Equations with Complex Numbers - Algebra II

Card 0 of 28

Question

Evaluate and simplify .

Answer

The first step is to evaluate the expression. By FOILing the expression, we get:

$=i\cdot i+3i+3i+3\cdot 3$

Now we need to simplify any terms that we can by using the properties of

$i = \sqrt-1$

$i^3 = -\sqrt-1$

Therefore, the expression becomes

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Question

Solve for :

Answer

In order to solve this problem, we need to first simplify our equation. The first thing we should do is distribute the square, which gives us

Now is actually just . Therefore, this becomes

Now all we need to do is solve for in the equation:

$27+\underset{-4i}{36i}=\underset{-4i}{4i}-30z$

which gives us

Finally, we get

$\frac{27+32i}{-30}=\frac{-30z}{-30}$

and therefore, our solution is

$z = \frac{-27-32i}{30}$

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Question

Solve

$2x^{^{2}} - 1 = 2x^{2} +3$

Answer

To solve

$2x^{^{2}} - 1 = 2x^{2} +3$

Subtract $2x^{2}$ from both side:

Which is never true, so there is no solution.

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Question

are real numbers.

$4x+ \left (3y+ 4 \right ) i = 21 + 7i$

Evaluate .

Answer

For two imaginary numbers to be equal to each other, their imaginary parts must be equal. Therefore, we set, and solve for in:

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Question

Solve for and :

$ai^{93}+bi^{35}+ai^{24}-bi^{86}=40+20i$

Answer

Remember that

$i = \sqrt{-1}\ i^2 = \sqrt{-1}^2 = -1\ i^3 = i^2\cdot i = -1 \cdot i = -i\ i^4 = i^2 \cdot i^2 = (-1)\cdot(-1) = 1\ i^5 = i^4\cdot i = 1\cdot i = i = \sqrt{-1}\ i^6 = i^4\cdot i^2 = 1\cdot i^2 = i^2 =-1$

So the powers of are cyclic.This means that when we try to figure out the value of an exponent of , we can ignore all the powers that are multiples of because they end up multiplying the end result by , and therefore do nothing.

This means that

$ai^{93} + bi^{35} + ai^{24} - bi^{86}\ = ai^{92+1} + bi^{32+3} + ai^{24+0} - bi^{84+2}\ = ai^{92}\cdot i^1 + bi^{32}\cdot i^3 + ai^{24}\cdot i^0 - bi^{84}\cdot i^2\ =a(i^4)^{23}\cdot i^1 + b(i^4)^8\cdot i^3 + a(i^4)^6\cdot i^0 - b(i^4)^{21}\cdot i^2\ = a (1^{23})\cdot i + b(1^8)\cdot i^3 + a(1^6) - b(1^{21})\cdot i^2$

Now, remembering the relationships of the exponents of , we can simplify this to:

$ai - bi + a - (-b) = ai-bi+a+b\ = (a+b) + (a-b)i = 40+20i$

Because the elements on the left and right have to correspond (no mixing and matching!), we get the relationships:

No matter how you solve it, you get the values , .

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Question

If $\small x$ and $\small y$ are real numbers, and $\small \small 3x+y+(2x+2y)i=13+10i$ , what is $\small z$ if $\small z=x-4y$ ?

Answer

To solve for $\small z$ , we must first solve the equation with the complex number for $\small x$ and $\small y$ . We therefore need to match up the real portion of the compex number with the real portions of the expression, and the imaginary portion of the complex number with the imaginary portion of the expression. We therefore obtain:

$\small 3x+y=13$ and $\small 2x+2y=10$

We can use substitution by noticing the first equation can be rewritten as $\small y=13-3x$ and substituting it into the second equation. We can therefore solve for $\small x$ :

$\small 2x+2(13-3x)=10$

$\small 2x+26-6x=10$

$\small -4x=-16$

$\small x=4$

With this $\small x$ value, we can solve for $\small y$ :

$\small 3(4)+y=13$

$\small 12+y=13$

$\small y=1$

Since we now have $\small x$ and $\small y$ , we can solve for $\small z$ :

$\small z=x-4y$

$\small \small z=(4)-4(1)=0$

Our final answer is therefore $\small z=0$

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Question

Solve for if $x = 4\cdot \left ( i^2 + 3\right )$ .

