General Non-structure Theory (1011.3576v2)

Abstract: The theme of the first two sections, is to prepare the framework of how from a "complicated" family of index models I in K_1 we build many and/or complicated structures in a class K_2. The index models are characteristically linear orders, trees with kappa+1 levels (possibly with linear order on the set of successors of a member) and linearly ordered graph, for this we phrase relevant complicatedness properties (called bigness). We say when M in K_2 is represented in I in K_1. We give sufficient conditions when {M_I:I\in K^1_\lambda} is complicated where for each I in K^1_lambda we build M_I in K^2 (usually in K^2_lambda) represented in it and reflecting to some degree its structure (e.g. for I a linear order we can build a model of an unstable first order class reflecting the order). If we understand enough we can even build e.g. rigid members of K^2_lambda. Note that we mention "stable", "superstable", but in a self contained way, using an equivalent definition which is useful here and explicitly given. We also frame the use of generalizations of Ramsey and Erdos-Rado theorems to get models in which any I from the relevant K_1 is reflected. We give in some detail how this may apply to the class of separable reduced Abelian p-group and how we get relevant models for ordered graphs (via forcing). In the third section we show stronger results concerning linear orders. If for each linear order I of cardinality lambda>aleph_0 we can attach a model M_I in K_lambda in which the linear order can be embedded so that for enough cuts of I, their being omitted is reflected in M_I, then there are 2^lambda non-isomorphic cases.