Proof. Given a multiplicative operator $B\in \mathcal {L}_{r}(E_{1},\,\ldots,\,E_{m};\mathcal {A})$, let $T_{i}\colon E_{i}\longrightarrow \mathcal {A},\, i=1,\,\ldots,\,m$, be such that $B(x_{1},\,\ldots,\,x_{m})=T_{1}(x_{1})\ast \cdots \ast T_{m}(x_{m})$ for all $x_{1}\in E_{1},\,\ldots,\,x_{m}\in E_{m}$. By [Reference Botelho and Garcia6, Remark 3.3 and the proof of Theorem 3.2] we have that, for each $\rho \in S_{m}$ and all $x_{1}^{\prime \prime }\in E_{1}^{\sim \sim },\,\ldots,\,x_{m}^{\prime \prime }\in E_{m}^{\sim \sim }$,

\[ AR_{m}^{\rho}(B)(x_{1}^{\prime\prime},\ldots,x_{m}^{\prime\prime})=T_{\rho(m)}^{\prime\prime}(x_{\rho(m)}^{\prime\prime})\odot \cdots\odot T_{\rho(1)}^{\prime\prime}(x_{\rho(1)}^{\prime\prime}). \]

The Arens product $\odot$ makes $\mathcal {A}^{\sim \sim }$ a Dedekind complete, hence Archimedean, commutative $f$-algebra [Reference Yilmaz20, Corollaries 3.5 and 3.6], so

\[ AR_{m}^{\rho}(B)(x_{1}^{\prime\prime},\ldots,x_{m}^{\prime\prime})=T_{1}^{\prime\prime}(x_{1}^{\prime\prime})\odot \cdots\odot T_{m}^{\prime\prime}(x_{m}^{\prime\prime}), \]

which gives, in particular, that all Arens extensions of $A$ coincide. In order to check that $AR_{m}^{\rho }(B)$ is separately order continuous, let $j\in \{1,\,\ldots.m\}$, $x_{i}^{\prime \prime }\in E_{i}^{\sim \sim },\, i=1,\,\ldots,\,m$, with $i\neq j$ be given and let $(x_{\alpha _{j}}^{\prime \prime })_{\alpha _{j}\in \Omega _{j}}$ be a net in $E_{j}^{\sim \sim }$ such that $x_{\alpha _{j}}^{\prime \prime } \xrightarrow {\, o \,} 0$. There exists a net $(z_{\alpha _{j}}^{\prime \prime })_{\alpha _{j}\in \Omega _{j}}$ such that $z_{\alpha _{j}}^{\prime \prime } \downarrow 0$ and $|x_{\alpha _{j}}^{\prime \prime }|\leq z_{\alpha _{j}}^{\prime \prime }$ for every $\alpha _{j}\in \Omega _{j}$. The functional

\[ \varphi:=|T_{1}^{\prime\prime}(x_{1}^{\prime\prime})|\odot\cdots\odot |T_{j-1}^{\prime\prime}(x_{j-1}^{\prime\prime})|\odot |T_{j+1}^{\prime\prime}(x_{j+1}^{\prime\prime})|\odot \cdots\odot |T_{m}^{\prime\prime}(x_{m}^{\prime\prime})|\in \mathcal{A}^{{\sim}{\sim}} \]

is positive. Using again that the product $\odot$ is commutative and [Reference Aliprantis and Burkinshaw2, Exercise 12, p. 131],

\begin{align*} & |AR_{m}^{\rho}(B)(x_{1}^{\prime\prime},\ldots,x_{\alpha_{j}}^{\prime\prime},\ldots,x_{m}^{\prime\prime})|=| T_{1}^{\prime\prime}(x_{1}^{\prime\prime})\odot\cdots\odot T_{j}^{\prime\prime}(x_{\alpha_{j}}^{\prime\prime})\odot \cdots\odot T_{m}^{\prime\prime}(x_{m}^{\prime\prime})|\\ & \quad =|T_{1}^{\prime\prime}(x_{1}^{\prime\prime})|\odot\cdots\odot |T_{j-1}^{\prime}(x_{j-1}^{\prime\prime})|\odot |T_{j}^{\prime\prime}(x_{\alpha_{j}}^{\prime\prime})|\odot |T_{j+1}^{\prime\prime}(x_{j+1}^{\prime\prime})|\odot \cdots\odot |T_{m}^{\prime\prime}(x_{m}^{\prime\prime})|\\ & \quad =|T_{j}^{\prime\prime}(x_{\alpha_{j}}^{\prime\prime})|\odot \big(|T_{1}^{\prime\prime}(x_{1}^{\prime\prime})|\odot\cdots\odot |T_{j-1}^{\prime\prime}(x_{j-1}^{\prime\prime})|\odot |T_{j+1}^{\prime\prime}(x_{j+1}^{\prime\prime})|\odot \cdots\odot |T_{m}^{\prime\prime}(x_{m}^{\prime\prime})|\big)\\ & \quad =|T_{j}^{\prime\prime}(x_{\alpha_{j}}^{\prime\prime})|\odot \varphi\leq |T_{j}^{\prime\prime}|(|x_{\alpha_{j}}^{\prime\prime}|)\odot \varphi\leq |T_{j}^{\prime\prime}|(z_{\alpha_{j}}^{\prime\prime})\odot \varphi. \end{align*}

Now it is enough to prove that $|T_{j}^{\prime \prime }|(z_{\alpha _{j}}^{\prime \prime })\odot \varphi \downarrow 0$. Let $0\leq y^{\prime }\in \mathcal {A}^{\sim }$ be given. Then $\varphi \diamond y^{\prime }$ is positive and, since $|T_{j}^{\prime \prime }|$ is order continuous and positive [Reference Aliprantis and Burkinshaw2, Theorems 1.56 and 1.73],

\[ \big(|T_{j}^{\prime\prime}|(z_{\alpha_{j}}^{\prime\prime})\odot \varphi\big)(y^{\prime})=|T_{j}^{\prime\prime}|(z_{\alpha_{j}}^{\prime\prime})(\varphi\diamond y^{\prime})\downarrow 0, \]

from which it follows that $(|T_{j}^{\prime \prime }|(z_{\alpha _{j}}^{\prime \prime })\odot \varphi )\downarrow 0$ [Reference Aliprantis and Burkinshaw2, Theorem 1.18] and gives the separate order continuity of $AR_{m}^{\rho }(B)$.

The linearity of the correspondence $A \mapsto AR_{m}^{\rho }(A)$ gives the result for finite sums of multiplicative operators.

Proof. It is not difficult to check that if $A \in {\mathcal {L}}_r(E_1,\, \ldots,\, E_m)$ is separately order continuous and $y \in F$, then the operator

\[ (x_1, \ldots, x_m) \in E_1 \times \cdots \times E_m \mapsto A(x_1, \ldots, x_m)y \in F, \]

is separately order continuous as well. Now the result follows from Proposition 4.1 and from its proof.

