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$$\begin{eqnarray} 32\times 38 &=& 30\times 40 + 2\times 8
\\ 34\times36 &=& 30\times40 + 4\times6\\ 56\times54
&=& 50\times60 + 6\times4\\ 73\times77 &=&
70\times80 + 3\times7\\ \end{eqnarray}$$
Chloe and Nina (Y7) St James Middle School, Bury St Edmunds found
these examples:
$$\begin{eqnarray} 81\times89 &=& 80\times90 + 1\times9 =
7209 \\ 72\times78 &=& 70\times80 + 2\times8 = 5616.\\
\end{eqnarray}$$
HOW WE WORKED IT OUT: The units on the first two numbers have to
add up to 10 to make this work and the second pair of numbers on
the right hand side also have to add up to 10. The tens in the
first product on the right hand side have to be 10 apart.
Suzanne Abbott and Nisha Doshi, (Y10) The Mount School, York proved
that the method always works. Here is their solution:
Yes these are all correct. Here are some more examples
$$\begin{eqnarray} 51\times59 &=& 50\times60 + 1\times9 \\
45\times45 &=& 40\times50 + 5\times5\\ \end{eqnarray}$$
It always seems to work. Using algebra, we can try to generalise
this
$$\begin{eqnarray} (10a + b)(10a + c) &=& 10a \times10(a +
1) + bc \\ 100a^2 +10ac +10ab + bc &=& 100a^2 + 100a + bc\\
10ac + 10ab &=& 100a\\ 10a(b + c) &=& 100a\\ so b +
c &=& 10\\ \end{eqnarray}$$
This fits with the examples we were given and the ones we have
chosen.
This proof depends on the argument being reversible. Set out
slightly differently it shows that the method works if and only if
$b + c = 10$ and it is perfectly rigorous.
$$\begin{eqnarray} (10a + b)(10a + c) &=& 100a^2 + 10ab +
10ac + bc \\ &=& 100a^2 + 100a + bc + 10ab + 10ac -100a \\
&=& 100a^2 + 100a + bc + 10a(b + c - 10)\\ &=&
10a\times 10(a + 1) + bc \\ \end{eqnarray}$$