A divide-and-conquer solution can be done by dividing the array into 2, say A_{1} and A_{2}. Then, once having recursively solved the problem for the two sub-arrays, you should consider the scenarios in which the optimal solution to the original array may lie.

**Option 1:** The longest contiguous increasing subsequence is completely in A_{1}, in which case you already found the maximum length, or the relevant answer, or whatever it is you are planning to return.

**Option 2:** Similarly, the longest contiguous increasing subsequence is entirely in A_{2}.

**Option 3:** The longest contiguous increasing subsequence is partially in A_{1} and partially in Array_{2}. In this case, considering A_{1} is the left portion of the array and A_{2} is the right portion, you basically have to go left from the intersection until it is not decreasing or you reach the left end of A_{1}. And then you go to right on A_{2} until it is not increasing or you reach the right end of it.

Among these options you take the one with the greatest length, and you're done.

However, I should note that divide-and-conquer is not the optimal solution to this problem, as it has **O(nlogn)** time complexity. As mentioned in Jon Bentley's notable book, Programming Pearls, a solution what he calls as the **maximum sum contiguous subsequence problem** is known to have **linear** time complexity. That solution may easily be adapted to handle increasing subsequences, instead of the maximum sum.

The algorithm is based on an approach Bentley calls scanning, and it is based on the idea that any subsequence has to **end** at some point.

The approach is painfully simple, and a Python implementation can be found below.

```
def maxIncreasing(arr):
maxLength = 1
maxStart = 0
curStart = 0
curLength = 1
for i in range(1, len(arr)):
if arr[i] <= arr[i-1]:
if curLength > maxLength:
maxLength = curLength
maxStart = curStart
curStart = i
curLength = 1
else:
curLength += 1
if curLength > maxLength:
maxLength = curLength
maxStart = curStart
return (maxLength, maxStart)
```