Systems of equations - Exercises | IB Math AAHL | Perplex

Systems of equations

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Systems of equations with 2 unknowns

SL Core 2.1

We can solve a system of 2 equations and 2 unknowns with different methods.

{3y+2x−2=03y−3x+1=0

By substitution

Rearranging

3y+2x−2=0⇒y=−32x+32

Substituting this into 3y−3x+1=0:

(−2x+2)−3x+1=0

−5x=−3

So x=53, which implies y=−32⋅53+32=154. So the intersection is (53,154).

By elimination

We can eliminate y from the equations by subtracting the second from the first:

(3y+2x−2)−(2y−3x+1)2x−2+3x−15x=0=0=3

So x=53⇒y=154 and the intersection is again (53,154).

We can use either of these methods to systems of equations with 2 equations and 2 unknowns.

Solving systems of equations with 3 unknowns

AHL AA 1.16

Systems of 3 equations with 3 unknowns, for example

(1)(2)(3)⎩⎪⎨⎪⎧2x−3y+4z=85x+2y−z=63x+4y+2z=17

can be solved with a calculator, or by using substitution.

Worked solution

For the system above, equation (2) is a convenient place to start, because it contains just −z, so it is easy to rearrange for z:

z=5x+2y−6

Now substitute this expression for z into equations (1) and (3).

2x−3y+4(5x+2y−6)=8

22x+5y=32

Using equation (3):

3x+4y+2(5x+2y−6)=17

13x+8y=29

We know have a system of 2 equations with 2 unknowns. Eliminate y by taking

8(22x+5y)−5(13x+8y)=8⋅32−5⋅29

176x+40y−65x−40y=256−145

111x=111

x=1

Now substitute x=1 into 13x+8y=29:

13(1)+8y=29

y=2

Finally, substitute x=1 and y=2 into z=5x+2y−6:

z=5(1)+2(2)−6

z=3

So the solution is x=1,y=2,z=3.

Solution count for 3 by 3 systems of equations

AHL AA 1.16

A system of 3 equations with 3 unknowns can have

no solutions
a unique solution
infinitely many solutions

Example

Consider the system of equations

(1)(2)(3)⎩⎪⎨⎪⎧x+2y−z=1−x−y−z=−1x+ay+2z=2

Add equations (1) and (2):

y−2z=0

y=2z

Now add equations (2) and (3):

(a−1)y+z=1

Substitute y=2z:

(a−1)(2z)+z=1

(2a−1)z=1

If 2a−1=0, then we can solve for

z=2a−11

and then find y and z. This represents a unique solution.

But if 2a−1=0, ie a=21, then we have 0z=1, to which there are no solutions.

Nice work completing Systems of equations, here's a quick recap of what we covered:

Skills covered

Mixed Practice

Exercises checked off

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Partial fractions

Algebra Skills

Systems of equations

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Want a deeper conceptual understanding? Try our interactive lesson!

Systems of equations with 2 unknowns

SL Core 2.1

We can solve a system of 2 equations and 2 unknowns with different methods.

{3y+2x−2=03y−3x+1=0

By substitution

Rearranging

3y+2x−2=0⇒y=−32x+32

Substituting this into 3y−3x+1=0:

(−2x+2)−3x+1=0

−5x=−3

So x=53, which implies y=−32⋅53+32=154. So the intersection is (53,154).

By elimination

We can eliminate y from the equations by subtracting the second from the first:

(3y+2x−2)−(2y−3x+1)2x−2+3x−15x=0=0=3

So x=53⇒y=154 and the intersection is again (53,154).

We can use either of these methods to systems of equations with 2 equations and 2 unknowns.

Solving systems of equations with 3 unknowns

AHL AA 1.16

Systems of 3 equations with 3 unknowns, for example

(1)(2)(3)⎩⎪⎨⎪⎧2x−3y+4z=85x+2y−z=63x+4y+2z=17

can be solved with a calculator, or by using substitution.

Worked solution

For the system above, equation (2) is a convenient place to start, because it contains just −z, so it is easy to rearrange for z:

z=5x+2y−6

Now substitute this expression for z into equations (1) and (3).

2x−3y+4(5x+2y−6)=8

22x+5y=32

Using equation (3):

3x+4y+2(5x+2y−6)=17

13x+8y=29

We know have a system of 2 equations with 2 unknowns. Eliminate y by taking

8(22x+5y)−5(13x+8y)=8⋅32−5⋅29

176x+40y−65x−40y=256−145

111x=111

x=1

Now substitute x=1 into 13x+8y=29:

13(1)+8y=29

y=2

Finally, substitute x=1 and y=2 into z=5x+2y−6:

z=5(1)+2(2)−6

z=3

So the solution is x=1,y=2,z=3.

Solution count for 3 by 3 systems of equations

AHL AA 1.16

A system of 3 equations with 3 unknowns can have

no solutions
a unique solution
infinitely many solutions

Example

Consider the system of equations

(1)(2)(3)⎩⎪⎨⎪⎧x+2y−z=1−x−y−z=−1x+ay+2z=2

Add equations (1) and (2):

y−2z=0

y=2z

Now add equations (2) and (3):

(a−1)y+z=1

Substitute y=2z:

(a−1)(2z)+z=1

(2a−1)z=1

If 2a−1=0, then we can solve for

z=2a−11

and then find y and z. This represents a unique solution.

But if 2a−1=0, ie a=21, then we have 0z=1, to which there are no solutions.

Nice work completing Systems of equations, here's a quick recap of what we covered:

Skills covered

Mixed Practice

Exercises checked off

I'm Plex, here to help you understand this concept!