Proof. It is straightforward that $B_{\alpha }\downarrow 0$ if $B_{\alpha }(x_{1},\,\ldots,\,x_{m})\downarrow 0$ in $F$ for all $x_{1}\in E_{1}^{+},\,\ldots,\, x_{m}\in E_{m}^{+}$. We prove the other implication by induction on $m$. The case $m=1$ follows from the Riesz-Kantorovich theorem [Reference Aliprantis and Burkinshaw2, Theorem 1.18]. Assume that the result holds for $n$ and let $(B_{\alpha })_\alpha$ be a net in $\mathcal {L}_{r}(E_{1},\,\ldots,\,E_{n+1}; F)$ such that $B_{\alpha }\downarrow 0$. Consider the canonical Riesz isomorphism

\[ \psi\colon \mathcal{L}_{r}(E_{1},\ldots,E_{n+1}; F)\longrightarrow \mathcal{L}_{r}(E_{1};\mathcal{L}_{r}(E_{2}\ldots,E_{n+1}; F)). \]

We have $0\leq \psi (B_{\alpha })\downarrow$ because $\psi$ is positive. Let $T \in \mathcal {L}_{r}(E_{1};\mathcal {L}_{r}(E_{2}\ldots,\,E_{n+1}; F))$ be such that $0\leq T\leq \psi (B_{\alpha })$ for every $\alpha$. Since $\psi ^{-1}$ is positive, $0 \leq \psi ^{-1}(T)\leq B_{\alpha }\downarrow 0$, hence $0\leq \psi ^{-1}(T)\leq 0$, which proves that $\psi (B_{\alpha })\downarrow 0$ in $\mathcal {L}_{r}(E_{1};\mathcal {L}_{r}(E_{2}\ldots,\,E_{n+1}; F))$. The linear case of the result gives that $\psi (B_{\alpha })(x_{1})\downarrow 0$ in $\mathcal {L}_{r}(E_{2}\ldots,\,E_{n+1}; F)$ for every $x_{1}\in E_{1}^{+}$. The induction hypothesis gives that, regardless of the $x_{2}\in E_{2}^{+},\,\ldots,\,x_{n+1}\in E_{n+1}^{+}$,

\[ B_{\alpha}(x_{1},x_{2},\ldots,x_{n+1})=\psi(B_{\alpha})(x_{1})(x_{2},\ldots,x_{n+1})\downarrow 0, \]

completing the proof.

Proof. We already know that $\overline {x_{\rho (k)}^{\prime \prime }}$ is a regular linear operator, $\big |\overline {x_{\rho (k)}^{\prime \prime }} \big |\leq \overline {|x_{\rho (k)}^{\prime \prime }|}$ because $B^{k}$ is positive for every positive $B\in \mathcal {L}_{r}(E_{\rho (k)},\,\ldots,\,E_{\rho (m)})$, so

\[ \overline{|x_{\rho(k)}^{\prime\prime}|}(B)=|x_{\rho(k)}^{\prime\prime}|\circ B^{k}\geq{\pm} x_{\rho(k)}^{\prime\prime}\circ B^{k}={\pm} \big(x_{\rho(k)}^{\prime\prime}\circ B^{k}\big)={\pm} \overline{x_{\rho(k)}^{\prime\prime}}( B). \]

Let $(A_{\alpha })_{\alpha \in \Omega }$ be a net in $\mathcal {L}_{r}(E_{\rho (k)},\,\ldots,\,E_{\rho (m)})$ such that $A_{\alpha }\xrightarrow {\, o\, } 0$. Then there are a net $(B_{\alpha })_{\alpha \in \Omega }$ in $\mathcal {L}_{r}(E_{\rho (k)},\,\ldots,\,E_{\rho (m)})$ and $\alpha _{0}\in \Omega$ such that $B_{\alpha }\downarrow 0$ and $|A_{\alpha }|\leq B_{\alpha }$ for every $\alpha \geq \alpha _{0}$. Thus,

\[ \big|\overline{x_{\rho(k)}^{\prime\prime}}(A_{\alpha})\big|\leq \big|\overline{x_{\rho(k)}^{\prime\prime}}\big|(|A_{\alpha}|)\leq \overline{|x_{\rho(k)}^{\prime\prime}|}(|A_{\alpha}|)\leq \overline{|x_{\rho(k)}^{\prime\prime}|}(B_{\alpha}) \text{ for every } \alpha\geq \alpha_{0}. \]

For $x_{i}\in E_{\rho (i)}^{+}$, $i\in \{k,\,\ldots,\,m\}$, Lemma 4.4 gives

\[ B_{\alpha}^{k}(x_{k+1},\ldots,x_{m})(x_{k})=B_{\alpha}(x_{k},x_{k+1},\ldots,x_{m})\downarrow 0. \]

By [Reference Aliprantis and Burkinshaw2, Theorem 1.18] it follows that $B_{\alpha }^{k}(x_{k+1},\,\ldots,\,x_{m})\downarrow 0$. Since $x_{\rho (k)}^{\prime \prime }$ is an order continuous functional, $|x_{\rho (k)}^{\prime \prime }|$ is a positive order continuous operator [Reference Aliprantis and Burkinshaw2, Theorem 1.56], so $|x_{\rho (k)}^{\prime \prime }|(B_{\alpha }^{k}(x_{k+1},\,\ldots,\,x_{m}))\downarrow 0$, that is, $\overline {|x_{\rho (k)}^{\prime \prime }|}(B_{\alpha })(x_{k+1},\,\ldots,\,x_{m})\downarrow 0.$ Calling on Lemma 4.4 once again it follows that $\overline {|x_{\rho (k)}^{\prime \prime }|}(B_{\alpha })\downarrow 0$, proving that $\overline {x_{\rho (k)}^{\prime \prime }}$ is order continuous.

Proof. It is clear that (b) and (c) follow from (a) (for (c) just take $j = m$ in (a)). To prove (a), take $j\in \{1,\,\ldots,\,m\}$, $x_{\rho (i)}^{\prime \prime }\in E_{\rho (i)}^{\sim \sim },\, i=1,\,\ldots,\,j-1$, and $x_{\rho (i)}^{\prime \prime }\in (E_{\rho (i)}^{\sim })_{n}^{\sim },\, i=j+1,\,\ldots,\,m$. Given a net $(x_{\alpha _{\rho (j)}}^{\prime \prime })_{\alpha _{\rho (j)}\in \Omega _{\rho (j)}}$ in $E_{\rho (j)}^{\sim \sim }$ such that $x_{\alpha _{\rho (j)}}^{\prime \prime } \xrightarrow {\, o \, } 0$, there is a net $(z_{\alpha _{\rho (j)}}^{\prime \prime })_{\alpha _{\rho (j)}\in \Omega _{\rho (j)}}$ in $E_{\rho (j)}^{\sim \sim }$ and $\alpha _{\rho (j)_{0}}$ such that $z_{\alpha _{\rho (j)}}^{\prime \prime }\downarrow 0$ and $|x_{\alpha _{\rho (j)}}^{\prime \prime }|\leq z_{\alpha _{\rho (j)}}^{\prime \prime }$ for every $\alpha _{\rho (j)}\geq \alpha _{\rho (j)_{0}}$. Let $A_{1},\, A_{2}\in \mathcal {L}_{r}(E_{1},\,\ldots,\,E_{m};F)$ be positive operators such that $A=A_{1}-A_{2}$ and put $B:=A_{1}+A_{2}$. Of course $B$ is positive. Denoting the operator in (4.1) by $AR_{m}^{\rho }(A)_{x_{\rho (1)}^{\prime \prime },\,\ldots,\,x_{\rho (j-1)}^{\prime \prime },\,x_{\rho (j+1)}^{\prime \prime },\,\ldots,\,x_{\rho (m)}^{\prime \prime }}$, for every $\alpha _{\rho (j)}\geq \alpha _{\rho (j)_{0}}$,

