Everyday Math and Algorithms A Look at the Steps in Completing the Focus Algorithms

Partial Sums An Addition Algorithm

Add the hundreds ( ) Add the tens (60 +80) 140 Add the ones (8 + 3) Add the partial sums ( )

Add the hundreds ( ) Add the tens (80 +40) 120 Add the ones (5 + 1) Add the partial sums ( )

The partial sums algorithm for addition is particularly useful for adding multi-digit numbers. The partial sums are easier numbers to work with, and students feel empowered when they discover that, with practice, they can use this algorithm to add number mentally. The partial sums algorithm for addition is particularly useful for adding multi-digit numbers. The partial sums are easier numbers to work with, and students feel empowered when they discover that, with practice, they can use this algorithm to add number mentally.

An alternative subtraction algorithm

When subtracting using this algorithm, start by going from left to right Ask yourself, “Do I have enough to subtract the bottom number from the top in the hundreds column?” In this problem, does not require regrouping Move to the tens column. I cannot subtract 5 from 3, so I need to regroup Now subtract column by column in any order Move to the ones column. I cannot subtract 6 from 2, so I need to regroup.

Let’s try another one together Now subtract column by column in any order Start by going left to right. Ask yourself, “Do I have enough to take away the bottom number?” In the hundreds column, 7- 4 does not need regrouping. Move to the tens column. I cannot subtract 9 from 2, so I need to regroup. Move to the ones column. I cannot subtract 8 from 5, so I need to trade.

Now, do this one on your own

Last one! This one is tricky!

Partial Products Algorithm for Multiplication Focus Algorithm

Calculate 50 X X 53 Calculate 50 X 7 3, Calculate 3 X 60 Calculate 3 X 7 + Add the results 3,551 To find 67 x 53, think of 67 as and 53 as Then multiply each part of one sum by each part of the other, and add the results

Calculate 10 X X 23 Calculate 20 X Calculate 3 X 10 Calculate 3 X 4 + Add the results 322 Let’s try another one.

Calculate 30 X X 79 Calculate 70 X 8 2, Calculate 9 X 30 Calculate 9 X 8 + Add the results Do this one on your own Let’s see if you’re right.

Partial Quotients A Division Algorithm

The Partial Quotients Algorithm uses a series of “at least, but less than” estimates of how many b’s in a. You might begin with multiples of 10 – they’re easiest There are at least ten 12’s in 158 (10 x 12=120), but fewer than twenty. (20 x 12 = 240) 10 – 1st guess Subtract There are more than three (3 x 12 = 36), but fewer than four (4 x 12 = 48). Record 3 as the next guess 3 – 2 nd guess Sum of guesses Subtract Since 2 is less than 12, you can stop estimating. The final result is the sum of the guesses ( = 13) plus what is left over (remainder of 2 )

Let’s try another one 36 7, – 1st guess - 3,600 4,291 Subtract 100 – 2 nd guess - 3, R7 Sum of guesses Subtract – 3 rd guess – 4th guess - 324

Now do this one on your own. 43 8, – 1st guess - 4, Subtract 90 – 2 nd guess R 15 Sum of guesses Subtract – 3 rd guess – 4th guess - 86

1. Create a grid. Write one factor along the top, one digit per cell. 2. Draw diagonals across the cells. 3.Multiply each digit in the top factor by each digit in the side factor. Record each answer in its own cell, placing the tens digit in the upper half of the cell and the ones digit in the bottom half of the cell. 4. Add along each diagonal and record any regroupings in the next diagonal Write the other factor along the outer right side, one digit per cell.

The lattice algorithm for multiplication has been traced to India, where it was in use before A.D Many Everyday Mathematics students find this particular multiplication algorithm to be one of their favorites. It helps them keep track of all the partial products without having to write extra zeros – and it helps them practice their multiplication facts