times\ \log_56\times\ \log_67\times\ \log_78\times\ \log_89$$
Next, we can use this property of log: $$\frac{\log_ba}{\log_bc}=\log_ca$$
Using this, we get:
$$\frac{\log\ 4}{\log\ 3}\times\ \frac{\log\ 5}{\log\ 4}\times\ \frac{\log\ 6}{\log\ 5}\times\ \frac{\log\ 7}{\log\ 6}\times\ \frac{\log\ 8}{\log\ 7}\times\ \frac{\log\ 9}{\log\ 8}$$
All the terms will cancel out except: $$\frac{\log\ 9}{\log\ 3}=\log_39=2$$
Therefore, 2 is the correct answer.
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