\begin{align*} & |AR_{m}^{\rho}(A)_{x_{\rho(1)}^{\prime\prime},\ldots,x_{\rho(j-1)}^{\prime\prime},x_{\rho(j+1)}^{\prime\prime},\ldots,x_{\rho(m)}^{\prime\prime}}(x_{\alpha_{\rho(j)}}^{\prime\prime})| =|AR_{m}^{\rho}(A)(x_{1}^{\prime\prime},\ldots,x_{\alpha_{\rho(j)}}^{\prime\prime},\ldots,x_{m}^{\prime\prime})|\\ & \quad \leq |AR_{m}^{\rho}(A)|(|x_{1}^{\prime\prime}|,\ldots,|x_{\alpha_{\rho(j)}}^{\prime\prime}|,\ldots,|x_{m}^{\prime\prime}|)\\ & \quad = |AR_{m}^{\rho}(A_{1})-AR_{m}^{\rho}(A_{2})|(|x_{1}^{\prime\prime}|,\ldots,|x_{\alpha_{\rho(j)}}^{\prime\prime}|,\ldots,|x_{m}^{\prime\prime}|)\\ & \quad \leq \big(AR_{m}^{\rho}(A_{1})+AR_{m}^{\rho}(A_{2}) \big) (|x_{1}^{\prime\prime}|,\ldots,|x_{\alpha_{\rho(j)}}^{\prime\prime}|,\ldots,|x_{m}^{\prime\prime}|)\\ & \quad = AR_{m}^{\rho}(B)(|x_{1}^{\prime\prime}|,\ldots,|x_{\alpha_{\rho(j)}}^{\prime\prime}|,\ldots,|x_{m}^{\prime\prime}|)\\ & \quad =AR_{m}^{\rho}(B)_{|x_{\rho(1)}^{\prime\prime}|,\ldots,|x_{\rho(j-1)}^{\prime\prime}|,|x_{\rho(j+1)}^{\prime\prime}|,\ldots,|x_{\rho(m)}^{\prime\prime}|}(|x_{\alpha_{\rho(j)}}^{\prime\prime}|)\\ & \quad \leq AR_{m}^{\rho}(B)_{|x_{\rho(1)}^{\prime\prime}|,\ldots,|x_{\rho(j-1)}^{\prime\prime}|,|x_{\rho(j+1)}^{\prime\prime}|,\ldots,|x_{\rho(m)}^{\prime\prime}|}(z_{\alpha_{\rho(j)}}^{\prime\prime}). \end{align*}

As Arens extensions of positive operators are positive, it follows that

\[ 0\leq AR_{m}^{\rho}(B)_{|x_{\rho(1)}^{\prime\prime}|,\ldots,|x_{\rho(j-1)}^{\prime\prime}|,|x_{\rho(j+1)}^{\prime\prime}|,\ldots,|x_{\rho(m)}^{\prime\prime}|}(z_{\alpha_{\rho(j)}}^{\prime\prime})\downarrow. \]

Setting $T:=\overline {|x_{\rho (m)}^{\prime \prime }|}\circ \cdots \circ \overline {|x_{\rho (j+1)}^{\prime \prime }|}$, since each $|x_{\rho (i)}^{\prime \prime }|,\, i=j+1,\,\ldots,\,m$, is order continuous, by Lemma 4.5 it follows that $\overline {|x_{\rho (i)}^{\prime \prime }|}$ is order continuous, so $T$ is order continuous and positive. On the other hand, it is clear that, for every positive $y^{\prime }\in F^{\sim }$,

\[ S:=\big(\overline{|x_{\rho(j-1)}^{\prime\prime}|}\circ \cdots\circ \overline{|x_{\rho(1)}^{\prime\prime}|}\big)((y^{\prime}\circ B)_{\rho})\in \mathcal{L}_{r}(E_{\rho(j)},\ldots,\ldots,E_{\rho(m)}) \]

is positive. From $z_{\alpha _{\rho (j)}}^{\prime \prime }\downarrow 0$ we conclude that $\overline {z_{\alpha _{\rho (j)}}^{\prime \prime }}(S)\downarrow 0$, therefore $T(\overline {z_{\alpha _{\rho (j)}}^{\prime \prime }}(S))\downarrow 0$. It follows that, for every positive $y^{\prime }\in F^{\sim }$,

\begin{align*} & AR_{m}^{\rho}(B)_{|x_{\rho(1)}^{\prime\prime}|,\ldots,|x_{\rho(j-1)}^{\prime\prime}|,|x_{\rho(j+1)}^{\prime\prime}|,\ldots,|x_{\rho(m)}^{\prime\prime}|}(z_{\alpha_{\rho(j)}}^{\prime\prime})(y^{\prime})\\ & \quad =AR_{m}^{\rho}(B)(|x_{1}^{\prime\prime}|,\ldots,z_{\alpha_{\rho(j)}}^{\prime\prime},\ldots,|x_{m}^{\prime\prime}|)(y^{\prime})\\ & \quad =\big(\overline{|x_{\rho(m)}^{\prime\prime}|}\circ\cdots\circ \overline{|x_{\rho(j+1)}^{\prime\prime}|}\circ \overline{z_{\alpha_{\rho(j)}}^{\prime\prime}}\circ \overline{|x_{\rho(j-1)}^{\prime\prime}|}\circ \cdots\circ \overline{|x_{\rho(1)}^{\prime\prime}|}\big)((y^{\prime}\circ B)_{\rho})\\ & \quad =\big(T\circ \overline{z_{\alpha_{\rho(j)}}^{\prime\prime}}\circ \overline{|x_{\rho(j-1)}^{\prime\prime}|}\circ \cdots\circ \overline{|x_{\rho(1)}^{\prime\prime}|}\big)((y^{\prime}\circ B)_{\rho})\\ & \quad =T\big(\big(\overline{z_{\alpha_{\rho(j)}}^{\prime\prime}}\circ \overline{|x_{\rho(j-1)}^{\prime\prime}|}\circ \cdots\circ \overline{|x_{\rho(1)}^{\prime\prime}|}\big)((y^{\prime}\circ B)_{\rho})\big)\\ & \quad =T\big(\overline{z_{\alpha_{\rho(j)}}^{\prime\prime}}\big(\big(\overline{|x_{\rho(j-1)}^{\prime\prime}|}\circ \cdots\circ \overline{|x_{\rho(1)}^{\prime\prime}|}\big)((y^{\prime}\circ B)_{\rho})\big)\big)=T(\overline{z_{\alpha_{\rho(j)}}^{\prime\prime}}(S))\downarrow 0. \end{align*}

Lemma 4.4 gives that $AR_{m}^{\rho }(B)_{|x_{\rho (1)}^{\prime \prime }|,\,\ldots,\,|x_{\rho (j-1)}^{\prime \prime }|,\,|x_{\rho (j+1)}^{\prime \prime }|,\,\ldots,\,|x_{\rho (m)}^{\prime \prime }|}(z_{\alpha _{\rho (j)}}^{\prime \prime })\downarrow 0$, and this allows us to conclude that $AR_{m}^{\rho }(A)_{x_{\rho (1)}^{\prime \prime },\,\ldots,\,x_{\rho (j-1)}^{\prime \prime },\,x_{\rho (j+1)}^{\prime \prime },\,\ldots,\,x_{\rho (m)}^{\prime \prime }}$ is order continuous.

Proof. Write $P=P_{1}-P_{2}$, where $P_1$ and $P_2$ are positive $m$-homogeneous polynomials, and let $\check {P}_{1},\, \check {P}_{2}\colon E^{m}\longrightarrow F$ be the positive symmetric $m$-linear operators associated to $P_1$ and $P_2$, respectively. Let $(x_{\alpha }^{\prime \prime })_{\alpha \in \Omega }$ be a net in $E^{\sim \sim }$ such that $x_{\alpha }^{\prime \prime }\xrightarrow {\, o \,} 0$. There are a net $(z_{\alpha }^{\prime \prime })_{\alpha \in \Omega }$ in $E^{\sim \sim }$ and $\alpha _{0}\in \Omega$ such that $z_{\alpha }^{\prime \prime }\downarrow 0$ and $|x_{\alpha }^{\prime \prime }|\leq z_{\alpha }^{\prime \prime }$ for every $\alpha \geq \alpha _{0}$. For a permutation $\rho \in S_m$, we know from Theorem 4.6 that the operator

\[ x'' \in E^{{\sim}{\sim}} \mapsto AR_m^{\rho}(\check{P}_1 + \check{P}_2)(z''_{\alpha_0}, \ldots, z''_{\alpha_0}, x'', z''_{\alpha_0}, \ldots, z''_{\alpha_0}), \]

where $x''$ is placed at the $\rho (m)$-th coordinate, is order continuous. For $\alpha \geq \alpha _{0}$ we have $z_{\alpha }^{\prime \prime }\leq z_{\alpha _{0}}^{\prime \prime }$, so, using that $AR_m^{\rho }(\check {P}_1 + \check {P}_2)$ is positive,

