Interpolation space

In the field of mathematical analysis, an interpolation space is a space which lies "in between" two other Banach spaces. The main applications are in Sobolev spaces, where spaces of functions that have a noninteger number of derivatives are interpolated from the spaces of functions with integer number of derivatives.

History
The theory of interpolation of vector spaces began by an observation of Józef Marcinkiewicz, later generalized and now known as the Riesz-Thorin theorem. In simple terms, if a linear function is continuous on a certain space $L^{p}$ and also on a certain space $L^{q}$, then it is also continuous on the space $L^{r}$, for any intermediate $r$ between $p$ and $q$. In other words, $L^{r}$ is a space which is intermediate between $L^{p}$ and $L^{q}$.

In the development of Sobolev spaces, it became clear that the trace spaces were not any of the usual function spaces (with integer number of derivatives), and Jacques-Louis Lions discovered that indeed these trace spaces were constituted of functions that have a noninteger degree of differentiability.

Many methods were designed to generate such spaces of functions, including the Fourier transform, complex interpolation, real interpolation, as well as other tools (see e.g. fractional derivative).

The setting of interpolation
A Banach space $X$ is said to be continuously embedded in a Hausdorff topological vector space $Z$ when $X$ is a linear subspace of $Z$ such that the inclusion map from $X$ into $Z$ is continuous. A compatible couple $(X_{0}, X_{1})$ of Banach spaces consists of two Banach spaces $X_{0}$ and $X_{1}$ that are continuously embedded in the same Hausdorff topological vector space $Z$. The embedding in a linear space $Z$ allows to consider the two linear subspaces


 * $$ X_0 \cap X_1$$

and


 * $$X_0 + X_1 = \left \{ z \in Z : z = x_0 + x_1, \ x_0 \in X_0, \, x_1 \in X_1 \right \}.$$

Interpolation does not depend only upon the isomorphic (nor isometric) equivalence classes of $X_{0}$ and $X_{1}$. It depends in an essential way from the specific relative position that $X_{0}$ and $X_{1}$ occupy in a larger space $Z$.

One can define norms on $X_{0} ∩ X_{1}$ and $X_{0} + X_{1}$ by


 * $$\|x\|_{X_0 \cap X_1} := \max \left ( \left \|x \right \|_{X_0}, \left \|x \right \|_{X_1} \right ),$$
 * $$\|x\|_{X_0 + X_1} := \inf \left \{ \left \|x_0 \right \|_{X_0} + \left \|x_1 \right \|_{X_1} \ : \ x = x_0 + x_1, \; x_0 \in X_0, \; x_1 \in X_1 \right \}.$$

Equipped with these norms, the intersection and the sum are Banach spaces. The following inclusions are all continuous:


 * $$X_0 \cap X_1 \subset X_0, \ X_1 \subset X_0 + X_1.$$

Interpolation studies the family of spaces $X$ that are intermediate spaces between $X_{0}$ and $X_{1}$ in the sense that


 * $$X_0 \cap X_1 \subset X \subset X_0 + X_1,$$

where the two inclusions maps are continuous.

An example of this situation is the pair $(L^{1}(R), L^{∞}(R))$, where the two Banach spaces are continuously embedded in the space $Z$ of measurable functions on the real line, equipped with the topology of convergence in measure. In this situation, the spaces $L^{p}(R)$, for $1 ≤ p ≤ ∞$ are intermediate between $L^{1}(R)$ and $L^{∞}(R)$. More generally,


 * $$L^{p_0}(\mathbf{R}) \cap L^{p_1}(\mathbf{R}) \subset L^p(\mathbf{R}) \subset L^{p_0}(\mathbf{R}) + L^{p_1}(\mathbf{R}), \ \ \text{when} \ \ 1 \le p_0 \le p \le p_1 \le \infty,$$

with continuous injections, so that, under the given condition, $L^{p}(R)$ is intermediate between $L^{p_{0}}(R)|undefined$ and $L^{p_{1}}(R)|undefined$.


