Recall the Coifman–Meyer Theorem as stated in Grafakos and Oh - The Kato-Ponce Inequality.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \setminus\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$

Edit: Thanks to Terry's remark, the estimate does not necessarily hold for any multiplier. Actually, I had the following estimate which I wanted to show, $$\|D^\alpha(fg)\|_p\leq C(\|gD^\alpha f\|+\|fD^\alpha g\|_p).$$ Naturally, one would write $D^\alpha(fg)$ as a double integral involving the Fourier transforms of $f$ and $g$. I was hoping that if the modified Coifman-Meyer estimate was true then this estimate would hold after applying Littlewood decomposition.

Recall the Coifman–Meyer Theorem as stated in Grafakos and Oh - The Kato-Ponce Inequality.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \setminus\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$

Edit: Thanks to Terry's remark, the estimate does not necessarily hold for any multiplier. Actually, I had the following estimate which I wanted to show, $$\|D^\alpha(fg)\|_p\leq C(\|gD^\alpha f\|+\|fD^\alpha g\|_p).$$ Here $\alpha\in (0,1)$ and $D^\alpha = (-\Delta)^\alpha.$

Naturally, one would write $D^\alpha(fg)$ as a double integral involving the Fourier transforms of $f$ and $g$. I was hoping that if the modified Coifman-Meyer estimate was true then this estimate would hold after applying Littlewood decomposition.

Recall the Coifman–Meyer Theorem as stated in Grafakos and Oh - The Kato-Ponce Inequality.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \setminus\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$

Recall the Coifman–Meyer Theorem as stated in Grafakos and Oh - The Kato-Ponce Inequality.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \setminus\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$

Edit: Thanks to Terry's remark, the estimate does not necessarily hold for any multiplier. Actually, I had the following estimate which I wanted to show, $$\|D^\alpha(fg)\|_p\leq C(\|gD^\alpha f\|+\|fD^\alpha g\|_p).$$ Naturally, one would write $D^\alpha(fg)$ as a double integral involving the Fourier transforms of $f$ and $g$. I was hoping that if the modified Coifman-Meyer estimate was true then this estimate would hold after applying Littlewood decomposition.

Recall the Coifman-Meyer Theorem as stated here.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \backslash\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$

Recall the Coifman–Meyer Theorem as stated in Grafakos and Oh - The Kato-Ponce Inequality.

Theorem: Let $m \in L^{\infty}\left(\mathbf{R}^{2 n}\right)$ be smooth away from the origin and satisfy $$ \left|\partial_{\xi}^{\alpha} \partial_{\eta}^{\beta} m\right|(\xi, \eta) \leq C(\alpha, \beta)(|\xi|+|\eta|)^{-|\alpha|-|\beta|} $$ for all $\xi, \eta \in \mathbf{R} \setminus\{0\}$ and $\alpha, \beta \in \mathbf{Z}^{n}$ multi-indices with $|\alpha|,|\beta| \leq 2 n+1$. Then for all $f, g \in \mathcal{S}\left(\mathbf{R}^{n}\right)$, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{r}\left(\mathbf{R}^{n}\right)} \leq C(p, q, r, m)\|f\|_{L^{p}\left(\mathbf{R}^{n}\right)}\|g\|_{L^{q}\left(\mathbf{R}^{n}\right)} $$ where $\frac{1}{2}<r<\infty, 1<p, q \leq \infty$ satisfy $\frac{1}{r}=\frac{1}{p}+\frac{1}{q}$.

I was wondering if it makes sense to expect the following estimate to hold, $$ \left\|\int_{\mathbf{R}^{2 n}} m(\xi, \eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{i\langle\xi+\eta,\rangle} d \xi d \eta\right\|_{L^{p}\left(\mathbf{R}^{n}\right)} \leq C(p, m)\|fg\|_{L^{p}\left(\mathbf{R}^{n}\right)} $$ for some Schwartz functions $f,g$ and exponent $p\geq 1?$