Answer

Go about this problem just like any other algebra problem by following your order of operations. We will first evaluate what is inside the parentheses: . At this point, we need to know the properties of which are as follows:

$i = \sqrt{-1}$

$i^3 = -\sqrt{-1}$

Therefore, and the original expression becomes $x = 4 \cdot (2) = 8$

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Question

Solve for :

Answer

In order to solve this problem, we need to first simplify our equation. The first thing we should do is distribute the square, which gives us

Now is actually just . Therefore, this becomes

Now all we need to do is solve for in the equation:

$27+\underset{-4i}{36i}=\underset{-4i}{4i}-30z$

which gives us

Finally, we get

$\frac{27+32i}{-30}=\frac{-30z}{-30}$

and therefore, our solution is

$z = \frac{-27-32i}{30}$

Compare your answer with the correct one above

Question

are real numbers.

$4x+ \left (3y+ 4 \right ) i = 21 + 7i$

Evaluate .

Answer

For two imaginary numbers to be equal to each other, their imaginary parts must be equal. Therefore, we set, and solve for in:

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Question

Solve for and :

$ai^{93}+bi^{35}+ai^{24}-bi^{86}=40+20i$

Answer

Remember that

$i = \sqrt{-1}\ i^2 = \sqrt{-1}^2 = -1\ i^3 = i^2\cdot i = -1 \cdot i = -i\ i^4 = i^2 \cdot i^2 = (-1)\cdot(-1) = 1\ i^5 = i^4\cdot i = 1\cdot i = i = \sqrt{-1}\ i^6 = i^4\cdot i^2 = 1\cdot i^2 = i^2 =-1$

So the powers of are cyclic.This means that when we try to figure out the value of an exponent of , we can ignore all the powers that are multiples of because they end up multiplying the end result by , and therefore do nothing.

This means that

$ai^{93} + bi^{35} + ai^{24} - bi^{86}\ = ai^{92+1} + bi^{32+3} + ai^{24+0} - bi^{84+2}\ = ai^{92}\cdot i^1 + bi^{32}\cdot i^3 + ai^{24}\cdot i^0 - bi^{84}\cdot i^2\ =a(i^4)^{23}\cdot i^1 + b(i^4)^8\cdot i^3 + a(i^4)^6\cdot i^0 - b(i^4)^{21}\cdot i^2\ = a (1^{23})\cdot i + b(1^8)\cdot i^3 + a(1^6) - b(1^{21})\cdot i^2$

Now, remembering the relationships of the exponents of , we can simplify this to:

$ai - bi + a - (-b) = ai-bi+a+b\ = (a+b) + (a-b)i = 40+20i$

Because the elements on the left and right have to correspond (no mixing and matching!), we get the relationships:

No matter how you solve it, you get the values , .

Compare your answer with the correct one above

Question

If $\small x$ and $\small y$ are real numbers, and $\small \small 3x+y+(2x+2y)i=13+10i$ , what is $\small z$ if $\small z=x-4y$ ?

Answer

To solve for $\small z$ , we must first solve the equation with the complex number for $\small x$ and $\small y$ . We therefore need to match up the real portion of the compex number with the real portions of the expression, and the imaginary portion of the complex number with the imaginary portion of the expression. We therefore obtain:

$\small 3x+y=13$ and $\small 2x+2y=10$

We can use substitution by noticing the first equation can be rewritten as $\small y=13-3x$ and substituting it into the second equation. We can therefore solve for $\small x$ :

$\small 2x+2(13-3x)=10$

$\small 2x+26-6x=10$

$\small -4x=-16$

$\small x=4$

With this $\small x$ value, we can solve for $\small y$ :

$\small 3(4)+y=13$

$\small 12+y=13$

$\small y=1$

Since we now have $\small x$ and $\small y$ , we can solve for $\small z$ :

$\small z=x-4y$

$\small \small z=(4)-4(1)=0$

Our final answer is therefore $\small z=0$

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Question

Solve for if $x = 4\cdot \left ( i^2 + 3\right )$ .

Answer

Go about this problem just like any other algebra problem by following your order of operations. We will first evaluate what is inside the parentheses: . At this point, we need to know the properties of which are as follows:

$i = \sqrt{-1}$

$i^3 = -\sqrt{-1}$

Therefore, and the original expression becomes $x = 4 \cdot (2) = 8$

Compare your answer with the correct one above

Question

Evaluate and simplify .

Answer

The first step is to evaluate the expression. By FOILing the expression, we get:

$=i\cdot i+3i+3i+3\cdot 3$

Now we need to simplify any terms that we can by using the properties of

$i = \sqrt-1$

$i^3 = -\sqrt-1$

Therefore, the expression becomes

Compare your answer with the correct one above

Question

Solve

$2x^{^{2}} - 1 = 2x^{2} +3$

Answer

To solve

$2x^{^{2}} - 1 = 2x^{2} +3$

Subtract $2x^{2}$ from both side:

Which is never true, so there is no solution.