\begin{align*} |AR_m^\rho(P)(x_{\alpha}^{\prime\prime})|& =|AR_m^\rho(P_1 - P_2)(x_{\alpha}^{\prime\prime})| = |AR_m^\rho((P_1 - P_2)^{{\vee}})(x_{\alpha}^{\prime\prime}, \ldots , x_{\alpha}^{\prime\prime})| \\ & =|AR_{m}^{\rho}(\check{P}_{1}-\check{P}_{2})(x_{\alpha}^{\prime\prime},\ldots,x_{\alpha}^{\prime\prime})|\leq |AR_{m}^{\rho}(\check{P}_{1}-\check{P}_{2})|(|x_{\alpha}^{\prime\prime}|,\ldots,|x_{\alpha}^{\prime\prime}|)\\ & \leq |AR_{m}^{\rho}(\check{P}_{1}-\check{P}_{2})|(z_{\alpha}^{\prime\prime},\ldots,z_{\alpha}^{\prime\prime}) \leq AR_{m}^{\rho}(\check{P}_{1}+\check{P}_{2})(z_{\alpha}^{\prime\prime},\ldots,z_{\alpha}^{\prime\prime}) \\ & \leq AR_{m}^{\rho}(\check{P}_{1}+\check{P}_{2})(z_{\alpha_{0}}^{\prime\prime},\ldots,z_{\alpha_{0}}^{\prime\prime}, z_{\alpha}^{\prime\prime},z_{\alpha_{0}}^{\prime\prime},\ldots,z_{\alpha_{0}}^{\prime\prime})\downarrow 0. \end{align*}

This proves that $AR_m^\rho (P)(x_{\alpha }^{\prime \prime })\xrightarrow {\, o\,} 0$.

Proof. Let $i,\,j=1,\,\ldots,\,m,\, i\neq j$, and $T\in \mathcal {L}_{r}(E_{i};E_{j}^{\ast })$ be given. For $k=1,\,\ldots,\,m,\, i \neq k\neq j$, choose $0 \neq \varphi _{k}\in E_{k}^{\ast }$ and consider the regular $m$-linear form

\[ A\colon E_{1}\times\cdots\times E_{m}\longrightarrow \mathbb{R},~A(x_{1},\ldots,x_{m})=\Bigg(\displaystyle\prod_{ \substack{k=1 \\ k\neq i, j}}^{m}\varphi_{k}(x_{k})\Bigg)T(x_{i})(x_{j}). \]

Of course we can assume $i< j$. Using the Davie–Gamelin description of the Arens extensions [Reference Davie and Gamelin12], for $x_l^{**} \in E_l^{**}$ and nets $(x_{\alpha _{l}})_{\alpha _{l}\in \Omega _{l}}$ in $E_{l}$ such that $x_{l}^{\ast \ast }=\omega ^{\ast }-\displaystyle \lim _{\alpha _{l}}J_{E_{l}}(x_{\alpha _{l}}),\, l=1,\,\ldots,\,m$, we have

\begin{align*} & A^{{\ast}[m+1]}(x_{1}^{{\ast}{\ast}},\ldots,x_{i}^{{\ast}{\ast}},\ldots,x_{j}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}})=\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i}}\cdots\lim_{\alpha_{j}}\cdots\lim_{\alpha_{m}} A(x_{\alpha_{1}},\ldots,x_{\alpha_{m}})\\ & \quad =\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i}}\cdots\lim_{\alpha_{j}}\cdots\lim_{\alpha_{m}} \Bigg(\displaystyle\prod_{ \substack{k=1 \\ k\neq i, j}}^{m}\varphi_{k}(x_{\alpha_{k}})\Bigg)T(x_{\alpha_{i}})(x_{\alpha_{j}})\\ & \quad=\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i}}\cdots\lim_{\alpha_{j}}\cdots\lim_{\alpha_{m-1}} \Bigg(\displaystyle\prod_{ \substack{k=1 \\ k\neq i, j}}^{m-1}\varphi_{k}(x_{\alpha_{k}})\Bigg)T(x_{\alpha_{i}})(x_{\alpha_{j}})\lim_{\alpha_{m}} J_{E_{m}}(x_{\alpha_{m}})(\varphi_{m}) \\ & \quad=\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i}}\cdots\lim_{\alpha_{j}}\cdots\lim_{\alpha_{m-1}} \Bigg(\displaystyle\prod_{ \substack{k=1 \\ k\neq i, j}}^{m-1}\varphi_{k}(x_{\alpha_{k}})\Bigg)T(x_{\alpha_{i}})(x_{\alpha_{j}}) x_{m}^{{\ast}{\ast}}(\varphi_{m})\\ & \quad \vdots\\ & \quad=\prod_{ \substack{k=i+1\\ k\neq j}}^{m}x_{k}^{{\ast}{\ast}}(\varphi_{k})\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i}}\Bigg(\displaystyle\prod_{ \substack{k=1}}^{i-1}\varphi_{k}(x_{\alpha_{k}})\Bigg) x_{j}^{{\ast}{\ast}}( T(x_{\alpha_{i}}))\\ & \quad=\prod_{ \substack{k=i+1\\ k\neq j}}^{m}x_{k}^{{\ast}{\ast}}(\varphi_{k})\lim_{\alpha_{1}}\cdots\lim_{\alpha_{i-1}}\Bigg(\displaystyle\prod_{ \substack{k=1}}^{i-1}\varphi_{k}(x_{\alpha_{k}})\Bigg) \lim_{\alpha_{i}}T^{{\ast}}(x_{j}^{{\ast}{\ast}})( x_{\alpha_{i}})\\ & \quad=\prod_{ \substack{k=1\\ k\neq i, j}}^{m}x_{k}^{{\ast}{\ast}}(\varphi_{k}) \lim_{\alpha_{i}} J_{E_{i}}( x_{\alpha_{i}})(T^{{\ast}}(x_{j}^{{\ast}{\ast}}))=\Bigg(\prod_{ \substack{k=1\\ k\neq i, j}}^{m}x_{k}^{{\ast}{\ast}}(\varphi_{k})\Bigg)x_{i}^{{\ast}{\ast}}(T^{{\ast}}(x_{j}^{{\ast}{\ast}}))\\ & \quad =\Bigg(\prod_{ \substack{k=1\\ k\neq i, j}}^{m}x_{k}^{{\ast}{\ast}}(\varphi_{k})\Bigg) T^{{\ast}{\ast}}(x_{i}^{{\ast}{\ast}})(x_{j}^{{\ast}{\ast}}). \end{align*}

Choosing $x_{k}\in E_{k}$ so that $\varphi _k(x_{k})=1$, $i \neq k \neq j$, we get

\begin{align*} A^{{\ast}[m+1]}(J_{E_{1}}(x_{1}),\ldots,x_{i}^{{\ast}{\ast}},\ldots, x_{j}^{{\ast}{\ast}},\ldots,J_{E_{m}}(x_{m})) =T^{{\ast}{\ast}}(x_{i}^{{\ast}{\ast}})(x_{j}^{{\ast}{\ast}}). \end{align*}

Since $A^{\ast [m+1]}$ is separately order continuous by assumption, the functional $T^{\ast \ast }(x_{i}^{\ast \ast })$ is order continuous for every $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast }$.

