# How to find peak elements in an array when there are multiple peaks?

For an array with single peak element, it could be done in o(logn) using binary search, however in case of multiple peak elements in an array what approach should we use ?

---Putting some more information ---- A peak element is something which is greater then it's neighbors for instance, look at the below array,

[1,3,20,4,1,0,7,5,2]

there are 2 peaks in it, 20 and 7.

We need to design an algorithm to find the peak elements in this array.

• Just sort it by value? Aug 16, 2017 at 12:39
• What exactly are multiple peaks? The max value, occurring multiple times? The array needs to be sorted for binary search. If it's sorted, these peaks must be right next to each other, so finding them isn't really an issue, right?
– f1sh
Aug 16, 2017 at 12:39
• @GillesLesire Sorting is O(n log n), linear scanning is O(n), max elements in ordered array are in the end, so for a sorted array complexity should be O(1). Have no idea where O(log n) came from. Aug 16, 2017 at 12:40
• @f1sh Multiple peaks may mean multiple number of values in the series which are significantly higher than the other values, though, not necessarily equal to each other. We see this sort of peaks in spectrum (frequency) analysis, for example. If it is this kind of situation, then sorting would not help much if the original index of the value is not also somehow stored. Because in such situation, the index may have more importance than the value of the peak. Aug 16, 2017 at 12:40
• @f1sh I agree. If the OP is talking about a rather mathematical problem, which I guess he is, then I also wouldn't expect to see any binary search algorithms anywhere. He probably first needs to define what a "peak" is. Is it just a value that's greater than the others, or is it a value that's "way greater" than the others? How much is "way greater"? I think the problem is not defined well enough yet. Aug 16, 2017 at 12:47

I might have not understand your question since, finding single peak can be done in O(logn) requires array to be sorted at first place.

I would advise you to store a difference array which will generate an output like: `[1,3,20,4,1,0,7,5,2]` => `[1, 1,-1,-1,-1, 1,-1,-1]` which is simply generate an array of size `n - 1` and place the direction of increase in the array. This can be done in O(n) single pass.

In the second pass you will look for [1, -1] pairs this is the place where peak occurs.

If you want to find peaks in the start and end you need to check if start is -1, and end is 1.

Hope this helps.

• anything that you could think of in o(logn)
– brij
Aug 17, 2017 at 10:48
• if you have single array it is impossible. Aug 17, 2017 at 10:50
• If there is exactly one peak then it's a binary search: O(log n). If there could be any number of peaks, that means you have to check ALL elements is a way or other, so it cannot be faster than O (n) Aug 22, 2017 at 11:45

I recently faced the similar problem on a programming website but there was another important constraint other than finding peaks. Firstly, there can be multiple peaks, but there can also be plateaus! A plateau is something that occurs in an arr: [1,2,2,2,1] and in this case we have to return the peak to be 2. In the problem we are also asked to return the first position where the peak occurs, so in this case it will be position = 1. The only case, that we have to remain careful about is that in arr: [1,2,2,2,3,4,5,1], there is peak with 5 in the second last position but there is no plateau even if there is a series of duplicates which look like a plateau in the first glance.

So the basic algorithm that I thought about was using a difference array as already suggested using {1,0,-1} where we use 0 when we get a series of duplicates in a continuous stream. Whenever we get a 0 while checking the difference array, we start looking for the first non zero entry, whether it is 1 or -1 and output accordingly. But again we have to remain careful that may be the Difference array looks like Diff = [-1,1,-1,1,0,0,0], in which case there is no plateau and only one peak. The python code looks like the following, when arr is given as input:

``````n = len(arr)
if arr == []:
return {"pos":[],"peaks":[]}
Diff = []
for i in range(0,n-1):
if arr[i]< arr[i+1]:
Diff.append(1)
elif arr[i] == arr[i+1]:
Diff.append(0)
if arr[i] > arr[i+1]:
Diff.append(-1)
pos = []
peaks = []
j = 0
for i in range(0,n-2):
if Diff[i] == 1 and Diff[i+1] == -1:
pos.append(i+1)
peaks.append(arr[i+1])
if Diff[i] == 1 and Diff[i+1] == 0:
if Diff[i+1:] == [Diff[i+1]]:
break
j = i+1
while(Diff[j] == 0 and j < n-2):
j = j+1
if Diff[j] == -1:
pos.append(i+1)
peaks.append(arr[i+1])

return {"pos":pos, "peaks":peaks}
``````

For finding all the peak elements when having multiple peaks.

``````class Solution(object):
def findPeakElement(self, nums):
"""
:type nums: List[int]
:rtype: int
"""
left, right = 0, len(nums) - 1
while left < right:
mid = left + right >> 1
if nums[mid] < nums[mid + 1]:
left = mid + 1
else:
right = mid
return left
``````
``````int arr[] = {50, 12, 13, 20, 16, 19, 11, 7, 24};
int size = sizeof(arr) / sizeof(arr[0]);

int peak_arr[size / 2];
int i, j, k = 0;
int next, previous = 0;

for(i = 0; i < size; i++){
if(i + 1 == size){
next = 0;
}
else{
next = arr[i + 1];
}

if(arr[i] > next && arr[i] >= previous){
peak_arr[k++] = arr[i];
}
previous = arr[i];
}
``````
• Although your answer might be the correct solution, it would help to have some explanation about your code. Nov 27, 2020 at 10:59

Finding multiple peak elemets using a recursive approach.

``````def Div(lst, low, high):
mid = (low + high)//2
if low > high:
return ""
else:
if mid+1 < len(lst) and lst[mid] > lst[mid+1] and lst[mid] > lst[mid -1]:
return str(lst[mid]) + " " + Div(lst, low, mid-1) + Div(lst, mid+1, high)
else:
return Div(lst, low, mid-1) + Div(lst, mid + 1, high)

def peak(lst):
if lst == []:
return "list is empty"
elif len(lst) in [1, 2]:
return "No peak"
else:
return Div(lst, 0, len(lst))

print(peak([0, 5, 2, 9, 1, 10, 1]))
``````
• @JariTurkia code is now fixed. Thank you for pointing it out. Im new to stackoverflow so did not know how to format code. Jul 23, 2021 at 15:16

The idea is to use modified binary search.

If `arr[mid+1]>arr[mid]` then your peak ALWAYS exists on the right half.

If `arr[mid-1]>arr[mid]` then your peak ALWAYS exists on the left half. Because arr[i+1] have only two options, either bigger than arr[i] or smaller than arr[i-1]

I don't have java implementation but here is a python implementation.

``````def FindAPeak(arr, i, j):
mid = (i+j)/2
# if mid element is peak
if (mid == len(arr)-1 or arr[mid] > arr[mid+1]) and (mid == 0 or arr[mid] > arr[mid-1]):
return arr[mid]
# when your peak exists in the right half
if arr[mid] < arr[mid+1] and mid+1 < len(arr):
return FindAPeak(arr, mid+1, j)
# when your peak exists in the left half
else:
return FindAPeak(arr, i, mid-1)

In [31]: arr = [1,2,3,2,1]
...: FindAPeak(arr, 0, len(arr)-1)
...:
Out[31]: 3

In [32]:
...: arr = [1,2,3,4,5,6]
...: FindAPeak(arr, 0, len(arr)-1)
...:
Out[32]: 6
``````
• Not necessarily, there can still be a peak on the other side, so for finding all the peaks, the above algorithm is wrong. Eg: 5,4,3,2,1,0,5,2 There is a peak on both the sides
– Sid
Sep 5, 2019 at 12:40