2.03 Write and represent multistep equations

Four less than twice a number equals the same number increased by six

Represent the 'number' with a variable. 'Less' indicates subtraction. 'Twice' means multiply by 2, and 'increased' indicates addition.

Choosing the variable x as our variable and the term equals separating our expressions, we can write the equation:2x-4=x+6

An equation represents a balance between two expressions. On one side, we start with twice a number, reduce it by four, and on the other, we simply add six to the same number. This following scale helps visualize the equation.

The product of six and the sum of a number and three is the difference of the number and twelve

Use a variable to represent the 'number'. 'Product' indicates multiplication, 'sum' means addition, and 'difference' means subtraction.

Notice, we are finding the product of a sum. So we need to multiply the entire sum x+3 by 6. This will require us to use parentheses: 6(x+3).

Choosing the variable x as our variable and the term is separating our expressions, we write the equation:6(x+3)=x-12

To better understand our equation 6\left(x+3\right)=x-12, let's visualize it using algebra tiles.

On one side of the equation, we have 6\left(x+3\right), which represents six groups of x+3. This visually shows the repeated addition that is caused by multiplication.

On the other side of the equation, we have x-12, represented by one x tile and twelve negative unit tiles.

The quotient of four more than triple a number and two is nine

Use a variable to represent the 'number'. 'Quotient' indicates division, 'triple' means multiplied by 3, and 'more than' indicates addition.

The word and acts as the separator between the numerator and denominator for the fraction representing the quotient. This tells us that 'four more than triple a number' is the numerator and 'two' is the denominator.

Using the word is to separate the expressions, we have the equation\dfrac{3x+4}{2}= 9

We can visualize the equation using algebra tiles. On the left are three x tiles and four 1 tiles, half grayed-out to represent dividing by 2. This is equal to nine 1 tiles on the right.

Write an algebraic equation to represent the situation.

Let's assign a variable to represent the cost of one notebook. Since the binder costs twice as much as a notebook and a pack of pens costs the same as six notebooks, we can write the costs of the binder and pens in terms of the notebook's cost. Finally, we'll use the total amount Carrie can spend to set up our equation.

We know the sum of everything Carrie buys is \$30, so:

6 \text{ notebooks} + 2 \text{ pens} + 1 \text{ binder} = \$30

Let n represent the cost of one notebook in dollars. So the cost of 6 notebooks is 6n.

The cost of one pack of pens is the same as the cost of 6 notebooks or 6n, so the cost of 2 packs of pens is 2 \cdot 6n.

The cost of one binder twice (or two times) the cost of a notebook, n, so the cost of a binder is 2n.

Adding these up and setting them equal to \$30 we get the equation: 6n + 2\cdot6n + 2n = 30

Draw a pictorial model to represent the equation you wrote in part (a).

To create a pictorial model of the equation, we will use visual representations for each component of the shopping list: notebooks, packs of pens, and the binder.

Let's use a circle to represent a notebook, a square for a pack of pens, and a triangle for the binder.

Since the binder costs twice as much as a notebook, we'll place two circles inside the triangle to show this relationship. Similarly, a pack of pens, costing the same as six notebooks, will have six circles within a square.

Carrie plans to buy 6 notebooks (6 circles), 2 packs of pens (2 squares, each containing 6 circles), and 1 binder (1 triangle containing 2 circles). The total cost represented by these symbols must equal the total cost of \$30.

Carrie solves the equations using the information she knows. Her value for n is 1.5. Verify and interpret the solution.

To verify Carrie's solution, we'll substitute her value for n into our the equation and see if the result matches the total cost of \$30 .

Substituting x = 1.5 into the equation:

\begin{aligned} 6\left(1.5\right) + 2\cdot6\left(1.5\right) + 2\left(1.5\right)&=30\\\\ 9+18+3 &= 30 \\\\ 30 &=30 \end{aligned}

This shows that the value of 1.5 for x makes the equation true, so it is the solution.