Proof. Let $(x_{\alpha _{i}}^{\ast \ast })_{\alpha _{i}\in \Omega _{i}}$ be a net in $E_{i}^{\ast \ast }$ such that $x_{\alpha _{i}}^{\ast \ast }\xrightarrow {\, \omega ^{\ast } \,} x_{i}^{\ast \ast }\in E_{i}^{\ast \ast }$. For every $x_{i}^{\ast }\in E_{i}^{\ast }$ we have $x_{i}^{\ast \ast }(x_{i}^{\ast })=\displaystyle \lim _{\alpha _{i}}x_{\alpha _{i}}^{\ast \ast }(x_{i}^{\ast })$. Given $x_{1}\in E_{1},\,\ldots,\,x_{i-1}\in E_{i-1}$ and $x_{j}^{\ast \ast }\in E_{j}^{\ast \ast },\, j=i+1,\,\ldots,\,m$,

\begin{align*} & A^{{\ast}[m+1]}(J_{E_{1}}(x_{1}),\ldots,J_{E_{i-1}}(x_{i-1}),x_{i}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}})\\ & \quad =\big(\overline{J_{E_{1}}(x_{1})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\\ & \quad =\overline{J_{E_{1}}(x_{1})}\big(\big(\overline{J_{E_{2}}(x_{2})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)\\ & \quad =J_{E_{1}}(x_{1})\big(\big(\overline{J_{E_{2}}(x_{2})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)\\ & \quad =\big(\overline{J_{E_{2}}(x_{2})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})(x_{1})\\ & \quad =\overline{J_{E_{2}}(x_{2})}\big(\big(\overline{J_{E_{3}}(x_{3})} \circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)(x_{1})\\ & \quad =J_{E_{2}}(x_{2})\big(\big(\big(\overline{J_{E_{3}}(x_{3})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)^{m-1}(x_{1})\big)\\ & \quad =\big(\big(\overline{J_{E_{3}}(x_{3})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)^{m-1}(x_{1})(x_{2})\\ & \quad =\big(\overline{J_{E_{3}}(x_{3})}\circ\cdots\circ \overline{J_{E_{i-1}}(x_{i-1})}\circ \overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})(x_{2},x_{1})\\ & \quad \vdots\\ & \quad =\big(\overline{x_{i}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})(x_{i-1},\ldots,x_{1})\\ & \quad =\overline{x_{i}^{{\ast}{\ast}}}\big(\big(\overline{x_{i+1}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)(x_{i-1},\ldots,x_{1})\\ & \quad =x_{i}^{{\ast}{\ast}}\big(\big(\big(\overline{x_{i+1}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)^{m-i+1}(x_{i-1},\ldots,x_{1})\big)\\ & \stackrel{(\Delta)}{=}\displaystyle\lim_{\alpha_{i}}x_{\alpha_{i}}^{{\ast}{\ast}}\big(\big(\big(\overline{x_{i+1}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{m}^{{\ast}{\ast}}}\big)(A_{\theta})\big)^{m-i+1}(x_{i-1},\ldots,x_{1}))\\ & \quad =\displaystyle\lim_{\alpha_{i}}A^{{\ast}[m+1]}(J_{E_{1}}(x_{1}),\ldots,J_{E_{i-1}}(x_{i-1}),x_{\alpha_{i}}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}}), \end{align*}

where, in $(\Delta )$, we used that $((\overline {x_{i+1}^{\ast \ast }}\circ \cdots \circ \overline {x_{m}^{\ast \ast }})(A_{\theta }))^{m-i+1}(x_{i-1},\,\ldots,\,x_{1})\in E_{i}^{\ast }$.

Proof. We shall proceed by induction on $m$. Given $A\in \mathcal {L}_{r}(E_{1},\,E_{2})$, $A^{***}$ has property $\mathcal {P}$ in the first variable because $\mathcal {P}$ is an Arens property. Let us prove that, for every $x_{1}^{\ast \ast }\in E_{1}^{\ast \ast }$, $A^{***}(x_{1}^{\ast \ast },\,\bullet )\in E_{2}^{\ast \ast \ast }$ has property $\mathcal {P}$. Recall that $A_{\theta }\colon E_{2}\times E_{1}\longrightarrow \mathbb {R}$ and consider the regular linear operator $T:=A_{\theta }^{1}\colon E_{1}\longrightarrow E_{2}^{\ast }$, $T(x_{2})(x_{1})=A_{\theta }(x_{1},\,x_{2})$. For all $x_{2}^{\ast \ast }\in E_{2}^{\ast \ast }$ and $x_{2}\in E_{1}$,

\[ T^{{\ast}}(x_{2}^{{\ast}{\ast}})(x_{2})=x_{2}^{{\ast}{\ast}}(T(x_{2}))=x_{2}^{{\ast}{\ast}}(A_{\theta}^{1}(x_{2}))=(x_{2}^{{\ast}{\ast}}\circ A_{\theta}^{1})(x_{2})=\overline{x_{2}^{{\ast}{\ast}}}(A_{\theta})(x_{2}), \]

that is, $T^{\ast }(x_{2}^{\ast \ast })=\overline {x_{2}^{\ast \ast }}(A_{\theta }).$ So, for all $x_{1}^{\ast \ast }\in E_{1}^{\ast \ast },\, x_{2}^{\ast \ast }\in E_{2}^{\ast \ast }$,

\[ T^{{\ast}{\ast}}(x_{1}^{{\ast}{\ast}})(x_{2}^{{\ast}{\ast}})=x_{1}^{{\ast}{\ast}}(T^{{\ast}}(x_{2}^{{\ast}{\ast}}))=x_{1}^{{\ast}{\ast}}\big(\overline{x_{2}^{{\ast}{\ast}}}(A_{\theta})\big)=\big(\overline{x_{1}^{{\ast}{\ast}}}\circ \overline{x_{2}^{{\ast}{\ast}}}\big)(A_{\theta})=A^{***}(x_{1}^{{\ast}{\ast}},x_{2}^{{\ast}{\ast}}). \]

Since $T^{\ast \ast }(x_{1}^{\ast \ast })$ has property $\mathcal {P}$ by assumption, it follows that $A^{***}(x_{1}^{\ast \ast },\,\bullet )$ has property $\mathcal {P}$. This shows that the result holds for $m=2$.

Assume now that the result holds for $n$ and let us prove it holds for $n+1$. To do so we suppose that conditions (a) and (b) hold for $n+1$. Let $A\in \mathcal {L}_{r}(E_{1},\,\ldots,\,E_{n+1})$ be given. For every $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast },\, i=2,\,\ldots,\,n+1$, we have

\[ \overline{x_{n-i+2}^{{\ast}{\ast}}}\colon\mathcal{L}_{r}(E_{n-i+2},\ldots,E_{1})\longrightarrow \mathcal{L}_{r}(E_{n-i+1},\ldots,E_{1}),\quad \overline{x_{n-i+2}^{{\ast}{\ast}}}(B)=x_{n-i+2}^{{\ast}{\ast}}\circ B^{i}, \]

where $B^{i}\colon E_{n-i+1}\times \cdots \times E_{1}\longrightarrow E_{n-i+2}^{\ast },\, B^{i}(x_{i+1},\,\ldots,\,x_{n+1})(x_{i})=B(x_{i},\,x_{i+1}, \ldots,\,x_{n+1})$. And for each $x_{1}^{\ast \ast }\in E_{1}^{\ast \ast }$, the functional $\overline {x_{1}^{\ast \ast }}\colon E_{1}^{\ast }\longrightarrow \mathbb {R}$ is given by $\overline {x_{1}^{\ast \ast }}=x_{1}^{\ast \ast }$. Moreover,

\begin{align*} A^{{\ast}[n+2]}(x_{1}^{{\ast}{\ast}},\ldots,x_{n+1}^{{\ast}{\ast}})& =\big(\overline{x_{1}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{n+1}^{{\ast}{\ast}}}\big)(A_{\theta})=\big(\overline{x_{1}^{{\ast}{\ast}}}\circ \cdots\circ \overline{x_{n}^{{\ast}{\ast}}}\big)\big(\overline{x_{n+1}^{{\ast}{\ast}}}(A_{\theta})\big)\\ & =\big(\overline{x_{n+1}^{{\ast}{\ast}}}(A_{\theta})\big)^{{\ast}[n+1]}(x_{1}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}). \end{align*}

