Have you read http://www.merriampark.com/ld.htm ?
You're computing the cost of transformation -- the number of inserts and deletes -- required to make one string into another.
This "cost" to transform is indicative of the distance between the two strings.
What about exchanges? That's the Damerau–Levenshtein algorithm, which is different. Including exchanges doesn't improve things much.
The essence is to create a matrix between the two words and compute -- column by column -- the "distance" from each letter of each word to each letter of the other word. The lower right hand corner of that matrix is the total distance, taking into account all of the letters.
The cell "above" reflects a history of changes, and the character for that row is (usually) different from this, so this cell is a deletion relative to it.
The cell "left" reflects a history of changes, and the character for that column is is (usually) different from this, so this cell is an insertion relative to it.
The only time this usually would be way wrong is words with a triple-letter sequence. Rare in English.
The row-column comparison has a cost of 0 or 1.
The minimum of "history plus one change" and the actual cost of a change is the applicable cost.
j aren't lengths of anything. They're positions in the comparison matrix. The "insertion" and "deletion" is the action required to transform one word into the other. The count of insert/delete actions is the distance between the words.