 * Definition. Given two compatible couples $(X_{0}, X_{1})$ and $(Y_{0}, Y_{1})$, an interpolation pair is a couple $(X, Y)$ of Banach spaces with the two following properties:
 * The space X is intermediate between $X_{0}$ and $X_{1}$, and Y is intermediate between $Y_{0}$ and $Y_{1}$.
 * If $L$ is any linear operator from $X_{0} + X_{1}$ to $Y_{0} + Y_{1}$, which maps continuously $X_{0}$ to $Y_{0}$ and $X_{1}$ to $Y_{1}$, then it also maps continuously $X$ to $Y$.

The interpolation pair $(X, Y)$ is said to be of exponent $θ$ (with $0 < θ < 1$) if there exists a constant $C$ such that
 * $$\|L\|_{X,Y} \leq C \|L\|_{X_0,Y_0}^{1-\theta} \; \|L\|_{X_1,Y_1}^{\theta}$$

for all operators $L$ as above. The notation $L_{X,Y}$ is for the norm of $L$ as a map from $X$ to $Y$. If $C = 1$, we say that $(X, Y)$ is an exact interpolation pair of exponent $θ$.

Complex interpolation
If the scalars are complex numbers, properties of complex analytic functions are used to define an interpolation space. Given a compatible couple (X0, X1) of Banach spaces, the linear space $$\mathcal{F}(X_0, X_1)$$ consists of all functions $&thinsp;f&thinsp; : C → X_{0} + X_{1}$, that are analytic on $S = {z : 0 < Re(z) < 1},$ continuous on $\overline{S} = {z : 0 ≤ Re(z) ≤ 1},$ and for which all the following subsets are bounded:



$$\mathcal{F}(X_0, X_1)$$ is a Banach space under the norm


 * $$\|f\|_{\mathcal{F}(X_0, X_1)} = \max \left\{ \sup_{t \in \mathbf{R}} \|f(it)\|_{X_0}, \; \sup_{t \in \mathbf{R}}\|f(1 + it)\|_{X_1} \right\}.$$

Definition. For ${&thinsp;f&thinsp;(z) : z ∈ S} ⊂ X_{0} + X_{1}$, the complex interpolation space ${&thinsp;f&thinsp;(it) : t ∈ R} ⊂ X_{0}$ is the linear subspace of ${&thinsp;f&thinsp;(1 + it) : t ∈ R} ⊂ X_{1}$ consisting of all values f(θ) when f varies in the preceding space of functions,


 * $$(X_0, X_1)_\theta = \left \{ x \in X_0 + X_1 : x = f(\theta), \; f \in \mathcal{F}(X_0, X_1) \right \}.$$

The norm on the complex interpolation space $0 < θ < 1$ is defined by


 * $$\ \|x\|_\theta = \inf \left \{ \|f\|_{\mathcal{F}(X_0, X_1)} \ :\ f(\theta) = x, \; f \in \mathcal{F}(X_0, X_1) \right \}.$$

Equipped with this norm, the complex interpolation space $(X_{0}, X_{1})_{θ}$ is a Banach space.


 * Theorem. Given two compatible couples of Banach spaces $X_{0} + X_{1}$ and $(X_{0}, X_{1})_{θ}$, the pair $(X_{0}, X_{1})_{θ}$ is an exact interpolation pair of exponent $θ$, i.e., if $(X_{0}, X_{1})$, is a linear operator bounded from $(Y_{0}, Y_{1})$ to $((X_{0}, X_{1})_{θ}, (Y_{0}, Y_{1})_{θ})$, then $T$ is bounded from $T : X_{0} + X_{1} → Y_{0} + Y_{1}$ to $X_{j}$ and $$ \|T\|_\theta \le \|T\|_0^{1 - \theta} \|T\|_1^\theta. $$

The family of $Y_{j}, j = 0, 1$ spaces (consisting of complex valued functions) behaves well under complex interpolation. If $(X_{0}, X_{1})_{θ}$ is an arbitrary measure space, if $(Y_{0}, Y_{1})_{θ}$ and $L^{p}$, then


 * $$\left( L^{p_0}(R, \Sigma, \mu), L^{p_1}(R, \Sigma, \mu) \right)_\theta = L^p(R, \Sigma, \mu), \qquad \frac{1}{p} = \frac{1 - \theta}{p_0} + \frac{\theta}{p_1},$$

with equality of norms. This fact is closely related to the Riesz–Thorin theorem.