Since $\overline {x_{n+1}^{\ast \ast }}(A_{\theta })\in \mathcal {L}_{r}(E_{n},\,\ldots,\,E_{1})$, by the induction hypothesis we have that $(\overline {x_{n+1}^{\ast \ast }}(A_{\theta }))^{\ast [n+1]}$ has $\mathcal {P}$-separately, so $A^{\ast [n+2]}$ has property $\mathcal {P}$ in the first $n$ variables. To prove that $A^{\ast [n+2]}$ has property $\mathcal {P}$ in the $(n+1)$-th variable, let $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast },\, i=1,\,\ldots,\,n$, be given. Our job is to show that $A^{\ast [n+2]}(x_{1}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast },\,\bullet )\colon E_{n+1}^{\ast \ast }\longrightarrow \mathbb {R}$ has property $\mathcal {P}$. Recall that $A_{\theta }\colon E_{n+1}\times \cdots \times E_{1}\longrightarrow \mathbb {R}$ is given by $A_{\theta }(x_{1},\,\ldots,\,x_{n+1})=A(x_{n+1},\,\ldots,\,x_{1})$ and $A_{\theta }^{1}\colon E_{n}\times \cdots \times E_{1}\longrightarrow E_{n+1}^{\ast },\, A_{\theta }^{1}(x_{2},\,\ldots,\,x_{n+1})(x_{1})=A_{\theta }(x_{1},\,x_{2},\,\ldots,\,x_{n+1})$. Given $x_{3}\in E_{n-1},\,\ldots,\,x_{n+1}\in E_{1}$, consider the regular linear operator

\[ A_{x_{3},\ldots,x_{n+1}}\colon E_{n}\longrightarrow E_{n+1}^{{\ast}},\quad A_{x_{3},\ldots,x_{n+1}}(x_{2})=A_{\theta}^{1}(x_{2},x_{3},\ldots,x_{n+1}). \]

Given $x_{n+1}^{\ast \ast }\in E_{n+1}^{\ast \ast }$, take a net $(x_{\alpha _2})_{\alpha _2}$ in $E_{n}$ such that $J_{E_{n}}(x_{\alpha _2}) \stackrel {\omega ^*} \longrightarrow x_{n}^{\ast \ast }$ and apply the $\omega ^{\ast }$-$\omega ^{\ast }$-continuity of $[A_{x_{3},\,\ldots,\,x_{n+1}}]^{\ast \ast }$ and Lemma 5.3 for $i=n+1$ and $i=n$ to obtain

(5.1)\begin{align} & [A_{x_{3},\ldots,x_{n+1}}]^{{\ast}{\ast}}(x_{n}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad=\lim_{\alpha_{2}}[A_{x_{3},\ldots,x_{n+1}}]^{{\ast}{\ast}}(J_{E_{n}}(x_{\alpha_{2}}))(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad=\lim_{\alpha_{2}}J_{E_{n+1}^{{\ast}}}(A_{x_{3},\ldots,x_{n+1}}(x_{\alpha_{2}}))(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad=\lim_{\alpha_{2}}x_{n+1}^{{\ast}{\ast}}(A_{x_{3},\ldots,x_{n+1}}(x_{\alpha_{2}}))=\lim_{\alpha_{2}}x_{n+1}^{{\ast}{\ast}}(A_{\theta}^{1}(x_{\alpha_{2}},x_{3},\ldots,x_{n+1}))\nonumber\\ & \quad=\lim_{\alpha_{2}}\overline{x_{n+1}^{{\ast}{\ast}}}(A_{\theta})(x_{\alpha_{2}},x_{3},\ldots,x_{n+1})\nonumber\\ & \quad=\lim_{\alpha_{2}} A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{3}),J_{E_{n}}(x_{\alpha_{2}}),x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad=A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{3}),x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}}). \end{align}

For $x_{n}^{\ast \ast }\in E_{n}^{\ast \ast }$ and $x_{4}\in E_{n-2},\,\ldots,\,x_{n+1}\in E_{1}$, consider the regular linear operator $A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{\ast \ast }}\colon$ $E_{n-1}\longrightarrow E_{n+1}^{\ast }$ given by

\[ A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{3})(x_{1})=A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{3}),x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{1})). \]

On the one hand, for every $x_{3}\in E_{n-1}$ the functional $[A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{\ast \ast }}(x_{3})]^{\ast \ast }$ is a $\omega ^{\ast }$-continuous extension of $A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{\ast \ast }}(x_{3})$. On the other hand, since $A_{x_3, \ldots, x_{n+1}}$ is weakly compact by assumption, for every $x_{n}^{\ast \ast }\in E_{n}^{\ast \ast }$ the functional $[A_{x_{3},\,\ldots,\,x_{n+1}}]^{\ast \ast }(x_{n}^{\ast \ast })$ is $\omega ^{\ast }$-continuous. Taking a net $(x_{\alpha _{1}})_{\alpha _{1}}$ in $E_{n+1}$ such that $J_{E_{n+1}}(x_{\alpha _{1}}) \stackrel {\omega ^*} \longrightarrow x_{n+1}^{\ast \ast }$,

(5.2)\begin{align} & [A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{3})]^{{\ast}{\ast}}(x_{n+1}^{{\ast}{\ast}})=\lim_{\alpha_{1}}[A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{3})]^{{\ast}{\ast}}(J_{E_{n+1}}(x_{\alpha_{1}}))\nonumber\\ & \quad =\lim_{\alpha_{1}}J_{E_{n+1}}(x_{\alpha_{1}})(A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{3}))\nonumber\\ & \quad =\lim_{\alpha_{1}}A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{3})(x_{\alpha_{1}})\nonumber\\ & \quad =\lim_{\alpha_{1}}A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{3}),x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{\alpha_{1}}))\nonumber\\ & \quad =\lim_{\alpha_{1}}[A_{x_{3},\ldots,x_{n+1}}]^{{\ast}{\ast}}(x_{n}^{{\ast}{\ast}})(J_{E_{n+1}}(x_{\alpha_{1}}))=[A_{x_{3},\ldots,x_{n+1}}]^{{\ast}{\ast}}(x_{n}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \stackrel{(5.1)}{=}A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{3}),x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}}). \end{align}

Take a net $(x_{\alpha _{3}})_{\alpha _{3}}$ in $E_{n-1}$ such that $J_{E_{n-1}}(x_{\alpha _{3}}) \stackrel {\omega ^*} \longrightarrow x_{n-1}^{\ast \ast }$. Using that $[A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{\ast \ast }}]^{\ast \ast }$ is $\omega ^{\ast }$-$\omega ^{\ast }$-continuous and calling on Lemma 5.3 for $i = n-1$, for each $x_{n+1}^{\ast \ast }\in E_{n+1}^{\ast \ast }$ we have

(5.3)\begin{align} & [A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(x_{n-1}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})=\lim_{\alpha_{3}}[A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(J_{E_{n-1}}(x_{\alpha_{3}}))(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad =\lim_{\alpha_{3}}J_{E_{n+1}^{{\ast}}}(A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{\alpha_{3}}))(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad =\lim_{\alpha_{3}}x_{n+1}^{{\ast}{\ast}}(A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{\alpha_{3}}))=\lim_{\alpha_{3}}[A_{x_{4},\ldots,x_{n+1},x_{n}^{{\ast}{\ast}}}(x_{\alpha_{3}})]^{{\ast}{\ast}}(x_{n+1}^{{\ast}{\ast}})\nonumber\nonumber\\ & \stackrel{\textrm{(5.2)}}{=}\lim_{\alpha_{3}} A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-1}}(x_{\alpha_{3}}),x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad =A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-2}}(x_{4}),x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}}). \end{align}

For $x_{n-1}^{\ast \ast }\in E_{n-1}^{\ast \ast },\, x_{n}^{\ast \ast }\in E_{n}^{\ast \ast }$ and $x_{5}\in E_{n-3},\,\ldots,\,x_{n+1}\in E_{1}$, consider the regular linear operator $A_{x_{5},\,\ldots,\,x_{n+1},\,x_{n-1}^{\ast \ast },\,x_{n}^{\ast \ast }}\colon E_{n-2}\longrightarrow E_{n+1}^{\ast }$ given by

\begin{align*} & A_{x_{5},\ldots,x_{n+1},x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}}}(x_{4})(x_{1})\\& \quad =A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-2}}(x_{4}),x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{1})). \end{align*}

