1 Introduction
In optimal transport, a condition known as A3w is necessary for regularity of the optimal transport map. Here we provide a geometric interpretation of A3w. We use freely the notation from [Reference Ma, Trudinger and Wang4]. Let
$c \in C^2(\mathbf {R}^n \times \mathbf {R}^n)$
satisfy A1 and A2 (see Section 2). Keeping in mind the prototypical case
$c(x,y) = |x-y|^2$
, we fix
$x_0,y_0 \in \mathbf {R}^n$
and perform a linear transformation so that
$c_{xy}(x_0,y_0) = -I$
. Define coordinates
$$ \begin{align} q(x)&:= -c_y(x,y_0), \end{align} $$
$$ \begin{align} p(\,y)&:= -c_x(x_0,y), \end{align} $$
and denote the inverse transformations by
$x(q),y(p)$
. Write
$c(q,p) = c(x(q),y(p))$
and let
$q_0=q(x_0)$
and
$p_0=p(\,y_0)$
. We prove A3w is satisfied if and only if whenever these transformations are performed,
$$ \begin{align*} (q-q_0)\cdot (p-p_0) \geq 0 {\implies} c(q,p)+c(q_0,p_0) \leq c(q,p_0)+c(q_0,p). \end{align*} $$
Heuristically, A3w implies that when
$q-q_0$
‘points in the same direction’ as
$p-p_0$
, it is cheaper to transport q to p and
$q_0$
to
$p_0$
than the alternative q to
$p_0$
and
$q_0$
to p. Thus, A3w represents compatibility between directions in the cost-convex geometry and the cost of transport.
A3w first appeared (in a stronger form) in [Reference Ma, Trudinger and Wang4]. It was weakened in [Reference Trudinger and Wang6] and a new interpretation was given in [Reference Loeper2]. The impetus for the above interpretation is Lemma 2.1 in [Reference Chen and Wang1]. Our result can also be realised by a particular choice of c-convex function in the unpublished preprint [Reference Trudinger and Wang5].
2 Proof of result
Let
$c \in C^2(\mathbf {R}^n \times \mathbf {R}^n)$
satisfy the following well-known conditions.
-
A1. For each
$x_0,y_0 \in \mathbf {R}^n$
, the mappings are injective.
$$ \begin{align*} x \mapsto c_y(x,y_0) \quad\text{and} \quad y \mapsto c_x(x_0,y) \end{align*} $$
-
A2. For each
$x_0,y_0 \in \mathbf {R}^n$
, we have
$\det c_{i,j}(x_0,y_0) \neq 0$
.
Here, and throughout, subscripts before a comma denote differentiation with respect to the first variable, subscripts after a comma denote differentiation with respect to the second variable.
By A1, we define on
$\mathcal {U}:= \{(x,c_x(x,y)): x,y \in \mathbf {R}^n\}$
a mapping
$Y:\mathcal {U}\rightarrow \mathbf {R}^n$
by
$$ \begin{align*} c_x(x,Y(x,p)) = p. \end{align*} $$
The A3w condition, usually expressed with fourth derivatives but written here as in [Reference Loeper and Trudinger3], is the following statement.
-
A3w. Fix x. The function
is concave along line segments orthogonal to
$$ \begin{align*} p \mapsto c_{ij}(x,Y(x,p))\xi_i\xi_j\end{align*} $$
$\xi $
.
To verify A3w, it suffices to verify the midpoint concavity, that is, whenever
${\xi \cdot \eta = 0}$
, it follows that
$$ \begin{align} 0 \geq [c_{ij}(x,Y(x,p+\eta)) - 2c_{ij}(x,Y(x,p)) + c_{ij}(x,Y(x,p-\eta))]\xi_i\xi_j. \end{align} $$
Finally, we recall that a set
$A \subset \mathbf {R}^n$
is called c-convex with respect to
$y_0$
provided
$c_y(A,y_0)$
is convex. When the A3w condition is satisfied and
$y,y_0 \in \mathbf {R}^n$
are given, the section
$\{x \in \mathbf {R}^n: c(x,y)> c(x,y_0)\}$
is c-convex with respect to
$y_0$
[Reference Loeper and Trudinger3].
