13.0
The dot is moving one decimal to right every step.
There appears to be no discernible pattern for these numbers, other than them increasing in arbitrary multiples of 6.
the mode is the highest occurring of term in a number sequence. eg:- 23,24,25,14,25,14,16,23,25,25...... here the mode is 25,as it is occurring more than the other numbers
The answer is 6.because the sequence is all the same numbers, but they are in different number bases.110= 6 in binary20= 6 in base 312= 6 in base 411= 6 in base 510= 6 in base 6all the rest of the numbers in the pattern would be 6, because we passed base 6 and all the other number bases have the digit '6' in them.
15,30,45,60,75,90,105,120,135,150,165,180,,195,210,225,240,,255,270,285,300,.................................. and so on This is the sequence of numbers whose common difference is 15 and other numbers can be found by adding 15 to the previous number.
Well a like sequence would follow the same rule as the sequence itself: Each number (after the first two) is the sum of the previous two numbers. Thus the sequence begins 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, etc. The higher up in the sequence, the closer two consecutive "Fibonacci numbers" of the sequence divided by each other will approach the golden ratio (approximately 1 : 1.618 or 0.618 : 1).
It is possible if you define some arbitrary sequence, to decide which number comes "after" which other number. There is no "natural" sequence, as in the case of integers; to be more precise, you can't use the ordering defined by the "less-than" operator as such a sequence: between any two different rational numbers, there are additional rational numbers.
common difference is the difference in every two consecutive numbers in the sequence .. or in the other way around, its the number added to a number that resulted to the next number of the sequence ..
8, if it is the Fibonacci sequence; 7, if it the sequence of non-composite numbers (1 and primes); there are other possible answers.
It can be any number. Two numbers do not even determine whether the "sequence" is arithmetic, geometric or other.
In applications such as reciprocal authentication and session key generation the requirement is not so much that the sequence of numbers be statistically random but that the successive numbers of the sequence are unpredictable. With true random sequences each number is statistically independent of other numbers in the sequence and therefore unpredictable.
None at all. That information is not part of a Social Security number. Numbers are issued in sequence- one after the other- in different regions.
A numeric sequence is a list of numbers in a particular order. A non-numeric sequence is an ordered list of something other than numbers.
Of course there are.
You cannot, with the information available. Probably not, but if you were given one more bit of information, the number of numbers in the sequence, then you might have a good chance if there aren't too many numbers in the sequence. If there is an odd number of numbers, then the median is the number such that half of the numbers are greater, and half are smaller. The mode is the number that occurs most often. The mean is the sum of all of the numbers, divided by the number of numbers. The range is the largest number minus the smallest number. For example, take this number sequence: 1, 2, 2. Given: mode=2, range=1, median=2, mean=5/3. Start with the mode. There must be at least two 2's, since it is the mode; so it must occur more often than any other number. The range is only 1; so it could go from 2 to 3, or from 1 to 2, assuming that only whole numbers are used. If the third number were 3, then the mean would be (2+2+3)/3=7/3. If the third number were 1, then the mean would be (1+2+2)/3=5/3, which matches the given mean; so the number sequence is 1, 2, 2. However, since we were not given the number of numbers in the sequence, could the sequence also be: 1, 1, 2, 2, 2, 2? The answer is, "Yes, it could be." So the bottom line is that if you were also given the number of numbers in the sequence, and it wasn't too many, you could have a good chance of figuring out the sequence from the mode, mean, median, and range. Another thing to think about is , if all of the numbers in the sequence are different, then you have multimodal rather than unimodal, and you might be given all of the numbers just from the mode. For example, the following number sequence 1, 3, 5, 7, 12, 21, 53, 77. Given the mode, mean, median, and range, could you figure out all of the numbers in the sequence. Answer: Yes, no problem, since it is multimodal, and no number occurs more often than any other number, the mode term would include all of the numbers in the sequence. How about this sequence: 1, 1, 2, 3, 12, 12, 17, 17? This sequence is trimodal; so the three modes are 1, 12, 17. If you were given that there were 8 numbers in the sequence, then you would know that there were only 2 numbers yet to determine, and from adding up the 6 numbers that you know from the mode, and knowing the mean, you should be able to determine that the two unknown numbers add up to 5. It can't be 1 and 4, since that would make 1 the only mode. It couldn't be 0 and 5, since you know the range, and that wouldn't fit. Any negative number wouldn't fit into the given range, which is 16. So you would be able to figure out that 2 and 3 were the remaining two numbers.
A set of numbers that follows a specific rule or sequence is called a sequence. This sequence can involve arithmetic operations, geometric progressions, or other mathematical patterns.
It is a sequence defined by the following rule:U(1) = 1U(2) = 1U(n) = U(n-2) + U(n-1) for n = 3, 4, 5, ...In other words, the first two numbers in the sequence are both 1. After that, each number is the sum of the two numbers before it.Some versions start with U(1) = 0. The only effect of this is that the position of each number in the sequence is increased by 1.
It must be 81 because 9 squared is 81 and 9 is not a prime number whereas the other numbers are squared prime numbers.