For every $x_{4}\in E_{n-2}$ the functional $[A_{x_{5},\,\ldots,\,x_{n+1},\,x_{n-1}^{\ast \ast },\,x_{n}^{\ast \ast }}(x_{4})]^{\ast \ast }$ is a $\omega ^{\ast }$-continuous extension of $A_{x_{5},\,\ldots,\,x_{n+1},\,x_{n-1}^{\ast \ast },\,x_{n}^{\ast \ast }}(x_{4})$. On the other hand, since $A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{**}}$ is weakly compact by assumption, for every $x_{n-1}^{\ast \ast }\in E_{n-1}^{\ast \ast }$ the functional $[A_{x_{4},\,\ldots,\,x_{n+1},\,x_{n}^{\ast \ast }}]^{\ast \ast }(x_{n-1}^{\ast \ast })$ is $\omega ^{\ast }$-continuous on $E_{n-2}$. So, repeating the procedure using (5.3) we get

(5.4)\begin{align} & [A_{x_{5},\ldots,x_{n+1},x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}}}(x_{4})]^{{\ast}{\ast}}(x_{n+1}^{{\ast}{\ast}})\nonumber\\ & \quad=A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-2}}(x_{4}),x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}}). \end{align}

Since the operator $[A_{x_{5},\,\ldots,\,x_{n+1},\,x_{n-1}^{\ast \ast },\,x_{n}^{\ast \ast }}]^{\ast \ast }$ is $\omega ^{\ast }$-$\omega ^{\ast }$-continuous, for every $x_{n+1}^{\ast \ast }\in E_{n+1}^{\ast \ast }$, taking a net $(x_{\alpha _{4}})_{\alpha _{4}}$ in $E_{n-2}$ such that $J_{E_{n-2}}(x_{\alpha _{4}}) \stackrel {\omega ^*} \longrightarrow x_{n-2}^{\ast \ast }$, using Lemma 5.3 for $i = n-2$ and ( 5.4) we have

\begin{align*} & [A_{x_{5},\ldots,x_{n+1},x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(x_{n-2}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})\\ & \quad =A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),\ldots,J_{E_{n-3}}(x_{5}),x_{n-2}^{{\ast}{\ast}},x_{n-1}^{{\ast}{\ast}},x_{n}^{{\ast}{\ast}},x_{n+1}^{{\ast}{\ast}}). \end{align*}

Repeating the procedure $(n-3)$ times, we end up with

(5.5)\begin{equation} [A_{x_{n+1},x_{3}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(x_{2}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})=A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),x_{2}^{{\ast}{\ast}},\ldots,x_{n+1}^{{\ast}{\ast}}) \end{equation}

for every $x_{n+1}^{\ast \ast }\in E_{n+1}^{\ast \ast }$, where, for each $x_{n+1}\in E_{1}$ and $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast },\, i=3,\,\ldots,\,n$, $A_{x_{n+1},\,x_{3}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast }}\colon$ $E_{2}\longrightarrow E_{n+1}^{\ast }$ is the regular linear operator given by

\[ A_{x_{n+1},x_{3}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n})(x_{1})= A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),J_{E_{2}}(x_{n}),x_{3}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{1})). \]

Finally, given $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast },\, i=2,\,\ldots,\,n$, the regular linear operator $A_{x_{2}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast }}\colon E_{1} \longrightarrow E_{n+1}^{\ast }$ defined by

\[ A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n+1})(x_{1})= A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{1})), \]

is weakly compact by condition (ii) for $n+1$. So, for every $x_{2}^{\ast \ast }\in E_{2}^{\ast \ast }$, $[A_{x_{n+1},\,x_{3}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast }}]^{\ast \ast }(x_{2}^{\ast \ast })$ is $\omega ^{\ast }$-continuous, therefore

(5.6)\begin{align} & [A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n+1})]^{{\ast}{\ast}}(x_{n+1}^{{\ast}{\ast}})=\lim_{\alpha_{1}}[A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n+1})]^{{\ast}{\ast}}(J_{E_{n+1}}(x_{\alpha_{1}}))\nonumber\\ & \quad =\lim_{\alpha_{1}}J_{E_{n+1}}(x_{\alpha_{1}})(A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n+1}))=\lim_{\alpha_{1}}A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{n+1})(x_{\alpha_{1}})\nonumber\nonumber\\ & \quad =\lim_{\alpha_{1}} A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}},J_{E_{n+1}}(x_{\alpha_{1}}))\nonumber\\ & \quad =\lim_{\alpha_{1}} [A_{x_{n+1},x_{3}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(x_{2}^{{\ast}{\ast}})(J_{E_{n+1}}(x_{\alpha_{1}}))=[A_{x_{n+1},x_{3}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(x_{2}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})\nonumber\nonumber\\ & \stackrel{\textrm{(5.5)}}{=}A^{{\ast}[n+2]}(J_{E_{1}}(x_{n+1}),x_{2}^{{\ast}{\ast}},\ldots,x_{n+1}^{{\ast}{\ast}}). \end{align}

For the final time, taking a net $(x_{\alpha _{n+1}})_{\alpha _{n+1}}$ in $E_{1}$ such that $J_{E_{1}}(x_{\alpha _{n+1}}) \stackrel {\omega ^*} \longrightarrow x_{1}^{\ast \ast }$, the $\omega ^{\ast }$-$\omega ^{\ast }$ continuity of $[A_{x_{2}^{\ast },\,\ldots,\,x_{n}^{\ast \ast }}]^{\ast \ast }$ and Lemma 5.3 for $i = 1$ give, for every $x_{n+1}^{\ast \ast }\in E_{n+1}^{\ast \ast }$,

\begin{align*} & [A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}]^{**}(x_{1}^{{\ast}{\ast}})(x_{n+1}^{{\ast}{\ast}})=\lim_{\alpha_{n+1}}[A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}]^{{\ast}{\ast}}(J_{E_{1}}(x_{\alpha_{n+1}})(x_{n+1}^{{\ast}{\ast}})\\ & \quad =\lim_{\alpha_{n+1}}J_{E_{n+1}^{{\ast}}}(A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{\alpha_{n+1}}))(x_{n+1}^{{\ast}{\ast}})\\ & \quad =\lim_{\alpha_{n+1}}x_{n+1}^{{\ast}{\ast}}(A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{\alpha_{n+1}}))=\lim_{\alpha_{n+1}}[A_{x_{2}^{{\ast}{\ast}},\ldots,x_{n}^{{\ast}{\ast}}}(x_{\alpha_{n+1}})]^{{\ast}{\ast}}(x_{n+1}^{{\ast}{\ast}})\\ & \quad \stackrel{\textrm{(5.6)}}{=}\lim_{\alpha_{n+1}} A^{{\ast}[n+2]}(J_{E_{1}}(x_{\alpha_{n+1}}),x_{2}^{{\ast}{\ast}},\ldots,x_{n+1}^{{\ast}{\ast}})=A^{{\ast}[n+2]}(x_{1}^{{\ast}{\ast}},\ldots,x_{n+1}^{{\ast}{\ast}}). \end{align*}

This proves that $[A_{x_{2}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast }}]^{\ast \ast }(x_{1}^{\ast \ast }) = A^{\ast [n+2]}(x_{1}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast },\,\bullet )$. By condition (b) for $n+1$ we know that $[A_{x_{2}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast }}]^{\ast \ast }(x_{1}^{\ast \ast })$ has property $\mathcal {P}$, so $A^{\ast [n+2]}(x_{1}^{\ast \ast },\,\ldots,\,x_{n}^{\ast \ast },\,\bullet )$ has property $\mathcal {P}$, which completes the proof.

