The title of this section is maybe a little misleading.
The title seems to imply that we’re going to look at equations that involve any radicals. However, we are going to restrict
ourselves to equations involving square roots. The techniques we are going to apply here can
be used to solve equations
with other radicals, however the work is usually significantly messier than
when dealing with square roots. Therefore, we will work only with
square roots in this section.
Before proceeding it should be mentioned as well that
in some Algebra textbooks you will find this section in with the equations reducible to quadratic form material. The
reason is that we will in
fact end up solving a quadratic equation in most cases. However, the approach
is significantly different
and so we’re going to separate the two topics into different section in this
course.
It is usually best to see how these work with an
example.
Example 1 Solve 
.
.
Solution
In this equation the basic problem is the square root.
If that weren’t there we could do the problem. The whole process that we’re going to go through here is set up to
eliminate the square root. However, as we will see, the steps that we’re going to take can actually
cause problems
for us.
So, let’s see how this all works.
Let’s notice that if we just square both sides we can
make the square root go away. Let’s do that and see what happens.
x2 = x + 6
x2 – x – 6 = 0
(x – 3)(x + 2) = 0 ⇒ x = 3, x = –2
Upon squaring both sides we see that we get a
factorable quadratic equation that gives us two solutions x = 3 and x = –2.
Now, for no apparent reason, let’s do something that we
haven’t actually done since the section on solving linear equations. Let’s check our answers. Remember as well that we
need to check
the answers in the original equation! That is very
important.
Let’s first check x = 3.
So x = 3 is a solution. Now let’s check x
= −2.
We have a problem. Recall that square roots are ALWAYS
positive and so x = – 2 does not work in the original equation. One possibility here is that we made a mistake
somewhere. We can go back and look however and we’ll quickly see that we haven’t made a mistake.
So, what is the deal? Remember that our first step in
the solution process was to square both sides. Notice that if we plug x = – 2 into the quadratic we solved it would in fact be a
solution to
that. When we squared both sides of the equation we actually
changed the equation and in the process
introduced a solution that is not a solution to the original equation.
With these problems it is vitally important that you
check your solutions as this will often happen.
When this does we only take the values that are actual
solutions to the original equation.
So, the original equation had a single solution x =
3 .
Now, as this example has shown us, we have to be very
careful in solving these equations. When we
solve the quadratic we will get two solutions and it is possible both of these,
one of these, or none
of these values to be solutions to the original equation. The only way to know
is to check
your solutions!
Let’s work a couple more examples that are a little
more difficult.
Example 2 Solve each of the following equations.
Solution
In this case let’s notice that if we just
square both sides we’re going to have problems.
Before discussing the problem we’ve got here let’s make
sure you can the squaring that we did above since it will show up on occasion. All that we did here was use the
formula.
(a + b)2 = a2
+ 2ab + b2
with a = y and 
. You will need to be able to do these because while this
may not have worked here we will need to this kind of work in the next set of problems.
. You will need to be able to do these because while this
may not have worked here we will need to this kind of work in the next set of problems.
Now, just what is the problem with this? Well recall
that the point behind squaring both sides in the first problem was to eliminate the square root. We haven’t done
that. There is still a square root in the problem and we’ve make the remainder of the problem
messier as well.
So, what we’re going to need to do here is make sure
that we’ve got a square root all by itself on one side of the equation before squaring. Once that is done we can
square both sides and the square
root really will disappear.
Here is the correct way to do this problem.
y – 4 = 16 – 8y + y2
0
= y2 – 8y + y2
0
= (y – 5)(y – 4) ⇒ y = 4, y = 5
As with the first example we will need to make sure and
check both of these solutions. Again, make sure that you check in the original equation. Once we’ve square both sides
we’ve changed the problem and so checking there won’t do us any good. In fact checking there
could well lead us into trouble.
First y = 4 .
So, that is a solution. Now y = 5 .
So, as with the first example we worked there is in
fact a single solution to the original equation, y = 4 .
Okay, so we will again need to get the square root on
one side by itself before squaring both sides.
1 – 2t + t2 = 2t – 3
t2 – 4t + 4 = 0
(t –
2)2 = 0 ⇒ t = 2
So, we have a double root this time. Let’s check it to
see if it really is a solution to the original
equation.
equation.
So, t = 2 isn’t a solution to the original
equation. Since this was the only possible solution, this means that there are no solutions to the original equation. This doesn’t
happen too often, but it does
happen so don’t be surprised by it when it does.
This one will work the same as the previous two.
0 = z2
– z – 2
0 = (z – 2)
(z + 1) ⇒ z – 1, z = 2
Let’s check these possible solutions start with z =
–
1.
So, that’s was a solution. Now let’s check z = 2 .
This was also a solution.
So, in this case we’ve now seen an example where both possible
solutions are in fact solutions to the original equation as well.
So, as we’ve seen in the previous set of examples once
we get our list of possible solutions anywhere from none to all of them can be solutions to the original equation.
Always remember to check
your answers!
Okay, let’s work one more set of examples that have an
added complexity to them. To this point all the equations that we’ve looked at have had a single square
root in them. However, there can be more than one square root in these equations. The next set of
examples is designed to show us how
to deal with these kinds of problems.
Example 3 Solve each of the following
equations.
Solution
In both of these there are two square roots in the problem. We will work these in basically the same manner however. The first step is to get one of the square roots by itself on one side of the equation then square both sides. At this point the process is different so we’ll see how to proceed from this point once we reach it in the first example.
So, the first thing to do is get one of the square
roots by itself. It doesn’t matter which one we get by itself. We’ll end up the same solution(s) in the end.
Now, we still have a square root in the problem, but we
have managed to eliminate one of them.
Not only that, but what we’ve got left here is identical to the examples we
worked in the first part of
this section. Therefore, we will continue now work this problem as we did in
the previous sets of
examples.
x2 –
2x + 1 = 16(x – 4)
x2 –
2x + 1 = 16x – 64
x2 –
18x + 65 = 0
(x – 13)(x
– 5) = 0 ⇒ x =
13, x = 5.
Now, let’s check both possible solutions in the
original equation. We’ll start with x =13.
So, the one is a solution. Now let’s check x = 5
.
So, they are both solutions to the original equation.
In this case we’ve already got a square root on one
side by itself so we can go straight to squaring both sides.
Next, get the remaining square root back on one side by
itself and square both sides again.
16(t +
7) = 64 + 32t + 4t2
16t +
112 = 64 + 32t + 4t2
0 =
4t2 + 16t – 48
0 =
4(t2 + 4t – 12)
0 =
4(t + 6)(t – 2) ⇒ t = – 6, t = 2
Now check both possible solutions starting with t =
2.
So, that wasn’t a solution. Now let’s check t = – 6.
It looks like in this case we’ve got a single solution,
t = – 6.
So, when there is more than one square root in the
problem we are again faced with the task of checking our possible solutions. It is possible that anywhere form none to all
of the possible solutions will in fact be solutions and the only way to know for sure is to
check them in the original equation.
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