Real interpolation
There are two ways for introducing the real interpolation method. The first and most commonly used when actually identifying examples of interpolation spaces is the K-method. The second method, the J-method, gives the same interpolation spaces as the K-method when the parameter $θ$ is in $(R, Σ, μ)$. That the J- and K-methods agree is important for the study of duals of interpolation spaces: basically, the dual of an interpolation space constructed by the K-method appears to be a space constructed from the dual couple by the J-method; see below.

K-method
The K-method of real interpolation can be used for Banach spaces over the field $1 ≤ p_{0}, p_{1} ≤ ∞$ of real numbers.

Definition. Let $0 < θ < 1$ be a compatible couple of Banach spaces. For $(0, 1)$ and every $R$, let


 * $$K(x, t; X_0, X_1) = \inf \left \{ \left \|x_0 \right \|_{X_0} + t \left \|x_1 \right \|_{X_1} \ :\ x = x_0 + x_1, \; x_0 \in X_0, \, x_1 \in X_1 \right \}.$$

Changing the order of the two spaces results in:


 * $$K(x, t; X_0, X_1) = t K \left (x, t^{-1}; X_1, X_0 \right).$$

Let


 * $$\begin{align}

\|x\|_{\theta,q; K} &= \left( \int_0^\infty \left( t^{-\theta} K(x, t; X_0, X_1) \right)^q \, \tfrac{dt}{t} \right)^{\frac{1}{q}}, && 0 < \theta < 1, 1 \leq q < \infty, \\ \|x\|_{\theta,\infty; K} &= \sup_{t > 0} \; t^{-\theta} K(x, t; X_0, X_1), && 0 \le \theta \le 1. \end{align}$$

The K-method of real interpolation consists in taking $(X_{0}, X_{1})$ to be the linear subspace of $t > 0$ consisting of all $x$ such that $x ∈ X_{0} + X_{1}$.

Example
An important example is that of the couple $K_{θ,q}(X_{0}, X_{1})$, where the functional $X_{0} + X_{1}$ can be computed explicitly. The measure $μ$ is supposed $σ$-finite. In this context, the best way of cutting the function $x_{θ,q;K} < ∞$ as sum of two functions $(L^{1}(R, Σ, μ), L^{∞}(R, Σ, μ))$ and $K(t, f&thinsp;; L^{1}, L^{∞})$ is, for some $&thinsp;f&thinsp; ∈ L^{1} + L^{∞}$ to be chosen as function of $t$, to let $&thinsp;f_{0} ∈ L^{1}&thinsp;$ be given for all $&thinsp;f_{1} ∈ L^{∞}&thinsp;$ by


 * $$f_1(x) = \begin{cases}

f(x) & |f(x)| < s, \\ \frac{s f(x)}{|f(x)|} & \text{otherwise} \end{cases}$$

The optimal choice of $s$ leads to the formula


 * $$K \left (f, t; L^1, L^\infty \right ) = \int_0^t f^*(u) \, d u,$$

where $s > 0$ is the decreasing rearrangement of $&thinsp;f_{1}(x)$.

J-method
As with the K-method, the J-method can be used for real Banach spaces.

