I know I have met the following construction somewhere, but I cannot remember where. Let $A$ be a (unital associative) ring, and let $N$ be an $A$-$A$ bimodule. On the product set $A\times N$ we define multiplication by \begin{equation*} (a,m)(b,n) := (ab,\,an+mb)~. \end{equation*} The set $A\times N$ equipped with this multiplication is a (unital associative) ring with the two-sided ideal $0\times N$ whose product with itself is $0$. The ideal $0\times N$ is the kernel of the surjective homomorphism of rings $A\times N\to A : (a,n)\mapsto a$. If $A$ is Jacobson-semisimple, then $0\times N$ is the Jacobson radical of the ring $A\times N$. Does this construction of the ring $A\times N$ from a ring $A$ and an $A$-$A$ bimodule $N$ have a name, and perhaps an established notation? The notation $A\times N$ is misleading since it suggests a direct product of rings, which it is not. **[Added a day later.]** The comment by Dag Oskar Madsen to the answer by Jeremy Rickard got me thinking. First consider the definition of the inner semidirect product of groups. Let $G$ be a group with a subgroup $H$ and a normal subgroup $N$. The following statements are equivalent: 1. $G=NH$ ($=HN$) and $N\cap H=\{e\}$. 2. The natural embedding $H\to G$, composed with the natural projection $G\to G/N$, is an isomorphism of groups. 3. There exist a group $H'$ and homomorphisms of groups $p\colon G\to H'$ and $j\colon H'\to G$ such that $p\circ j = \mathrm{id}_{H'}$ and $j(H')=H$, $\ker p = N$. 4. There exists an idempotent endomorphism $e$ of the group $G$ such that $e(G)=H$ and $\ker e = N$. If one of these statements holds (and therefore all hold) we say that the group $G$ is the (*inner*) *semidirect product* of its normal subroup $N$ and its subgroup $H$, and write $G=N\rtimes H$. Now compare this definition to an analogous situation in a ring in place of a group. Let $R$ be a ring with a subring $A$ and a (two-sided) ideal $N$. The following statements are equivalent: 1. The underlying additive group of $R$ is a direct sum of the additive underlying groups of $N$ and $A$, which we write $R=N\oplus A$. 2. The natural embedding $A\to R$, composed with the natural projection $R\to R/N$, is an isomorphism of rings. 3. There exist a ring $A'$ and homomorphisms of rings $p\colon R\to A'$ and $j\colon A'\to R$ such that $p\circ j=\mathrm{id}_{A'}$ and $j(A')=A$, $\ker p = N$. 4. There exists an idempotent endomorphism $e$ of the ring $R$ such that $e(R)=A$ and $\ker e=N$. I propose to say, whenever the situation described by any of the four cases above occurs, that $R$ is the (*inner*) *semidirect product* of its ideal $N$ and its subring $A$, and write $R=N\rtimes A$. The structure of the inner semidirect product of an ideal and a subring of a ring suggests the following definition of the outer semidirect product of a rng $N$ and a ring $A$ with respect to a coherent biaction $\varphi$ of $A$ on $N$. (A rng is an additive group with an associative biadditive multiplication. A multiplicative identity is not required; if it is present, it is ignored.) What we mean by a coherent biaction of $A$ on $N$: the rng $N$ is an $A$-$A$ (unital) bimodule, where $(am)n=a(mn)$, $m(na)=(mn)a$ for all $m$, $n$ in $N$ and all $a$ in $A$. We define the multiplication on the set $B:=N\times A$ by \begin{equation*} (m,a)(n,b) \,:=\, (mn+an+mb,\,ab)~. \end{equation*} Then $B$ is a ring, $0\times A$ is a subring of $B$, $N\times 0$ is an ideal of $B$, and $B=(N\times 0)\oplus(0\times A)$. I propose to call the ring $B$ the (*outer*) *semidirect product* of a rng $N$ and a ring $A$ with respect to a coherent biaction $\varphi$, and write $B = N\rtimes_\varphi A$. I believe this is a natural transfer, by analogy, of the notion of a semidirect product from groups to rings. The outer semidirect product for rings is peculiar in that it constructs a ring from a rng and a ring (thus it is an 'inter-species' construction) with the ring coherently biacting on the rng. If we have just a plain $A$-$A$ bimodule $N$, with no multiplication on $N$, we equip $N$ with an all-zero multiplication ($mn=0$ for all $m$, $n$ in $N$), obtaining a legitimate rng, and so have $A$ coherently biacting on the rng $N$. I propose that in this special case we write $B=N\mathbin{{}_0\rtimes_\varphi} A$, where $0$ stands for the all-zero multiplication on $N$ and $\varphi$ is the bimodule action of the ring $A$ on the additive group~$N$. I googled "semidirect product of rings" and got no exact matches. The approximate matches were "crossed product of rings", "semidirect product of Hopf algebras", "semidirect product of Lie algebras/rings". There was also a 'mixed marriage' semidirect product $K[N]\rtimes_\varphi H\cong K[N\rtimes_\varphi H]$ of the group algebra of a group $N$ with coefficients in a commutative ring $K$ and a group $H$, with respect to an action $\varphi$ of the group $H$ on the group $N$ (by isomorphisms), which induces an action of the group $H$ on the group algebra $K[N]$ (by isomorphisms). Mark the notion of a retract of a topological space: a subspace $A$ of a topological space $X$ is a *retract* of $X$ if there exists an idempotent continuous map $e\colon X\to X$ such that $e(X)=A$; the restriction of $e$ to $r\colon X\to A$ (the codomain $X$ of $e$ is narrowed down to the codomain $A$ of $r$) is a *retraction*.