It is better to be broadly right instead of precisely wrong.

In this blog I will discuss a recent move by the National Trust to ‘macro-manage’ land in an attempt to get things broadly right over a large geographic scale.  Attempting to manage land for nature can be difficult because nature is so complex, in the face of such complex systems the National Trust’s strategy is not only cost efficient, it is extremely sensible.  To explain why I think this, I first need to write a little on the nature of randomness.  I will distinguish between three types of randomness, inherent, game and apparent randomness.  All three types of randomness are alike in a crucial way: they make the future uncertain.  Inherent randomness belongs in the domain of physics, more precisely quantum mechanics which states, amongst other things, that it is impossible to know both where a (sub-atomic) particle is and where it is going.  There is pure randomness at the root of reality.  Fortunately, as we move to larger scales e.g the size of a cell all of the randomness averages out in a predictable way hence this randomness has no influence on our lives.  Game randomness is the randomness we are most familiar with, the moment before the die is rolled we are uncertain about what the outcome will be, if we pick a card at random from a deck we do not know for certain which card we will pick.  Now, if the die is fair and the deck is a complete one then we can know with certainty the probability of rolling a ‘2’ (1/6) or picking an Ace (1/13), we know how uncertain the future is, how much we don’t know.  The last type of randomness, apparent randomness, is the most important to this topic.  Apparent randomness is the case of facing an uncertain future due to a lack of knowledge and understanding, it can be thought of trying to play cards with a weighted deck (say, one in which all clubs have been replaced by hearts) the composition of which the player does not know.  Here, if one knew the makeup of the deck then they would be able to predict the probability of different outcomes but the deck, the randomness generator, is not known to the player.  For example, though the weather may be determined by laws, just as the movement of a planet is determined by (Newton’s) laws of motion, our understanding of the weather laws is such that we are unable to predict it, thus, for all purposes, the future weather appears to us to be, at least slightly, random.  For another example consider the many precise (but often wrong) predictions made by the Bank of England regarding future inflation/interest rates/unemployment (see here for the result of a very quick Google search)

The weather is so difficult to predict because it depends upon many ‘units’ (water droplets, the solids around which they form, local air pressures and more) which can interact to form positive feedbacks.  The result is a system which is rendered hugely difficult to predict, in part because a tiny mis-estimation can have far reaching consequences.  In fact it was a study of the weather which gave birth to the mathematical field of ‘chaos theory’.  Chaos theory can be understood by imagining a tennis ball sat atop a large exercise ball in the middle of a sports hall.  If the perfectly balanced tennis ball is instead placed slightly to the right then it will roll away to the right, perhaps as far as the end of the sports hall and vice versa if the ball is placed slightly to the left.  Thus a tiny mis-estimation of the starting position of the tennis ball has far reaching consequences for predictions of the future position of the ball.  That the weather forms such an unpredictable system is a problem for ecology, conservation and agriculture because the weather plays such a large role in determining what happens at the very base of every foodweb.  Even if the weather was perfectly forecastable, predicting the precise impact of altering a complex foodweb via carrying out a conservation intervention would be nigh on impossible as is predicting the impact of a government’s economic intervention.

Conservation interventions (outside of academia) are normally carried out on the belief that doing A will result in a change in B.  If A is expensive then it will need to be justified.  The normal approach to this problem is to make a prediction about the change in B which will result from action A.  Unfortunately this usually means making predictions about complex systems which are not completely understood.  The more precise one attempts to be, the more likely one is to be wrong, herein lies the problem. 

There are two solutions to the difficulties of forecasting presents:

making vaguer predictions and making no predictions at all.

Both of these solutions run counter to our nature and also counter to the media’s handling of prediction making in the face of randomness.  Firstly we cannot help but attempt to predict the future by imagining various scenarios, not making predictions requires a great mental effort and self-restraint.  Secondly, when we cast our minds forwards we do so by imagining one possible scenario at a time.  Such a forecasting system is deeply flawed.  A useful forecast is not the sum of one or a few imagined scenarios, is the (weighted) average of all the possible scenarios which includes in it a measure of uncertainty.

The National Trust’s Wicken Fen (Cambridge) (see here) and High Peak Moors (Peak District) (see here and here) projects are both attempts to manage land whilst making the minimal possible number of predictions.  The National Trust is doing this by utilising fairly unspecific tools (i.e. livestock graze land instead of fine scale intervention by hand in Cambridge and blocking ditches in the Peak District) in the hope that these will bring about broad benefits to the ecosystem.  Precisely what those benefits will be, there has been little attempt to precisely predict.  Instead the introduction of the livestock, ditch blocking and other broad-stroke interventions, are forming lessons from which the National Trust will learn in order to inform future efforts.

Restraining the extent of our meddling with nature, basing this meddling on minimal ecological theorising and instead looking for examples of what worked in the past may seem a non-scientific approach but it isn’t.  Learning what works is scientific.  If broad and approaches can be shown scientifically to work best, scientists are obliged to put aside any inherent preference for complexity and evaluate these approaches in the same way as more complex ones. 

Being broadly right means dealing with uncertainty, with vagueness, a situation which may not sit well with us at first but it is surely better than being precisely wrong.