Definition. Let $x ∈ R$ be a compatible couple of Banach spaces. For $&thinsp;f^{ ∗}$ and for every vector $&thinsp;f&thinsp;$, let $$J(x, t; X_0, X_1) = \max \left ( \|x\|_{X_0}, t \|x\|_{X_1} \right ).$$

A vector $x$ in $(X_{0}, X_{1})$ belongs to the interpolation space $t > 0$ if and only if it can be written as


 * $$x = \int_0^\infty v(t) \, \frac{dt}{t},$$

where $x ∈ X_{0} ∩ X_{1}$ is measurable with values in $X_{0} + X_{1}$ and such that


 * $$\Phi(v) = \left( \int_0^\infty \left( t^{-\theta} J(v(t), t; X_0, X_1) \right)^q \, \tfrac{dt}{t} \right)^{\frac{1}{q}} < \infty.$$

The norm of $x$ in $J_{θ,q}(X_{0}, X_{1})$ is given by the formula


 * $$\|x\|_{\theta,q;J} := \inf_v \left\{ \Phi(v) \ :\ x = \int_0^\infty v(t) \, \tfrac{dt}{t} \right\}.$$

Relations between the interpolation methods
The two real interpolation methods are equivalent when $v(t)$.


 * Theorem. Let $X_{0} ∩ X_{1}$ be a compatible couple of Banach spaces. If $J_{θ,q}(X_{0}, X_{1})$ and $0 < θ < 1$, then $$J_{\theta,q}(X_0, X_1) = K_{\theta,q}(X_0, X_1),$$ with equivalence of norms.

The theorem covers degenerate cases that have not been excluded: for example if $(X_{0}, X_{1})$ and $0 < θ < 1$ form a direct sum, then the intersection and the J-spaces are the null space, and a simple computation shows that the K-spaces are also null.

When $1 ≤ q ≤ ∞$, one can speak, up to an equivalent renorming, about the Banach space obtained by the real interpolation method with parameters $θ$ and $q$. The notation for this real interpolation space is $X_{0}$. One has that


 * $$(X_0, X_1)_{\theta, q} = (X_1, X_0)_{1 - \theta, q}, \qquad 0 < \theta < 1, 1 \le q \le \infty.$$

For a given value of $θ$, the real interpolation spaces increase with $q$: if $X_{1}$ and $0 < θ < 1$, the following continuous inclusion holds true:


 * $$(X_0, X_1)_{\theta, q} \subset (X_0, X_1)_{\theta, r}.$$


 * Theorem. Given $(X_{0}, X_{1})_{θ,q}$, $0 < θ < 1$ and two compatible couples $1 ≤ q ≤ r ≤ ∞$ and $0 < θ < 1$, the pair $1 ≤ q ≤ ∞$ is an exact interpolation pair of exponent $θ$.

A complex interpolation space is usually not isomorphic to one of the spaces given by the real interpolation method. However, there is a general relationship.


 * Theorem. Let $(X_{0}, X_{1})$ be a compatible couple of Banach spaces. If $(Y_{0}, Y_{1})$, then $$(X_0, X_1)_{\theta, 1} \subset (X_0, X_1)_\theta \subset (X_0, X_1)_{\theta, \infty}.$$

Examples
When $((X_{0}, X_{1})_{θ,q}, (Y_{0}, Y_{1})_{θ,q})$ and $(X_{0}, X_{1})$, the space of continuously differentiable functions on $0 < θ < 1$, the $X_{0} = C([0, 1])$ interpolation method, for $X_{1} = C^{1}([0, 1])$, gives the Hölder space $[0, 1]$ of exponent $θ$. This is because the K-functional $(θ, ∞)$ of this couple is equivalent to


 * $$ \sup \left\{ |f(u)|, \, \frac{|f(u) - f(v)|}{1 + t^{-1} |u - v|} \ : \ u, v \in [0, 1] \right\}.$$

Only values $0 < θ < 1$ are interesting here.

Real interpolation between $C^{0,θ}$ spaces gives the family of Lorentz spaces. Assuming $K(f, t; X_{0}, X_{1})$ and $0 < t < 1$, one has:


 * $$ \left ( L^1(\mathbf{R}, \Sigma, \mu), L^\infty(\mathbf{R}, \Sigma, \mu) \right)_{\theta, q} = L^{p, q}(\mathbf{R}, \Sigma, \mu), \qquad \text{where } \tfrac{1}{p} = 1 - \theta,$$

with equivalent norms. This follows from an inequality of Hardy and from the value given above of the K-functional for this compatible couple. When $L^{p}$, the Lorentz space $0 < θ < 1$ is equal to $1 ≤ q ≤ ∞$, up to renorming. When $q = p$, the Lorentz space $L^{p,p}$ is equal to weak-$L^{p}$.

