Convergence in measure

Definitions

Properties

• Global convergence in measure implies local convergence in measure. The converse, however, is false; i.e., local convergence in measure is strictly weaker than global convergence in measure, in general.
• If, however, or, more generally, if f and all the f_n vanish outside some set of finite measure, then the distinction between local and global convergence in measure disappears.
• If μ is σ-finite and converges to f in measure, there is a subsequence converging to f almost everywhere. The assumption of σ-finiteness is not necessary in the case of global convergence in measure.
• If μ is σ-finite, converges to f locally in measure if and only if every subsequence has in turn a subsequence that converges to f almost everywhere.
• In particular, if converges to f almost everywhere, then converges to f locally in measure. The converse is false.
• Fatou's lemma and the monotone convergence theorem hold if almost everywhere convergence is replaced by convergence in measure.
• If μ is σ-finite, Lebesgue's dominated convergence theorem also holds if almost everywhere convergence is replaced by convergence in measure.
• If X = ⊆ R and μ is Lebesgue measure, there are sequences of step functions and of continuous functions converging globally in measure to f.
• If f and f_n are in L^p for some p > 0 and converges to f in the p-norm, then converges to f globally in measure. The converse is false.
• If f_n converges to f in measure and g_n converges to g in measure then f_n + g_n converges to f + g in measure. Additionally, if the measure space is finite, f_ng_n also converges to fg.

  Counterexamples

• The sequence converges to f locally in measure, but does not converge to f globally in measure.
• The sequence where and

• The sequence converges to f almost everywhere and globally in measure, but not in the p-norm for any.

  Topology