Four Fours: Difference between revisions

Revision as of 00:54, 10 April 2017

Four Fours

The goal of this puzzle is to combine 4 4's with any other mathematical symbol, excepting numbers, to produce every whole number from 1 to 20.

You can extend this to 5 5's, and 6 6's, and so on.

A good strategy is to compile a long list of all the numbers you get when you combine one 4, two 4's, three 4's, and so on. This helps you chain together expressions.

Numbers Puzzle/Table of 4s - a table of various combinations of 4s

Starting with 4s:

$1 = \dfrac{4+4}{4+4}$

$2 = \dfrac{4 \times 4}{4 + 4}$

$3 = \dfrac{4 + 4 + 4}{4}$

$5 = \dfrac{4 \times 4 + 4}{4}$

$6 = 4 = \dfrac{4+4}{4}$

$6 = 4 \times \dfrac{ \ln{\left( \sqrt{4+4} \right)} }{ \ln{\sqrt{4}} }$

$7 = 4 + \sqrt{4} + \dfrac{4}{4}$

$8 = 4 + 4 \left( \dfrac{4}{4} \right)$

$8 = \sqrt{4} + \sqrt{4} + \sqrt{4} + \sqrt{4}$

$9 = 4 + 4 + \dfrac{4}{4}$

$10 = 4 + 4 + 4 - \sqrt{4}$

$11 = (4 \times 4) - (4 + \dfrac{4}{4})$

$11 = \dfrac{44}{\sqrt{4} \sqrt{4}}$

$12 = 4 + 4 + \sqrt{4} + \sqrt{4}$

$13 = \dfrac{44}{4} + \sqrt{4}$

$14 = 4 \times \sqrt{4} \times \sqrt{4} - \sqrt{4}$

$15 = 4 \times 4 - \dfrac{4}{4}$

$16 = \sqrt{4} \sqrt{4} \sqrt{4} \sqrt{4}$

$$ 16 = 4 + 4 + 4 + 4 $$

$17 = 4 \times 4 + \dfrac{4}{4}$

$18 = 4 \times 4 + \dfrac{4}{\sqrt{4}}$

$18 = 4^{\sqrt{4}} + \dfrac{4}{\sqrt{4}}$

$19 = 4 \times 4 + 4 - i^{4}$

$20 = 4 \times 4 + \sqrt{ 4 \times 4 }$

$20 = \sqrt{4} \sqrt{4} + 4^{\sqrt{4}}$

$21 = 4 \times 4 + 4 + i^{4}$

$22 = \dfrac{ \ln{ \left( \left(\sqrt{4}\right)^{44} \right) } }{ \ln{(4)} }$

$23 = 4! - i^{4}$

$24 = 4! \times i^{4}$

$25 = 4! + i^{4}$

$26 = 4! + \dfrac{4+4}{4}$

$27 = 4! + \dfrac{ \ln{(4+4)} }{ \ln{\sqrt{4}} }$

$28 = 4 (\sqrt{4} + i^{4} + 4)$

$29 = 4! + 4 + \dfrac{4}{4}$

$30 = (4 + i^4)(4 + \sqrt{4})$

$$ 31 = 4 ( 4 + 4 ) - i^4 $$

$32 = \dfrac{ 4 \times 4 \times 4 }{ \sqrt{4} }$

$$ 33 = 4 ( 4 + 4 ) + i^4 $$

$34 = 4(4+4) + \sqrt{4}$

$35 = (4+\sqrt{4})^{\sqrt{4}} - i^4$

$36 = \left( 4 + \dfrac{4}{\sqrt{4}} \right)^{\sqrt{4}}$

$36 = 4 \left( \sqrt{4} + i^{4} \right)^{\sqrt{4}}$

$36 = 4 \left( 4 \sqrt{4} + i^4 \right)$

$$ 36 = 4! + 4 + 4 + 4 $$

$37 = (4+\sqrt{4})^{\sqrt{4}}$

$38 = \left( 4 + \sqrt{4} \right)^{\sqrt{4}} + \sqrt{4}$

$39 = 4! + 4 \times 4 - i^4$

$40 = 4 (4+4+\sqrt{4})$

$$ 40 = (4+4)(4+i^4) $$

$41 = 4! + 4 \times 4 + i^4$

$42 = (4!)(\sqrt{4}) - (4+\sqrt{4})$

$43 = (4!)(\sqrt{4}) - (4+i^4)$

$44 = (4!)(\sqrt{4}) - (\sqrt{4} + \sqrt{4})$

$44 = \sqrt{4} \left( 4! - \dfrac{4}{\sqrt{4}} \right)$

Five Fives

Extending this idea, we can take a crack at the game of Five Fives.

$5 = \dfrac{ \sqrt{5}^{\sqrt{5}} \sqrt{5} }{ 5 \times 5 }$

$6 = 5 + \dfrac{5 \times 5}{5 \times 5}$

$7 = 5 + \dfrac{5}{5} + \dfrac{5}{5}$

$8 = 5 + \dfrac{5+5+5}{5}$

$9 = \sqrt{5} \sqrt{5} + 5 - \dfrac{5}{5}$

$10 = \dfrac{5 \times 5 + 5 \times 5}{5}$

$11 = \dfrac{5 \times 5 + 5}{5} + 5$

$12 = 5 + 5 + \dfrac{5+5}{5}$

$13 = 5 + 5 + 5 - \dfrac{ \ln{5} }{ \ln{\sqrt{5}} }$

$14 = 5 + 5 + 5 - \dfrac{5}{5}$

$15 = \left( \dfrac{5+5}{5} \right) \times 5 + 5$

$16 = 5 + 5 + 5 + \dfrac{5}{5}$

$17 = 5 + 5 + 5 + \dfrac{ \ln{5} }{ \ln{\sqrt{5}} }$

$18 = 5 \times 5 - 5 - \dfrac{\ln{5}}{\ln{\sqrt{5}}}$

$19 = 5 \times 5 - 5 - \dfrac{5}{5}$

$20 = \dfrac{5}{5} \left( 5 \times 5 - 5 \right)$

@@ Line 194: / Line 194: @@
 <math>
-=
+= (4+\sqrt{4})^{\sqrt{4}}
 </math>
 <math>
-=
+= \left( 4 + \sqrt{4} \right)^{\sqrt{4}} + \sqrt{4}
 </math>
 <math>
-=
+= 4! + 4 \times 4 - i^4
 </math>
 <math>
-=
+= 4 (4+4+\sqrt{4})
+</math>
+<math>
+= (4+4)(4+i^4)
+</math>
+<math>
+= 4! + 4 \times 4 + i^4
+</math>
+<math>
+= (4!)(\sqrt{4}) - (4+\sqrt{4})
+</math>
+<math>
+= (4!)(\sqrt{4}) - (4+i^4)
+</math>
+<math>
+= (4!)(\sqrt{4}) - (\sqrt{4} + \sqrt{4})
+</math>
+<math>
+= \sqrt{4} \left( 4! - \dfrac{4}{\sqrt{4}} \right)
 </math>

Four Fours: Difference between revisions

From charlesreid1

Revision as of 00:54, 10 April 2017

Four Fours

Five Fives