The reiteration theorem
An intermediate space $X$ of the compatible couple $q = ∞$ is said to be of class θ if


 * $$(X_0, X_1)_{\theta,1} \subset X \subset (X_0, X_1)_{\theta,\infty},$$

with continuous injections. Beside all real interpolation spaces $L^{p,∞}$ with parameter $θ$ and $L^{p}$, the complex interpolation space $(X_{0}, X_{1})$ is an intermediate space of class $θ$ of the compatible couple $(X_{0}, X_{1})_{θ,q}$.

The reiteration theorems says, in essence, that interpolating with a parameter $θ$ behaves, in some way, like forming a convex combination $1 ≤ q ≤ ∞$: taking a further convex combination of two convex combinations gives another convex combination.


 * Theorem. Let $(X_{0}, X_{1})_{θ}$ be intermediate spaces of the compatible couple $(X_{0}, X_{1})$, of class $a = (1 − θ)x_{0} + θx_{1}$ and $A_{0}, A_{1}$ respectively, with $(X_{0}, X_{1})$. When $θ_{0}$ and $θ_{1}$, one has $$(A_0, A_1)_{\theta, q} = (X_0, X_1)_{\eta, q}, \qquad \eta = (1 - \theta) \theta_0 + \theta \theta_1.$$

It is notable that when interpolating with the real method between $0 < θ_{0} ≠ θ_{1} < 1$ and $0 < θ < 1$, only the values of $1 ≤ q ≤ ∞$ and $A_{0} = (X_{0}, X_{1})_{θ_{0},q_{0}}|undefined$ matter. Also, $A_{1} = (X_{0}, X_{1})_{θ_{1},q_{1}}|undefined$ and $θ_{0}$ can be complex interpolation spaces between $θ_{1}$ and $A_{0}$, with parameters $A_{1}$ and $X_{0}$ respectively.

There is also a reiteration theorem for the complex method.


 * Theorem. Let $X_{1}$ be a compatible couple of complex Banach spaces, and assume that $θ_{0}$ is dense in $θ_{1}$ and in $(X_{0}, X_{1})$. Let $X_{0} ∩ X_{1}$ and $X_{0}$, where $X_{1}$. Assume further that $A_{0} = (X_{0}, X_{1})_{θ_{0}}|undefined$ is dense in $A_{1} = (X_{0}, X_{1})_{θ_{1}}|undefined$. Then, for every $0 ≤ θ_{0} ≤ θ_{1} ≤ 1$, $$ \left( \left (X_0, X_1 \right )_{\theta_0}, \left (X_0, X_1 \right )_{\theta_1} \right)_\theta = (X_0, X_1)_\eta, \qquad \eta = (1 - \theta) \theta_0 + \theta \theta_1.$$

The density condition is always satisfied when $X_{0} ∩ X_{1}$ or $A_{0} ∩ A_{1}$.

Duality
Let $0 ≤ θ ≤ 1$ be a compatible couple, and assume that $X_{0} ⊂ X_{1}$ is dense in X0 and in X1. In this case, the restriction map from the (continuous) dual $$X'_j$$ of $X_{1} ⊂ X_{0}$, $(X_{0}, X_{1})$ to the dual of $X_{0} ∩ X_{1}$ is one-to-one. It follows that the pair of duals $$\left (X'_0, X'_1 \right )$$ is a compatible couple continuously embedded in the dual $X_{j}$.

