This question is from a free aptitude test on naukri.com (image)
This question is based upon the figure shown below.
$$ \begin{array}{|ccc|c|ccc|c|ccc|} \; & 41 & \; & \; & \; & 31 & \; & \; & \; & ? & \; \\ 5 & \; & 6 & \; & 9 & \; & 4 & \; & 8 & \; & 7 \\ 7 & \; & 8 & \; & 2 & \; & 6 & \; & 2 & \; & 6 \\ \end{array}$$
- a. 51
- b. 62
- c. 48
- d. 53
Question:
Find the missing number on the basis of the pattern of figures shown above.
I found a pattern, which I personally do not like because it uses two additional constants, but: 1. it is simple, 2. it takes into account all given numbers and 3. it provides expected result. I post this answer because there is not other working pattern was suggested up to now.
Let's name the numbers in pentagon like:
E
a b
c d
Then for each pentagon: $E = 10\times(a+b+c-d)-59$.
In this case the answer is 51.
This answer somewhat works, but part of the logic seems a bit arbitrary, so maybe I am missing something.
5/7 + 6/8 = 82/56 = 41/28. The numerator 41 matches the top number in the first figure.
9/2 + 4/6 = 62/12 = 31/6. The numerator 31 matches the top number in the second figure.
8/2 + 7/6 = 62/12 = 31/6. 31 isn't a choice for the answer, but 62 is. Why we don't reduce the fraction in this case I do not know.
a) The answer is obviously 51. The topmost number is decremented by 10 every step with an odd number, and incremented by 20 on every step with an even number.
b) The answer is obviously 62. The topmost number is decremented by 10 every step with an odd number, and doubled on every step with an even number.
c) The answer is obviously 48. The topmost number is decremented by 10 every step with an odd number, and incremented by 17 on every step with an even number.
d) The answer is obviously 53. In every third image it is set to the constant 53.
Edit: My answer isn't even on the list of options. My bad, scrap this. I totally read the 51 as a 31.
Even though this question is old and hasn't seen much action recently, it bothers me that the accepted answer uses additional constants when there is a much simpler solution. It can be stated in one line:
The top number is equal to the average of the products of the diagonal numbers.
This can be expressed as the following equation:
E = ((a * d) + (b * c))/2,
where the pentagon is represented by the variables shown below.
E
a b
c d
For the first pentagon: ((5 * 8) + (6 * 7))/2 = (40 + 42)/2 = 41
For the second: ((9 * 6) + (4 * 2))/2 = (54 + 8)/2 = 31
And for the unknown: ((8 * 6) + (7 * 2))/2 = (48 + 14)/2 = 31
Therefore the answer is 31.
I looked for solutions that use only products, additions and subtractions, without any magical constants.
With the numbers
a b
c d
I look for possible solutions of the form
x1*a + x2*b + x3*c + x4*d +
x5*a*a + x6*b*b + x7*c*c + x8*d*d +
x9*a*b + x10*a*c + x11*a*d +
x12*b*c + x13*b*d + x14*c*d
Where xN in [-1,0,1]
There are a total of 3**14 = 4782969 possible combinations and only 88 of those work for both of the first two examples. Out of those 88 there is at least one solution for each of possible answers:
+a -b +d +bc + bd +cd = 41/31/51
-a -b +bb -cc -ab -ac +ad +bc +bd = 41/31/62
-a -b +c +bb +cc -ab +ad -bc +bd -cd = 41/31/48
-a +b +d +bb -ab +ad +bc -cd = 41/31/48
+a +b +d -dd +ab +cd = 41/31/53
None of those stands out for being especially simple or symmetric, but c:48 has twice as many solutions as the others, which tips the scales slightly in its favor.
(5+7+6+8)*2-11=41
(9+2+4+6)*2-11=31
but
(8+2+7+6)*2-11=35
Not the answer looking for but just can be another soln
First I got the above two then I found this.
Wild guess here - but it still could be a pattern
41 // 4 + 1 = 5 (answer is on top-left) 31 // 3 + 1 = 4 (answer is on top-right) 51 // 5 + 1 = 6 (answer is on bottom-right)
Maybe the pattern here is that the answer to adding each digit of the topmost number from each image is moving clockwise for each image.
^Not sure if that makes sense... But I tried. Would be nice if you tell us the answer if you found it :D
Let's say $41$ is the top number and $a=5,b=6,c=7,d=8$.
$$\begin{align} cb-41 + ad &= 41\\ cb-31 + ad &= 31\\ cb-x + ad &= x\\ \implies 14-x+48 &= x\\ 2x &= 62\\ x&=31 \end{align}$$
therefore answer is $31$.
How about something a little simpler. Using the variable names for the numbers as above:
$$\begin{array}{ccc} &E\\ a&&b\\ c&&d \end{array}$$
Steps:
Solutions for $E$:
$$\begin{align} 5+6+7+8 &= 26 &&\rightarrow \text{Subtract:}\ 6-2 = 4 &\rightarrow \text{Append:}\ 41.\\ 9+4+2+6 &= 21 &&\rightarrow \text{Add:}\ 2+1 = 3 &\rightarrow \text{Append:}\ 31.\\ 8+7+2+6 &= 23 &&\rightarrow \text{Add:}\ 2+3 = 5 &\rightarrow \text{Append:}\ 51. \end{align}$$
I may not be correct but just let me know if I have a mistake in my logic.
My thought is that I consider them as sequence with $15,10,25,10,35$ and so on...
Therefore,
$$41-(5+6+7+8) = 15$$
$$31- (9+4+2+6) = 10$$
$$X - (8+7+2+6) = 25$$
Hence, I think $48$ is my answer.
