Submitted:
20 June 2026
Posted:
23 June 2026
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Abstract
Keywords:
1. Introduction
- 1.
- We define abstract structures: discordant normed spaces, discordant Banach spaces, and discordant Hilbert spaces. These extend classical functional analysis in a natural way.
- 2.
- We give concrete examples using weighted and Sobolev spaces. The weight is determined by the derivative of the reference function. We prove that these examples are complete, and that they have natural discordant versions of reflexivity and separability.
- 3.
- We prove a compactness theorem for bounded sequences in : every bounded sequence has a discordantly convergent subsequence. This is the discordant analogue of the classical Bolzano-Weierstrass theorem.
- 4.
- We show that the framework is useful by solving a nonlinear parabolic equation where the reaction term depends on the discordant distance. The proof uses a fixed-point argument and relies on our compactness theorem.
2. Preliminaries
2.1. Function Spaces and Structural Embeddings
2.2. Mollification and Approximation
- for every ;
- in for every as ;
- If (resp. ), then , and hence in the Sobolev norm.
2.3. Weak Compactness in : The Dunford-Pettis Theorem
2.4. Measures and Weak-* Convergence
2.5. The Adaptive Measures
3. Discordant Distance and Convergence
3.1. The Discordant Distance
3.2. Discordant Convergence
3.3. Topological Nature: The Failure of Open Balls
- 1.
- for all (so f has height at most h);
- 2.
- is small (in fact, );
- 3.
- the -norm of is arbitrarily large, say , where M is a large constant to be chosen.
3.4. Illustrative Examples
4. Discordant Banach and Hilbert Spaces
4.1. Discordant Normed Spaces
- (N1)
- Definiteness: ;
- (N2)
- Homogeneity: for all ;
- (N3)
- Triangle inequality: for all .
- Non-negativity and definiteness: , and . This follows directly from (N1).
- Triangle inequality: For any ,where the triangle inequality is applied in the normed space . Note that the third term is , which uses the same reference u (not v). Thus the triangle inequality holds for d as a metric.
- Asymmetry: In general, , sinceand there is no reason for the norms and to agree. This asymmetry is a defining feature of discordant spaces and distinguishes them from classical metric spaces.
4.2. Completeness and Discordant Cauchy Sequences
4.3. Discordant Hilbert Spaces and Geometric Structure
- (IP1)
- Sesquilinearity: is linear in v and conjugate-linear in w (if ; bilinear if );
- (IP2)
- Symmetry: ;
- (IP3)
- Positive-definiteness: , with equality if and only if .
4.4. Concrete Realisations
4.5. Comparison with Classical Structures
5. Completeness of the Weighted Discordant Hilbert Space
5.1. Step 1: Classical Boundedness of a Discordant Cauchy Sequence
5.2. Step 2: Strong Convergence in of a Subsequence
5.3. Step 3: Discordant Convergence of the Subsequence
5.4. Step 4: Extension to the Whole Sequence
6. Reflexivity and Separability in Discordant Spaces
6.1. Discordant Reflexivity: Sequential Compactness of Bounded Sets
6.2. Discordant Separability: Countable Dense Subsets
6.3. Summary and Consequences
- (i)
- X is discordantly reflexive: every sequence bounded in the classical norm has a subsequence that converges in the discordant sense.
- (ii)
- X is discordantly separable: there exists a countable set S such that for every and every , we can find with .
7. Application: An Evolution Equation with Discordant Feedback
7.1. Problem Setting
- is a fixed target function (for instance, ),
- is the discordant distance between the current state and the target , measured with respect to the reference ,
- is a bounded continuous function (e.g., ).
7.2. Mild Formulation and the Fixed-Point Operator
7.3. Discordant Continuity and Compactness
- 1.
- Construction of an invariant set. Let , where R is chosen large enough so that for all t, and the contribution from the integral is bounded by using the boundedness of f. Since the heat semigroup maps into for , maps into itself for a suitable R.
- 2.
- Discordant continuity of . If in the discordant sense on (meaning ), then by Lemma 7.1, for each t, and the convergence is uniform in t because of the boundedness and the dominated convergence theorem. Hence, uniformly in t. By the continuity of the heat semigroup in , we get in . Thus is continuous with respect to discordant convergence.
- 3.
- Discordant compactness of . Let . Then for some . By the regularizing property of the heat semigroup, the set is bounded in for every . A diagonal argument gives a subsequence (still denoted ) such that in for each t, and moreover, for each fixed t, the derivatives are bounded in . By the discordant compactness theorem (Theorem 6.1), applied to the sequence for each t, there exists a subsequence such that for each t. By a standard diagonal argument, we can ensure this holds for all t in a dense subset. The equicontinuity in time (from the heat semigroup) allows us to extend to all t, yielding a subsequence converging discordantly in . Thus, is relatively sequentially compact in the discordant sense.
- 4.
- Application of Schauder’s fixed point theorem. We need a fixed point theorem for sequentially compact, discordantly continuous maps. Although discordant spaces are not topological, the sequential Schauder theorem holds: if is convex, bounded, and sequentially closed in the discordant sense, and is discordantly continuous and is relatively discordantly sequentially compact, then has a fixed point. The proof is identical to the classical Schauder argument: starting with any , define . The discordant compactness gives a subsequence converging discordantly to some . By discordant continuity, converges discordantly to . Since and are the same sequence shifted, their discordant limits coincide, so . Thus, u is a fixed point.
7.4. Discussion and Significance
- Self-adaptive feedback: The reaction term depends on the discordant distance , which adapts to the current state . This is a genuine nonlocal, state-dependent effect that cannot be captured by a fixed metric.
- Overcoming classical non-compactness: Even when the sequence converges only weakly in , the discordant compactness theorem provides a subsequence converging in the discordant sense, which is exactly the right convergence for the nonlinearity.
- Generality: The proof does not rely on specific properties of the heat semigroup other than its regularizing effect. The same argument applies to any evolution equation governed by a compact semigroup, such as parabolic equations with more general elliptic operators or even some hyperbolic equations with damping.
- Applications: Such equations arise in models of chemotaxis with adaptive sensing, where cells or organisms adjust their perception of gradients based on their own state; in control theory, where the cost functional depends on an adaptive distance to a target; and in image processing, where the metric for comparing images is adapted to the local structure.
Conflicts of Interest
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