For the complex interpolation method, the following duality result holds:


 * Theorem. Let $j = 0, 1,$ be a compatible couple of complex Banach spaces, and assume that $X_{0} ∩ X_{1}$ is dense in $(X_{0} ∩ X_{1})′$ and in $(X_{0}, X_{1})$. If $X_{0} ∩ X_{1}$ and $X_{0}$ are reflexive, then the dual of the complex interpolation space is obtained by interpolating the duals, $$ ( (X_0, X_1)_\theta )' = \left(X'_0, X'_1 \right )_\theta, \qquad 0 < \theta < 1.$$

In general, the dual of the space $X_{1}$ is equal to $$ \left (X'_0, X'_1 \right )^{\theta},$$ a space defined by a variant of the complex method. The upper-&theta; and lower-&theta; methods do not coincide in general, but they do if at least one of X0, X1 is a reflexive space.

For the real interpolation method, the duality holds provided that the parameter q is finite:


 * Theorem. Let $X_{0}$ and $X_{1}$ a compatible couple of real Banach spaces. Assume that $(X_{0}, X_{1})_{θ}$ is dense in $0 < θ < 1, 1 ≤ q < ∞$ and in $(X_{0}, X_{1})$. Then $$ \left ( \left (X_0, X_1 \right )_{\theta, q} \right )' = \left (X'_0, X'_1 \right )_{\theta, q'},$$ where $$\tfrac{1}{q'} = 1 - \tfrac{1}{q}.$$

Discrete definitions
Since the function $X_{0} ∩ X_{1}$ varies regularly (it is increasing, but $X_{0}$ is decreasing), the definition of the $X_{1}$-norm of a vector $n$, previously given by an integral, is equivalent to a definition given by a series. This series is obtained by breaking $t → K(x, t)$ into pieces $1⁄tK(x, t)$ of equal mass for the measure $K_{θ,q}$,


 * $$ \|x\|_{\theta, q; K} \simeq \left( \sum_{n \in \mathbf{Z}} \left( 2^{-\theta n} K \left (x, 2^n; X_0, X_1 \right ) \right)^q \right)^{\frac{1}{q}}.$$

In the special case where $(0, ∞)$ is continuously embedded in $(2^{n}, 2^{n+1})$, one can omit the part of the series with negative indices $n$. In this case, each of the functions $dt⁄t$ defines an equivalent norm on $X_{0}$.

The interpolation space $X_{1}$ is a "diagonal subspace" of an $x → K(x, 2^{n}; X_{0}, X_{1})$-sum of a sequence of Banach spaces (each one being isomorphic to $X_{1}$). Therefore, when $q$ is finite, the dual of $(X_{0}, X_{1})_{θ,q}$ is a quotient of the $ℓ^{&thinsp;q}$-sum of the duals, $X_{0} + X_{1}$, which leads to the following formula for the discrete $(X_{0}, X_{1})_{θ,q}$-norm of a functional x' in the dual of $ℓ^{&thinsp;p}$:


 * $$ \|x'\|_{\theta, p; J} \simeq \inf \left\{ \left( \sum_{n \in \mathbf{Z}} \left( 2^{\theta n} \max \left (\left \|x'_n \right \|_{X'_0}, 2^{-n} \left \|x'_n \right\|_{X'_1} \right ) \right)^p \right)^{\frac{1}{p}} \ : \ x' = \sum_{n \in \mathbf{Z}} x'_n \right\}.$$

The usual formula for the discrete $1⁄p + 1⁄q = 1$-norm is obtained by changing $n$ to $J_{θ,p}$.

The discrete definition makes several questions easier to study, among which the already mentioned identification of the dual. Other such questions are compactness or weak-compactness of linear operators. Lions and Peetre have proved that:


 * Theorem. If the linear operator $T$ is compact from $(X_{0}, X_{1})_{θ,q}$ to a Banach space $Y$ and bounded from $J_{θ,p}$ to $Y$, then $T$ is compact from $−n$ to $Y$ when $X_{0}$, $X_{1}$.

Davis, Figiel, Johnson and Pełczyński have used interpolation in their proof of the following result:


 * Theorem. A bounded linear operator between two Banach spaces is weakly compact if and only if it factors through a reflexive space.