Proof. Let $A\in \mathcal {L}_{r}(E_{1},\,\ldots,\,E_{m};F)$ and $y^{\ast }\in F^{\ast }$ be given. Since $y^{\ast }\circ A\in \mathcal {L}_{r}(E_{1},\,\ldots,\,E_{m})$ and order continuity is an Arens property, by Theorem 5.6 the extension $(y^* \circ A)^{\ast [m+1]}$ is separately order continuous. For all $x_{i}^{\ast \ast }\in E_{i}^{\ast \ast },\, i=1,\,\ldots,\,m$,

\[ A^{{\ast}[m+1]}(x_{1}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}})(y^{{\ast}})=(y^{{\ast}}\circ A)^{*[m+1]}(x_{1}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}}). \]

For each $j\in \{1,\,\ldots,\,m\}$ let $x_{j}^{\ast \ast }\in E_{j}^{\ast \ast }$ and let $(x_{\alpha _{j}}^{\ast \ast })_{\alpha _{j}\in \Omega _{j}}$ be a net $E_{j}^{\ast \ast }$ such that $x_{\alpha _{j}}^{\ast \ast } \xrightarrow {\, o \, } 0$. There exists a net $(y_{\alpha _{j}}^{\ast \ast })_{\alpha _{j}\in \Omega _{j}}$ in $E_{j}^{\ast \ast }$ and $\alpha _{j_{0}}\in \Omega _{j}$ so that $y_{\alpha _{j}}^{\ast \ast }\downarrow 0$ and $|x_{\alpha _{j}}^{\ast \ast }|\leq y_{\alpha _{j}}^{\ast \ast }$ for every $\alpha _{j}\geq \alpha _{j_{0}}$. Without loss of generality, assume that $A$ and $y^{\ast }$ are positive. Since $(y^{\ast }\circ A)^{*[m+1]}(|x_{1}^{\ast \ast }|,\,\ldots,\,\bullet,\,\ldots,\,|x_{m}^{\ast \ast }|)\colon E_{j}^{\ast \ast }\longrightarrow \mathbb {R}$ is positive and order continuous,

\begin{align*} & A^{*[m+1]}(|x_{1}^{{\ast}{\ast}}|,\ldots,y_{\alpha_{j}}^{{\ast}{\ast}},\ldots,|x_{m}^{{\ast}{\ast}}|)(y^{{\ast}})\\ & \quad =(y^{{\ast}}\circ A)^{*[m+1]}(|x_{1}^{{\ast}{\ast}}|,\ldots,\bullet,\ldots,|x_{m}^{{\ast}{\ast}}|)(y_{\alpha_{j}}^{{\ast}{\ast}})\downarrow 0. \end{align*}

It follows that $A^{*[m+1]}(|x_{1}^{\ast \ast }|,\,\ldots,\,y_{\alpha _{j}}^{\ast \ast },\,\ldots,\,|x_{m}^{\ast \ast }|) \downarrow 0$ [Reference Aliprantis and Burkinshaw2, Theorem 1.18] and, for every $\alpha _{j}\geq \alpha _{j_{0}}$,

\begin{align*} |A^{*[m+1]}(x_{1}^{{\ast}{\ast}},\ldots,x_{\alpha_{j}}^{{\ast}{\ast}},\ldots,x_{m}^{{\ast}{\ast}})| & \leq A^{*[m+1]}(|x_{1}^{{\ast}{\ast}}|,\ldots,|x_{\alpha_{j}}^{{\ast}{\ast}}|,\ldots,|x_{m}^{{\ast}{\ast}}|)\\ & \leq A^{*[m+1]}(|x_{1}^{{\ast}{\ast}}|,\ldots,y_{\alpha_{j}}^{{\ast}{\ast}},\ldots,|x_{m}^{{\ast}{\ast}}|) \downarrow 0. \end{align*}

This shows that $A^{*[m+1]}(x_{1}^{\ast \ast },\,\ldots,\,x_{\alpha _{j}}^{\ast \ast },\,\ldots,\,x_{m}^{\ast \ast }) \xrightarrow {\, o \, } 0$ and proves that $A^{*[m+1]}$ is separately order continuous.

Proof. Condition (a) of Theorem 5.7 is given by assumption. For $x_{1}^{\ast \ast }\in E_{1}^{\ast \ast }$ and $T\in \mathcal {L}_{r}(E_{1};E_{k}^{\ast })$, $x_{1}^{\ast \ast }$ is order continuous because the norm of $E_{1}^{\ast }$ is order continuous [Reference Meyer–Nieberg17, Theorem 2.4.2]. Since $T^*$ is order continuous [Reference Aliprantis and Burkinshaw2, Theorem 1.73], $T^{**}(x_1^{**}) = x_1^{**} \circ T^*$ is order continuous as well, so condition (b) is fulfilled too.

Proof. The Arens regularity of $E$ immediately gives condition (a) of Theorem 5.7 and implies that, for every $T\in \mathcal {L}_{r}(E;E^{\ast })$, $T^{**}(E^{**}) \subseteq J_{E^*}(E^*) \subseteq (E^{**})^*_n$, which gives condition (b).

Proof. Assume first that $P$ is orthogonally additive and $F = \mathbb {R}$. By Proposition 4.8 we know that $P^{\ast [m+1]}$ is order continuous at the origin on $E^{**}$, therefore it is order continuous at every point of $E^{**}$ by [Reference Boyd, Ryan and Snigireva8, Proposition 8].

Suppose now that $E$ is symmetrically Arens regular. It is clear that we can assume that $P$ is positive. We know that $(\check {P})^{\ast [m+1]}$ is order continuous in the first variable on $E^{**}$ (Theorem 4.6) and positive because $\check {P}$ is positive. In order to check that it is symmetric, let $\rho \in S_m$ be given. For every $\varphi \in F^*$, since $E$ is symmetrically Arens regular and $\varphi \circ \check {P}$ is symmetric, by [Reference Aron, Cole and Gamelin5, Theorem 8.3] (or [Reference Cabello Sánchez, García and Villanueva11, Corollary 6]) we know that $AR_m^{\theta }(\varphi \circ \check {P})$ is symmetric as well. So, for $x_1^{**},\, \ldots,\, x_m^{**} \in E^{**}$,

\begin{align*} (\check{P})^{{\ast}[m+1]}(x_1^{**}, \ldots, x_m^{**} )(\varphi) & = AR_m^{\theta}(\check{P})(x_1^{**}, \ldots, x_m^{**})(\varphi)\\ & = AR_m^{\theta}(\varphi \circ \check{P})(x_1^{**}, \ldots, x_m^{**})\\ & = AR_m^{\theta}(\varphi \circ \check{P})(x_{\rho(1)}^{**}, \ldots, x_{\rho(m)}^{**})\\ & = AR_m^{\theta}(\check{P})(x_{\rho(1)}^{**}, \ldots, x_{\rho(m)}^{**})(\varphi)\\ & = (\check{P})^{{\ast}[m+1]}(x_{\rho(1)}^{**}, \ldots, x_{\rho(m)}^{**} )(\varphi), \end{align*}

proving that $(\check {P})^{\ast [m+1]}$ is symmetric. The order continuity in the first variable and the symmetry yield that the positive $m$-linear operator $(\check {P})^{\ast [m+1]}$ is separately order continuous on $(E^{**})^m$. By [Reference Buskes and Roberts10, Lemma 2.6] it follows that $(\check {P})^{\ast [m+1]}$ is jointly order continuous on $(E^{**})^m$. So, if $x_{\alpha }^{**}\xrightarrow {\, o \,} x^{**}$ in $E^{**}$, then

\begin{align*} P^{{\ast}[m+1]}(x_{\alpha}^{**}) & = (\check{P})^{{\ast}[m+1]}(x_{\alpha}^{**}, \ldots, x_{\alpha}^{**}) \xrightarrow{\,\, o \,\,} (\check{P})^{{\ast}[m+1]}(x^{**}, \ldots, x^{**})\\ & = P^{{\ast}[m+1]}(x^{**}). \end{align*}