One day in Outremer: 'Lanchester' Battles Extended (2)

Not WW1, but air combat was the basis of Lanchester's
Theory of Battles.

In the previous instalment, I discussed a theory of battles suggested by one F.W. Lanchester. What he had in mind was the random melee of the type imagined of the aerial dogfights of World War One. It was in 1916 that Lanchester published his ideas.  

The theory was that in such a random environment, the outcome was determined by the squares of the numbers involved on each side. One of the assumptions behind this was that all combatants were in it with an equal chance of killing or being killed. If one side has more battle prowess (man for man) than the other, it might affect the scale of the outcome, but, if outnumbered two to one, they had to have four times the battle prowess (however that might be measured) than their opponents, and that just to come out even (mutual annihilation).

An article by Graham Jones in Wargames illustrated back in 1991 pointed out the limitations of this theory in the absence of randomness. However, upon reading that article, it occurred to me that some randomness did exist in the scenario he used to illustrate the problem. This was a force of 1200 people against 600, in which both sides had 200 in the firing line. 

Extending the Theory

...It seemed to me that Lanchester's theory could be extended to cope with this, and even more general cased, i.e. to include firefights. True, the randomness of elimination of individuals does not extend over the entire forces, but it is reasonable to suppose that it will apply to the embattled front ranks - the forces actually engaged. This will be our first assumption. Our second will be that the unengaged ranks will act as a reserve from which losses will be replaced as they occur.

A generalised battle along these lines might have as many as three 'phases'.
PHASE I:
Both sides have engaged in the actual fighting some number less than their overall numerical strength. The remainder on each side forms a reserve pool of replacements. The number engaged on each side need nit be equal.
PHASE II:
One side has been so reduced in numbers as to have exhausted its reserve pool. Its losses among those engaged can no longer be made good; and the force's fighting strength now declines. A battle could end in this phase.
PHASE III:
Both sides have used up their reserve pools. This is the straightforward Lanchester battle.

Our extended battles might pass through any or all of these 'phases'.

General Postulate:

A more general postulate than Lanchester's might be 
The outcome of a battle depends upon the product of overall numerical strength and the numbers engaged at any given moment.  This, of course, becomes the square of either if they are equal.

Symbolic Expression of the Generalised Theory:
What follows is in symbolic form the outcomes of the battles of the types just described. For reasons of (a) space and (b) I'd have otherwise to fiddle around with more symbols than indices and square roots, I'll omit the mathematical process I took to reach these conclusions. They weren't hard.
In what follows:

R =  numerical strength of RED 
B =  numerical strength of BLUE
r  = maximum number of RED individuals that can engage at any time
b = maximum number of BLUE that can engage at any time
p = relative effectiveness of RED soldiers, compared with the basis of...
q = 1 = relative effectiveness of BLUE soldiers.

Then: 
RED wins in PHASE II if :

prR - pr² > bB - b²/2         or     R > bB/pr - b²/2pr + r              [A1]

with survivors
s(RED) = R - bB/pr + b²/2pr

BLUE wins in PHASE II if:

bB - b² > prR - pr²/2         or     B > prR/b - pr²/2b + b              [A2]

with survivors 
s(BLUE) = B - prR/b + pr²/2b

RED wins in PHASE III if:

prR - pr²/2 > bB - b²/2         or     R > bB/pr - b²/2pr + r/2        [B1]

with survivors:
                    ____________________ 
s(RED) =  √ {(r(2R-r) - (b/p)(2B-b)}

BLUE wins in PHASE III if:

bB - b²/2 > prR - pr²/2         or     B > prR/b - pr²/2b + b/2        [B2]

with survivors 
                     _____________________
s(BLUE) = √ {(b(2B-b) - (pr)(2R-r)}

Can you see at what point mutual annihilation will occur?

Back to Outremer...
Now, imagine you are one Yakub Salah ed-Din, surnamed 'the BLUE', a distant relative of Saladin, charged with the safekeeping of the vital caravan mentioned in the previous article. You are particularly concerned about Bedouin raids. Suddenly a scout comes in from the west, with word that that rapacious Frank, Reynald of Chatillon, has violated the truce and is, even now, in full march to attack the caravan. Seventy-one of his followers, according to the ever-reliable scout, Ali Muhammad the Far Seeing, knights and sergeants all, are riding hither filled with malice aforethought.

Realising that a melee in the plain will lose retainers, caravan and credibility with Saladin, you recall that Reynald will have to pass through a defile not far west of here. Ten men abreast is the maximum the defile can accommodate. But just as they debouche from the pass into the open, they will have to face twenty Saracens at a time - not more will be in reach - to their ten.  This promises your men a fighting chance.

But you can't send off your whole hundred retainers: there's still the Bedouin to consider. So, what is the fewest number to send against the Franks?  Maybe fifty will do? How about matching the Frankish numbers and send 71?

To determine the numbers required, you want to send the minimum that will stop the Franks, whilst retaining the maximum possible protection for the caravan.  Even if you lose the whole column, just so long as Reynald is stopped. That will suffice. We'll use relation [B2] and state that your strength B must be at least -

B = prR/b - pr²/2b + b/2 
where R=71,  p=2 (RED fighting ability twice as effective as BLUE), r=10 (RED front line) , b=20 (BLUE front line)

B = (2x10x71)/20 - (2x10x10)/(2x20) + 20/2
   = 71 - 5 + 10 
   = 76.
So you must send at least 76 - although if you do send that many, don't expect to see anyone - Frank or Saracen - to come back from the west.  You might, withal, send 77 instead, and leave just 23 men to defend the caravan. According to my calculations, you'll see 6 men come back.

Applications... Sort of.

At this point I added a short paragraph indicating what I thought might be applications for war games. Of course, I didn't want mutual annihilation, but, having come this far, it was not that hard to envisage what might be going on if one side or the other was reduced by, say, one-third. Take that as the bench mark, and calculate (this again is where the calculus comes in) the losses on the other side.

I was going to suggest the Lanchester model for a Space Opera game based on what I've heard and read of the Waddington board game 4000A.D. I gather that a RED fleet of 20 ships would defeat with equal ease an opposing BLUE fleet of 19 or a squadron of 5 - and at zero cost. I thought it would be nice to have a table that offered standard results according to the Lanchester model. According to that model, the BLUE 5-ship squadron would be scarcely more than a speed bump for the 20-ship fleet - losing all five and taking out, with luck, maybe one RED ship. The 19-vessel BLUE fleet would inflict a deal more damage before going under, and leave just 6 RED ships out of 20 to limp homeward.

I once put together a Table of Outcomes for fleets up to 20 or so ships a side, the losers being wiped out, of course, but it showed the numbers of survivors from the winning side. I would have produced it here, but the thing seems to have vanished the way of all good and useful things...

Limitations:

Note that in all this, we are concerned with the overall result as a statistical expectation: who wins, and by how much. What is going on internally is another matter altogether. I will admit that, upon working out that a force outnumbered 2 to 1 had to fight, man for man, with 4 times the efficiency of the enemy just to break even, I concluded that, without that skill superiority, the odds of their winning was 4 to 1 against.

It turns out that was wrong. In a forum discussion (long since defunct) I was informed that a study concluded that the odds against the smaller side's winning was 8:92 against - 1:11.5. Odd looking numbers, that, and I'm not 100% sure what they really mean. Something for discussion another time, perhaps...