A general interpolation method
The space $(X_{0}, X_{1})_{θ,q}$ used for the discrete definition can be replaced by an arbitrary sequence space Y with unconditional basis, and the weights $0 < θ < 1$, $1 ≤ q ≤ ∞$, that are used for the $ℓ^{&thinsp;q}$-norm, can be replaced by general weights


 * $$a_n, b_n > 0, \ \ \sum_{n=1}^\infty \min(a_n, b_n) < \infty.$$

The interpolation space $a_{n} = 2^{−θn}$ consists of the vectors $x$ in $b_{n} = 2^{(1−θ)n}$ such that


 * $$\|x\|_{K(X_0, X_1)} = \sup_{m \ge 1} \left \| \sum_{n=1}^m a_n K \left (x, \tfrac{b_n}{a_n}; X_0, X_1 \right) \, y_n \right\|_Y < \infty,$$

where {yn} is the unconditional basis of $Y$. This abstract method can be used, for example, for the proof of the following result:

Theorem. A Banach space with unconditional basis is isomorphic to a complemented subspace of a space with symmetric basis.

Interpolation of Sobolev and Besov spaces
Several interpolation results are available for Sobolev spaces and Besov spaces on Rn,


 * $$\begin{align}

&H^s_p && s \in \mathbf{R}, 1 \le p \le \infty \\ &B^s_{p, q} && s \in \mathbf{R}, 1 \le p, q \le \infty \end{align}$$

These spaces are spaces of measurable functions on $K_{θ,q}$ when $K(X_{0}, X_{1}, Y, {a_{n}}, {b_{n}})$, and of tempered distributions on $X_{0} + X_{1}$ when $R^{n}$. For the rest of the section, the following setting and notation will be used:


 * $$\begin{align}

0 &< \theta < 1, \\ 1 &\le p, p_0, p_1, q, q_0, q_1 \le \infty, \\ s, &s_0, s_1 \in \mathbf{R}, \\ s_\theta &= (1 - \theta) s_0 + \theta s_1, \\[4pt] \frac 1 {p_\theta} &= \frac{1 - \theta}{p_0} + \frac{\theta}{p_1}, \\[4pt] \frac 1 {q_\theta} &= \frac{1 - \theta}{q_0} + \frac{\theta}{q_1}. \end{align}$$

Complex interpolation works well on the class of Sobolev spaces $$H^{s}_{p}$$ (the Bessel potential spaces) as well as Besov spaces:


 * $$\begin{align}

\left (H^{s_0}_{p_0}, H^{s_1}_{p_1} \right )_\theta &= H^{s_\theta}_{p_\theta}, && s_0 \ne s_1, 1 < p_0, p_1 < \infty. \\ \left (B^{s_0}_{p_0,q_0}, B^{s_1}_{p_1,q_1} \right)_\theta &= B^{s_\theta}_{p_\theta, q_\theta}, && s_0 \ne s_1. \end{align}$$

Real interpolation between Sobolev spaces may give Besov spaces, except when $s ≥ 0$,


 * $$\left (H^{s}_{p_0}, H^{s}_{p_1} \right)_{\theta, p_\theta} = H^{s}_{p_\theta}.$$

When $R^{n}$ but $s < 0$, real interpolation between Sobolev spaces gives a Besov space:


 * $$\left (H^{s_0}_p, H^{s_1}_p \right)_{\theta, q} = B^{s_\theta}_{p, q}, \qquad s_0 \ne s_1.$$

Also,


 * $$\begin{align}

\left (B^{s_0}_{p,q_0}, B^{s_1}_{p,q_1} \right)_{\theta, q} &= B^{s_\theta}_{p,q}, && s_0 \ne s_1. \\ \left (B^s_{p,q_0}, B^s_{p, q_1} \right )_{\theta, q} &= B^{s}_{p, q_\theta}. \\ \left (B^{s_0}_{p_0,q_0}, B^{s_1}_{p_1,q_1} \right )_{\theta, q_\theta} &= B^{s_\theta}_{p_\theta, q_\theta}, && s_0 \ne s_1, p_\theta =q_\theta. \end{align}$$