Solving Logarithms - Math

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Question

You are given that and .

Which of the following is equal to ?

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Answer

Since and , it follows that and

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Question

$\textup{Solve for }x\textup{: $},\log_{2}$32=x$

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Answer

$\textup{This can be re-written as an exponent problem: } $2^{x}$=32$

$2\times2\times2\times2\times2=32:\textup{ so $}32=2^{5}$:::x=5$

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Question

What is ?

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Answer

Recall that by definition a logarithm is the inverse of the exponential function. Thus, our logarithm corresponds to the value of in the equation:

.

We know that and thus our answer is .

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Question

Solve for :

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Answer

To solve for , first convert both sides to the same base:

Now, with the same base, the exponents can be set equal to each other:

Solving for gives:

$x = $\frac{2}{9}$$

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Question

Solve the equation:

$$\log{_${4}$}{x^${2}$}+$\log{_{4}$$}{3}=1$

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Answer

$$\log{_${4}$}{x^${2}$}+$\log{_{4}$$}{3}=1$

$\Rightarrow $\log{_${4}$}{x^${2}$}+$\log{_{4}$$$}{3}=$\log{_{4}$$}{4}$

$\Rightarrow $\log{_${4}$}{(x^{2}$\times $3)}=$\log{_{4}$$}{4}$

$\Rightarrow $3x^{2}$=4$

$\Rightarrow $x^{2}$=\frac{4}{3}$$

$\Rightarrow x=\frac{2\sqrt{3}$}{3}, x=-$\frac{2\sqrt{3}$}{3}$

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Question

Solve for .

$log_${9}^{ }$(2x+1)=2$

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Answer

Rewrite in exponential form:

Solve for x:

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Question

$\log x+\log\left ( x+21\right )=2$

Solve for .

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Answer

Logs are exponential functions using base 10 and a property is that you can combine added logs by multiplying.

You cannot take the log of a negative number. x=-25 is extraneous.

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Question

Use $\small \small \log_23\approx 1.5850$ to approximate the value of $\small \log_2 24$ .

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Answer

Rewrite as a product that includes the number :

$\small \log_2 24 = \log_2 $(2^3$ \cdot 3)$

Then we can split up the logarithm using the Product Property of Logarithms:

$\small \log_2 $(2^3$\cdot 3) = \log_2 $2^3$ + \log_2 3$

$\small =3+\log_2 3$

$\small \approx 3 + 1.5850$

Thus,

$\small \log_2 24 \approx 4.5850$ .

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Question

Solve for :

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Answer

To solve this logarithm, we need to know how to read a logarithm. A logarithm is the inverse of an exponential function. If a exponential equation is

then its inverse function, or logarithm, is

Therefore, for this problem, in order to solve for , we simply need to solve

which is .

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Question

Solve the following equation:

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Answer

For this problem it is helpful to remember that,

is equivalent to because

Therefore we can set what is inside of the parentheses equal to each other and solve for as follows:

$x=-$\frac{7}{3}$$

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Question

If , which of the following is a possible value for ?

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Answer

This question is testing the definition of logs. is the same as .

In this case, can be rewritten as .

Taking square roots of both sides, you get $x=\pm 6$ . Since only the positive answer is one of the answer choices, is the correct answer.

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Question

Rewriting Logarithms in Exponential Form

Solve for below:

Which of the below represents this function in log form?

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Answer

The first step is to rewrite this equation in log form.

When rewriting an exponential function as a log we must remember that the form of an exponential is:

When this is rewritten in log form it is:

.

Therefore we have which when rewritten gives us,

.

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Question

Solve for $\small x$ :

$\small $\log_{2}$(x+6)=4$

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Answer

Logarithms are another way of writing exponents. In the general case, $\small \log_a{x}=b$ really just means $\small $a^{b}$=x$ . We take the base of the logarithm (in our case, 2), raise it to whatever is on the other side of the equal sign (in our case, 4) and set that equal to what is inside the parentheses of the logarithm (in our case, x+6). Translating, we convert our original logarithm equation into $\small $2^{4}$=x+6$ . The left side of the equation yields 16, thus $\small x=10$ .

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Question

Solve the equation for .

$\log_9(3-x) = \log_9(5x-15)$

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Answer

Because both sides have the same logarithmic base, both terms can be set equal to each other:

Now, evaluate the equation.

First, add x to both sides:

Add 15 to both sides:

Finally, divide by 6: .

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Question

Evaluate .

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Answer

In logarithmic expressions, is the same thing as .

Therefore, the equation can be rewritten as .

Both 8 and 128 are powers of 2, so the equation can then be rewritten as .

Since both sides have the same base, set .

Solve by dividing both sides of the equation by 3: $n=\frac{7}{3}$$ .

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Question

Solve for :

$log_3x=\frac{1}{3}$log_364+\frac{1}{2}$log_349$ .

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Answer

Use the rule of Exponents of Logarithms to turn all the multipliers into exponents:

$log_3x=log_364^$\frac{1}{3}$+log_349^$\frac{1}{2}$$ .

Simplify by applying the exponents: .

According to the law for adding logarithms, .

Therefore, multiply the 4 and 7.

.

Because both sides have the same base, .

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Question

Solve this logarithmic equation:

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Answer

To solve this problem you must be familiar with the one-to-one logarithmic property.

if and only if x=y. This allows us to eliminate to logarithmic functions assuming they have the same base.

one-to-one property:

isolate x's to one side:

move constant:

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Question

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Answer

To solve this equation, remember log rules

.

This rule can be applied here so that

and

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Question

Solve the equation:

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Answer

Get all the terms with e on one side of the equation and constants on the other.

Apply the logarithmic function to both sides of the equation.

$x=\frac{-4+ln2}{3}$$

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Question

Solve the equation:

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Answer

Recall the rules of logs to solve this problem.

First, when there is a coefficient in front of log, this is the same as log with the inside term raised to the outside coefficient.

Also, when logs of the same base are added together, that is the same as the two inside terms multiplied together.

In mathematical terms:

$log(a)+log(b)=log(a\cdot b)$

Thus our equation becomes,

To simplify further use the rule,

$log_b(x)\rightarrow $b^{log_b(x)}$=x$

$x=\pm10$\sqrt{2}$$ .

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