In Book "Intro to algorithm -- by CLRS" mentioned in Sec-9.1 that Simultaneous Maximum & minimum finding can be done in the running time 3*floor(n/2). Same as for lower-bound also.

I have written the following algorithm (taking help from CLRS) whose lower-bound is 2*floor(n/2). [ This is wrong --- thanks to Ricky Bobby ]

```
I m using the variables: 'max' & 'min' to denote maximum & minimum elements, 'i' as indexing variable.
Simultaneous_Maximum_&_Minimum (A, n) // Array A[1...n]
{
1. If n is even, compare the first two elements and assign the larger to max and
smaller to min. Set StartIndex = 3.
2. If n is odd, set both max & min to the first element. Set StartIndex = 2.
3. for (i = StartIndex; i <= n; i = i+2 ) { // Processing elements in pair
if (max < A[i]) { // Compare max with A[i]
if (A[i] < A[i+1]) // Compare max with A[i+1]
max = A[i+1]; // we sure that A[i] or A[i+1] can't be min
else { // When max less than A[i] but A[i] not less than A[i+1]
max = A[i]; // Set A[i] as max
if (min > A[i+1]) // Possible that A[i+1] can be min
min = A[i+1]; // if yes, set A[i+1] as min
}
}
// When max is not less than A[i]
else if (min > A[i]) { // Compare min with A[i]
if (A[i] > A[i+1]) // Compare min with A[i+1]
min = A[i+1]; // we sure that A[i] or A[i+1] can't be max
else { // When min is greater than A[i] but A[i] not greater than A[i+1]
min = A[i]; // Set A[i] as min
if (max < A[i+1]) // Possible that A[i+1] can be max
max = A[i+1] // if yes, set A[i+1] as max
}
}
}
else { // max > A[i] and min < A[i] -- so A[i] can't be max or min
if (max < A[i+1])
max = A[i+1]
if (min > A[i+1])
min = A[i+1]
}
}
}
```

Thanks to Ricky Bobby for pointing out my mistakes -- we can't done find simultaneous maximum & minimum in 2*floor(n/2) running time.