# What is the logic for solving this sequence? [closed]

The sequence goes like this.. `7,8,77,78,87,88,777,778,787,788` and so on..

What can be the logic for finding the nth number of the sequence? I tried that by dividing it by 2 and then by 4 and hence, but it doesn't seem to work.

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People who vote to close it: how is algorithm for finding n-th element of sequence is off-topic? –  Nikita Rybak Sep 9 '10 at 20:07
It'd be nice if people commented but if i had to guess it's that it smells like homework and a complete answer rather than a hint is being asked for. –  Paul Sasik Sep 9 '10 at 20:18
@Nikita Rybak: It doesn't make sense to have a n-th element algorithm. Any sequence can continue in any way. –  Thomas Ahle Sep 9 '10 at 20:23
Consider this sequence: [0, 1, 00, 01, 10, 11, 000, 001, 010, 011]. It's the same as yours. –  Thomas Ahle Sep 9 '10 at 20:25
@Thomas: It does seem to have a certain similarity, but that doesn't really explain the reason to close. What about that sequence is unworthy of being in a question? –  recursive Sep 9 '10 at 20:29

## closed as off topic by Henk Holterman, Roger Pate, bmargulies, ho1, Michael PetrottaSep 12 '10 at 2:41

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Observations:

1. The sequence appears to be an ascending list of numbers containing only the digits 7 and 8.

2. The number of digits is non-decreasing and for each n-digit section, there are `2 ** n` numbers in the sequence.

3. The first half of the n-digit numbers starts with 7, and the second half starts with 8.

4. For each half of the n-digit numbers, the remaining digits after the first are the same as the n-1 digit numbers.

These facts can be used to construct a reasonably efficient recursive implementation.

Here is a C# implementation:

``````void Main() {
for (int i = 0; i < 10; i++)
Console.WriteLine (GetSequence(i));
}

string GetSequence(int idx) {
if (idx == 0) return "7";
if (idx == 1) return "8";

return GetSequence(idx / 2 - 1) + GetSequence(idx % 2);
}
``````

Output:

``````7
8
77
78
87
88
777
778
787
788
``````
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+1 I like it! ' –  Nikita Rybak Sep 9 '10 at 20:13
seems you are obsessed with recursion.. :) –  vaibhav Sep 9 '10 at 20:24

Binary, counting from two, ignoring the leading digit, using 7 and 8 for zero and one:

``````        7,  8,  77,  78,  87,  88,  777,  778,  787,  788
0, 1, 10, 11, 100, 101, 110, 111, 1000, 1001, 1010, 1011
``````
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nicest solution..!! –  vaibhav Sep 9 '10 at 20:29
+1 for the solution. Wonderful observation Pete! Here is the python 2.6 implementation -for i in range(2,15):print "".join(map((lambda x: ('8','7')[x=='0']), bin(i)[2:])[1:]), –  Gangadhar Sep 10 '10 at 5:24
Bloated. Here: `for i in range(2,15):print"".join('78'[int(x)]for x in bin(i)[3:]),` –  recursive Sep 10 '10 at 18:13

Since size of block is growing exponentially (2 elements of length 1, 4 elements of length 2, 8 elements of length 3, etc), you can easily determine number of digits in result number.

``````    long block_size = 2;
int len = 1;
while (n > block_size) {
n -= block_size;  // n is changed here
block_size *= 2;
++len;
}
``````

Now, you just create binary representation of `n - 1`, with 7 for zeroes and 8 for ones (padding it to length `len` with zeroes). Quite simple.

I assume indexes start from 1 here.

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lets take n=10.. that must give 788 as answer.. or 011. but for n=10, n-1 is 9 which gives the binary sequence of 1001.. taking the block size as 3 we select last three binaries i.e. 001 which is not the answer..!! –  vaibhav Sep 9 '10 at 19:59
@vaibhav Note, we change n in the loop too. I edited answer to emphasize it. –  Nikita Rybak Sep 9 '10 at 20:04
ohh ya.. my mistake.. thanks a lot.. –  vaibhav Sep 9 '10 at 20:05

substitute 0 for 7 and 1 for 8 and treat it like a binary sequence

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Not exactely: 7* = 0* will always be 0. –  tur1ng Sep 9 '10 at 19:48

Written as PHP. I assume that the sequence elements are numbered starting from 1.

``````\$n = 45;
// let's find the 45th sequence element.
\$length = 1;
while ( \$n >= pow(2, \$length + 1) - 1 ) {
\$length++;
}
// determine the length in digits of the sequence element
\$offset = \$n - pow(2, \$length) + 1;
// determine how far this sequence element is past the
// first sequence element of this length
\$binary = decbin(\$offset);
// obtain the binary representation of \$offset, as a string of 0s and 1s
while ( strlen(\$binary) < \$length ) {
\$binary = '0'.\$binary;
}
// left-pad the string with 0s until it is the required length
array('7', '8'),
\$binary
);
``````
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+1: Looks like we had the same idea. ;) You can actually avoid the first while loop by using the log and floor functions. –  gnovice Sep 9 '10 at 20:50
Yes, I considered log() and floor(), but I wasn't sure whether floor() would cause problems due to floating-point inaccuracy in php. –  Hammerite Sep 9 '10 at 22:41

It looks like a simple binary sequence, where 7 represents binary zero, and 8 represents binary 1.

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ok.. then why the third number is 77 or in your case.. 00..?? –  vaibhav Sep 9 '10 at 19:48
The sequence restarts at binary zero, but with two digits instead of one. And so on. Each time the sequence overflows its digits, restart at zero and add another digit. –  Robert Harvey Sep 9 '10 at 19:50
The problem is to find the nth element, and that would require enumerating all elements until n. –  recursive Sep 9 '10 at 19:53
@recursive: Not really. `d = 1; seq = n; while (seq >= 2^d) { seq -= 2^d; ++d; }`. You'll be returning the `seq`'th `d`-digit sequence, which turns trivially into the required sequence by converting 0 into 7 and 1 into 8. –  cHao Sep 9 '10 at 20:10

You can compute this directly for the Nth number (`num`) without recursion or looping by doing the following (the sample code is in MATLAB):

• Compute the number of digits in the number:

``````nDigits = floor(log2(num+1));
``````
• Find the binary representation of the number `num` (only the first `nDigits` digits) after first subtracting one less than two raised to the power `nDigits`:

``````binNum = dec2bin(num-(2^nDigits-1),nDigits);
``````
• Add 7 to each value in the string of ones and zeroes:

``````result = char(binNum+7);
``````

And here's a test, putting the above three steps into one anonymous function `f`:

``````>> f = @(n) char(dec2bin(n+1-2^floor(log2(n+1)),floor(log2(n+1)))+7);
>> for n = 1:20, disp(f(n)); end
7
8
77
78
87
88
777
778
787
788
877
878
887
888
7777
7778
7787
7788
7877
7878
``````
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