Transition 1 (and 2)
Transition 1 can be modeled by the logistic function, with a pseudo R2 of 0.56:
probability of transition =
1/1 +e -(1.6089 - 8.9706(decreasers/increasers))
Transition 2 can be modeled by using the negatives of the slope and intercept parameters like so:
probability of transition =
1/1 +e -(-1.6089 + 8.9706(decreasers/increasers))
Transition 3 (and 4)
Transition 3 can be modeled by the logistic function, with a pseudo R2 of 0.82:
probability of transition =
1/1 +e -(15.86395 - 31.3721(grass/shrub))
Transition 4 can be modeled by using the negatives of the slope and intercept parameters like so:
probability of transition =
1/1 +e -(-15.86395 + 31.3721(grass/shrub))
Transition 5
Transition 5 can be modeled by the following logistic function. (This function, based upon the available data was "perfect" in the sense that the two groups of data (S2 and S3) did not overlap at all, leading to a pseudo R2 of 1.0. Thus, multiple parameters are possible solutions and the solution provided below is unstable. In practice this is not terribly important because the boundary between the two states is in the range between 27 and 28% exotic annual cover):
probability of transition =
1/1 +e -(198.2512 - 720.8806(exotic annual cover))
Simulations
We solved the above equations for all reasonable values of each of these predictors. The results are plotted in Figure 1.
Fig. 1. Logistic equations of Transitions 1,3, and 5, predicitng the probability of transition. Dashed horizontal lines depict critical probabilities (5%, 25%, 50%, 95%) (click to enlarge image)
This modeling exercise provides real values which can trigger management actions. Our critical probabilities are: 5% the threshold beyond which transitions are a reasonable possibility, 95% the threshold beyond which transitions are almost certain, 50% the threshold at which transition or lack thereof are equiprobable, and 25% the threshold beyond which transitions are becoming a common event. The values corresponding to all 5 transitions are tabulated below (Table 1).
Table 1. Critical probabilities of transition given values of monitorable predictors for 5 transitions (click to enlarge).
Interpretation:
Unlike many semi-arid ecosystems, grazing pressures primarily take the form of shifts in vegetation composition and do not degrade soil surfaces. All of the transitions are assumed to be driven at least partially by grazing pressure. If Decreasers/Increasers is used as an index of the grazing pressure on community composition, a negligible probability of transition from S1P1 to S1P2 exists is decreasers compose 51% or more of the community. If grazing is allowed to decrease this ratio to 30% a transition would not be an uncommon event, and if the ratio decreases to 18% transition is just as probable as no transition. If these probabilities of transition are too high given management priorities, relaxation of grazing might be prescribed. Using this predictor, near certainty (95% transition probability) of transition is not observed even if all decreasers are eliminated. This implies that there is another unmeasured driver of transition that is not incorporated into the model.
If transition does occur to S1P2, the ecosystem is then at-risk for transition to a new state with an increase in prevalence of grazing tolerant grasses (State 2). Whether this constitutes degradation depends upon management goals. Again, grazing pressure is assumed to underly this transition. Grasses may compose up to 41% of the community without a transition being possible. If, however grasses (primarily Pleuraphis jamesii) are allowed to increase to 51% a transition is about as probably as not. Transition becomes nearly certain as grasses compose 60% of the community. Again, if these probabilities of transition are too high given management priorities, relaxation of grazing might be prescribed.
The primary management concern with State 2 is that it may be susceptible to annualization. The best measure of annualization is the intra- and interannual variation in vegetation cover. We did not have this data to work with, thus we used exotic annual cover as our predictor. Regardless of land use preferences, annualization by exotics is never desired. Our data indicate a very sharp boundary between S2 and S3. Below 27 % exotic annual cover, transition is highly improbable. Above 28% exotic annual cover, transition is nearly certain. Thus if 27% exotic annual cover is close to being attained management intervention should occur to increase perrenial species or reduce exotic annuals.