Compare your answer with the correct one above

Question

Solve for :

Answer

In order to solve this problem, we need to first simplify our equation. The first thing we should do is distribute the square, which gives us

Now is actually just . Therefore, this becomes

Now all we need to do is solve for in the equation:

$27+\underset{-4i}{36i}=\underset{-4i}{4i}-30z$

which gives us

Finally, we get

$\frac{27+32i}{-30}=\frac{-30z}{-30}$

and therefore, our solution is

$z = \frac{-27-32i}{30}$

Compare your answer with the correct one above

Question

are real numbers.

$4x+ \left (3y+ 4 \right ) i = 21 + 7i$

Evaluate .

Answer

For two imaginary numbers to be equal to each other, their imaginary parts must be equal. Therefore, we set, and solve for in:

Compare your answer with the correct one above

Question

Solve for and :

$ai^{93}+bi^{35}+ai^{24}-bi^{86}=40+20i$

Answer

Remember that

$i = \sqrt{-1}\ i^2 = \sqrt{-1}^2 = -1\ i^3 = i^2\cdot i = -1 \cdot i = -i\ i^4 = i^2 \cdot i^2 = (-1)\cdot(-1) = 1\ i^5 = i^4\cdot i = 1\cdot i = i = \sqrt{-1}\ i^6 = i^4\cdot i^2 = 1\cdot i^2 = i^2 =-1$

So the powers of are cyclic.This means that when we try to figure out the value of an exponent of , we can ignore all the powers that are multiples of because they end up multiplying the end result by , and therefore do nothing.

This means that

$ai^{93} + bi^{35} + ai^{24} - bi^{86}\ = ai^{92+1} + bi^{32+3} + ai^{24+0} - bi^{84+2}\ = ai^{92}\cdot i^1 + bi^{32}\cdot i^3 + ai^{24}\cdot i^0 - bi^{84}\cdot i^2\ =a(i^4)^{23}\cdot i^1 + b(i^4)^8\cdot i^3 + a(i^4)^6\cdot i^0 - b(i^4)^{21}\cdot i^2\ = a (1^{23})\cdot i + b(1^8)\cdot i^3 + a(1^6) - b(1^{21})\cdot i^2$

Now, remembering the relationships of the exponents of , we can simplify this to:

$ai - bi + a - (-b) = ai-bi+a+b\ = (a+b) + (a-b)i = 40+20i$

Because the elements on the left and right have to correspond (no mixing and matching!), we get the relationships:

No matter how you solve it, you get the values , .

Compare your answer with the correct one above

Question

If $\small x$ and $\small y$ are real numbers, and $\small \small 3x+y+(2x+2y)i=13+10i$ , what is $\small z$ if $\small z=x-4y$ ?

Answer

To solve for $\small z$ , we must first solve the equation with the complex number for $\small x$ and $\small y$ . We therefore need to match up the real portion of the compex number with the real portions of the expression, and the imaginary portion of the complex number with the imaginary portion of the expression. We therefore obtain:

$\small 3x+y=13$ and $\small 2x+2y=10$

We can use substitution by noticing the first equation can be rewritten as $\small y=13-3x$ and substituting it into the second equation. We can therefore solve for $\small x$ :

$\small 2x+2(13-3x)=10$

$\small 2x+26-6x=10$

$\small -4x=-16$

$\small x=4$

With this $\small x$ value, we can solve for $\small y$ :

$\small 3(4)+y=13$

$\small 12+y=13$

$\small y=1$

Since we now have $\small x$ and $\small y$ , we can solve for $\small z$ :

$\small z=x-4y$

$\small \small z=(4)-4(1)=0$

Our final answer is therefore $\small z=0$

Compare your answer with the correct one above

Question

Solve for if $x = 4\cdot \left ( i^2 + 3\right )$ .

Answer

Go about this problem just like any other algebra problem by following your order of operations. We will first evaluate what is inside the parentheses: . At this point, we need to know the properties of which are as follows:

$i = \sqrt{-1}$

$i^3 = -\sqrt{-1}$

Therefore, and the original expression becomes $x = 4 \cdot (2) = 8$

Compare your answer with the correct one above

Question

Evaluate and simplify .

Answer

The first step is to evaluate the expression. By FOILing the expression, we get:

$=i\cdot i+3i+3i+3\cdot 3$

Now we need to simplify any terms that we can by using the properties of

$i = \sqrt-1$

$i^3 = -\sqrt-1$

Therefore, the expression becomes

Compare your answer with the correct one above

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