Write 2,784 in expanded notation as the sum of multiplication expressions
for 230 in expanded notation it well look like [2x100]+[3x10]= 200+30= 230
(40x1000)+(7x1000)
(4 * 103) + (7 * 102) + (6 * 101) + (8 * 100).
Expanded notation is a way of writing a number as the sum of its individual place values. For example, the number 3,456 in expanded notation would be written as 3 x 1000 + 4 x 100 + 5 x 10 + 6 x 1.
Expanded Notation of 80 = (8 x 101) + (0 x 100).
Expanded Notation of 525 = (5 x 102) + (2 x 101) + (5 x 100).
Expanded Notation of 456 = (4 x 102) + (5 x 101) + (6 x 100)
Expanded Notation of 2784 = (2 x 103) + (7 x 102) + (8 x 101) + (4 x 100).
Oh honey, it's simple. 14.95 in expanded form is 10 + 4 + 0.9 + 0.05. It's like breaking down a fancy latte into its basic ingredients - no froth or foam, just the cold hard facts.
Write 2,784 in expanded notation as the sum of multiplication expressions
Expanded Notation of 14 = (1 x 10) + (4 x 1)
Expanded Notation of 267,853 = (2 x 105) + (6 x 104) + (7 x 103) + (8 x 102) + (5 x 101) + (3 x 100).
Expanded Notation written using the powers of 10 This is an extension of writing the equation in expanded notation! Therefore I will use the information from that to explain; First I'll do out a table showing powers 10^2 = 100 10 to the power of 2 is One Hundred (2 zero's-after the 1) So hopefully you see the pattern in the above table!
250,000 = (2 x 100000) + (5 x 10000) + (0 x 1000) + (0 x 100) + (0 x 10) + (0 x 1)
for 230 in expanded notation it well look like [2x100]+[3x10]= 200+30= 230
Expanded Notation of 65 = (6 x 10) + (5 x 1).