The study of experimental communities is fundamental to the development of ecol-1 ogy. Yet, for most ecological systems, the number of experiments required to build, 2 model, or analyze the community vastly exceeds what is feasible using current meth-3 ods. Here, we address this challenge by presenting a statistical approach that uses 4 the results of a limited number of experiments to predict the outcomes (coexistence 5 and species abundances) of all possible assemblages that can be formed from a 6 given pool of species. Using three well-studied experimental systems-encompassing 7 plants, protists, and algae with grazers-we show that this method predicts with 8 high accuracy the results of unobserved experiments, while making no assumptions 9 about the dynamics of the systems. These results suggest a fundamentally different 10 study design for building and quantifying experimental systems, requiring a small 11 number of experiments relative to traditional approaches. By providing a scalable 12 method for navigating large systems, this work provides an efficient way to study 13 highly diverse experimental communities. 14 1 Results 60 Empirical systems 61To demonstrate this method, we first analyze published data of three experimental systems. Although 62 these studies were not specifically designed to test our method, each study reports the final abundances 63 of all species in each experimental assemblage, and each contains a sufficient number of unique 64 assemblages to benchmark the method by making out-of-fit predictions. 65 First, we consider data from Kuebbing et al. 11 , who conducted growth experiments using two 66 phylogenetically paired sets of old-field plants. Both sets contain four species, drawn from the fam-67 ilies Asteraceae, Fabaceae, Lamiaceae, and Poaceae. In one set, all species are native to the study 68 site; in the other, all species are non-native. For both the native and non-native pools, experimental 69 communities were initialized with 14 out of 15 (= 2 4 − 1) possible assemblages, with each combina-70 tion replicated 10 times. Dry-weight aboveground biomass for each species in each assemblage was 71 recorded after 112 days of growth 11 . 72 Second, we analyze data from Rakowski and Cardinale 12 , who grew consumer-resource commu-73 nities consisting of five species of green algae and two herbivorous species from the family Daphni-74 idae (Ceriodaphnia dubia and Daphnia pulex). Here we focus on the four algal species that survived in 75 a sufficient number of endpoints to test our method: Chlorella sorokiniana, Scenedesmus acuminatus, 76 Monoraphidium minutum, and Monoraphidium arcuatum. The algae were grown in all four-species 77 combinations with high replication, and one of the two herbivores was added to two-thirds of the repli-78 cates. The communities were incubated for 28 days, during which time each assemblage collapsed to 79 a subset of the initial pool, generating a variety of distinct endpoints. 80 Third, we turn to time-series data published by Pennekamp et al. 13 , who stu...