Now fix
$(x_0,p_0) \in \mathcal {U}$
and
$y_0 = Y(x_0,p_0)$
. To simplify the proof, we assume
$x_0,y_0,q_0,p_0 = 0$
. Up to an affine transformation (replace y with
$\tilde {y}:=-c_{xy}(0,0)y$
), we assume
$c_{xy}(0,0) = -I$
. Note that with
$q,p$
, as defined in (1.1), (1.2), this implies
${\partial q}/{\partial x}(0) = I$
. Put
$$ \begin{align*} \tilde{c}(x,y) &:= c(x,y) - c(x,0) - c(0,y) + c(0,0),\\ \overline{c}(q,p) &:= \tilde{c}(x(q),y(p)). \end{align*} $$
Theorem 2.1. The A3w condition is satisfied if and only if whenever the above transformations are applied, the following implication holds:
$$ \begin{align} q \cdot p \geq 0 {\implies} \overline{c}(q,p) \leq 0. \end{align} $$
Proof. Observe by a Taylor series
$$ \begin{align} \overline{c}(q,p) = -(q \cdot p) + \overline{c}_{ij}(\tau q,p)q_iq_j \end{align} $$
for some
$\tau \in (0,1)$
. First, assume A3w and let
$q \cdot p> 0$
. By (2.3), we have
$\overline {c}(-tq,p)> 0 > \overline {c}(tq,p)$
for
$t>0$
sufficiently small. If
$\overline {c}(q,p)> 0$
, then the c-convexity (in our coordinates, convexity) of the section
$$ \begin{align*} \{ q : \overline{c}(q,p)> \overline{c}(q,0) = 0 \} \end{align*} $$
is violated. By continuity,
$\overline {c}(q,p) \leq 0$
whenever
$q \cdot p \geq 0$
.
In the other direction, take nonzero q with
$q \cdot p = 0$
and small t. By (2.2) and (2.3),
$$ \begin{align*} 0 \geq \overline{c}(t q,p)/t^2 = \overline{c}_{ij}(t \tau q,p)q_iq_j. \end{align*} $$
This inequality also holds with
$-p$
. Moreover,
$\overline {c}_{ij}(t \tau q, 0) = 0$
. Thus,
$$ \begin{align*} 0 \geq [\overline{c}_{ij}(t \tau q,p) - 2\overline{c}_{ij}(t \tau q , 0) + \overline{c}_{ij}(t \tau q, -p)]q_iq_j.\end{align*} $$
Sending
$t \rightarrow 0$
and returning to our original coordinates, we obtain (2.1).
Remark 2.2. On a Riemannian manifold with
$c(x,y) = d(x,y)^2$
, for d the distance function, Loeper [Reference Loeper2] proved A3w implies nonnegative sectional curvature. Our result expedites his proof. Let
$x_0=y_0 \in M$
and
$u,v \in T_{x_0}M$
satisfy
$u\cdot v = 0$
with
$x = \exp _{x_0}(tu)$
and
$y=\exp _{x_0}(tv)$
. Working in a sufficiently small local coordinate chart, our previous proof implies that if A3w is satisfied,
$$ \begin{align} d(x,y)^2 \leq d(x_0,y)^2+d(x_0,x)^2 = 2t. \end{align} $$
The sectional curvature in the plane generated by
$u,v$
is the
$\kappa $
satisfying
$$ \begin{align} d(\exp_{x_0}(tu),\exp_{x_0}(tv)) = \sqrt{2}t\bigg(1-\frac{\kappa}{12}t^2+O(t^3)\bigg) \quad\text{as }t \rightarrow 0, \end{align} $$
whereby comparison with (2.4) proves the result. (See [Reference Villani7, Equation (1)] for (2.5).) We note Loeper proved his result using an infinitesimal version of (2.4).
Acknowledgements
My thanks to Jiakun Liu and Robert McCann for helpful comments and discussion.
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